MIVAR 25V2E BIFONICO CHASSIS TV3536/1
Tuner MIVAR TV3701 and Frequency synthesizer + prescaler and Video IF and Sound 1 IF In One module.
Frequency synthesizer + prescaler with SDA3302 (SIEMENS)
Video IF with TDA8341 (PHILIPS)
Mixer + osc with TDA5330T (PHILIPS)
PHILIPS TDA5330T VHF, UHF and Hyperband mixer/oscillator for TV and VCR 3-band tuners
GENERAL DESCRIPTION
The TDA5330T is a monolithic integrated circuit that performs the band A, band B and band C mixer/oscillator functions
in TV and VCR tuners. This device gives the designer the capability to design an economical and physically small 3-band
tuner which will be capable of meeting the most stringent requirements e.g. FTZ or FCC. The tuner development time
can be drastically reduced by using this device.
Features
· Balanced mixer with a common emitter input for band A
· Amplitude-controlled oscillator for band A
· Balanced mixer with common base input for band B and C
· Balanced oscillator for band B and C
· Local oscillator buffer output for external prescaler
· SAW filter preamplifier with an output impedance of 100 W
· Bandgap voltage stabilizer for oscillator stability
· Electronic bandswitch
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PHILIPS TSA5511 1.3 GHz Bidirectional I2C-bus
FEATURES
· Complete 1.3 GHz single chip system
· Low power 5 V, 35 mA
· I2C-bus programming
· In-lock flag
· Varicap drive disable
· Low radiation
· Address selection for Picture-In-Picture (PIP), DBS
tuner (3 addresses)
· Analog-to-digital converter
· 8 bus controlled ports (5 for TSA5511T), 4 current
limited outputs (1 for TSA5511T), 4 open collector
outputs (bi-directional)
· Power-down flag
APPLICATIONS
· TV tuners
· VCR Tuners
GENERAL DESCRIPTION
The TSA5511 is a single chip PLL frequency synthesizer
designed for TV tuning systems. Control data is entered
via the I2C-bus; five serial bytes are required to address
the device, select the oscillator frequency, programme the
eight output ports and set the charge-pump current. Four
of these ports can also be used as input ports (three
general purpose I/O ports, one ADC). Digital information
concerning those ports can be read out of the TSA5511 on
the SDA line (one status byte) during a READ operation.
A flag is set when the loop is “in-lock” and is read during a
READ operation. The device has one fixed I2C-bus
address and 3 programmable addresses, programmed by
applying a specific voltage on Port 3. The phase
comparator operates at 7.8125 kHz when a 4 MHz crystal
is used.
controlled synthesizer
CHASSIS TV3536/1 THOMSON TEA2164 SWITCH MODE POWER SUPPLY PRIMARY CIRCUIT
.POSITIVE AND NEGATIVE OUTPUT CURRENT
UP TO 1.2AAND – 1.7A .A TWO LEVEL COLLECTOR CURRENT LIMITATION
.COMPLETE TURN OFF AFTER LONG DURATION
OVERLOADS .UNDER AND OVER VOLTAGELOCK-OUT .SOFT START BY PROGRESSIVE CURRENT
LIMITATION .DOUBLE PULSE SUPPRESSION .BURST MODE OPERATION UNDER STANDBY
CONDITIONS
DESCRIPTION
In amaster slave architecture, the TEA2164control
IC achieves the slave function. Primarily designed
for TV receivers and monitors applications, this
circuit provides an easy synchronizationand smart
solution for low power stand by operation.
Located at the primary side the TEA2164 Control
IC ensures :
- the power supply start-up
- the power supply control under stand-by conditions
- the process of the regulation signals sent by the
master circuit located at the secondary side
- directbasedrive of the bipolarswitching transistor
- the protection of the transistor and the power
supply under abnormal conditions.
II. GENERAL DESCRIPTION
In a master slave architecture, the TEA2164 Control
IC, located at the primary side of an off line
power supply achievesthe slave function ;whereas
the master circuit is located at the secondary side.
The link between both circuits is realized by a small
pulse transformer
In the operation of the master-slave architecture,
four majors cases must be considered :
- normal operating
- stand-bymode
- power supply start-up
- abnormal conditions : off load, short circuit, ...
II.1. Normal Operating (master slave mode)
In this configuration, the master circuit generatesa
pulse widthmodulatedsignal issued from themonitoring
of the output voltage which needs the best
accuracy (in TV applications : the horizontal deflection
stagesupplyvoltage).Themaster circuit power
supply can be supplied by another output.
The PWM signal are sent towards the primary side
through small differentiating transformer. For the
TEA2164 positive pulses are transistor switchingon
commands ; and negative pulses are transistor
switching-offcommands (Figure 4). In this configuration,
only by synchronizing the master oscillator,
the switching transistor may be synchronized with
an external signal.
II.2. Stand-by Mode
In this configuration the master circuit no longer
sends PWM signals, the structure is not synchronized
; and the TEA2164 operates in burst mode.
The average power consumption at the secondary
side may be very low 1W 3 P 3 6W (as it is
consumed in TV set during stand by).
By action on the maximum duty cycle control, a
primary loop maintains a semi-regulation of the
output voltages.Voltage on feed-back is applied on
Pin 9.
Burst period is externally programmedby capacitor
C1.
II.3. Power Supply Start-up
After the mains have been switched-on, the VCC
storage capacitor of the TEA2164 is charged
through a high value resistor connected to the
rectified high voltage.When Vcc reaches VCC start
threshold (9V typ), the TEA2164 starts operatingin
burst mode. Since available output power is low in
burst mode the output power consumption must
remain low before complete setting-up of output
voltage. In TV application it can be achieved by
maintaining the TV in stand-by mode during startup.
Overvoltage Protection
When VCC exceeds VCC max, an internal flip-flop
stops output conduction signals. The circuit will
start again after the capacitor C1 discharge ; it
means : after loss of synchronization or after Vcc
stop crossing (Figure 7).
In flyback converters, this function protects the
power supply against output voltage runaway.
MIVAR 21L1E TVD CHASSIS TV3536/1 Switch-mode power supply with burst mode standby operation:
In a switch mode power supply, a first switching transistor is coupled to a primary winding of a transformer for generating pulses of a switching current. A secondary winding of the transformer is coupled via a switching diode to a capacitor of a control circuit for developing a control signal in the capacitor. The control signal is applied to a mains coupled chopper second transistor for generating and regulating supply voltages in accordance with pulse width modulation of the control signal. During standby operation, the first and second transistors operate in a burst mode that is repetitive at a frequency of the AC mains supply voltage such as 50 Hz. In the burst mode operation, during intervals in which pulses of the switching current occur, the pulse width and peak amplitude of the switching current pulses progressively increase in accordance with the waveform of the mains supply voltage to provide a soft start operation in the standby mode of operation within each burst group.
Description:
The invention relates to switch-mode power supplies.
In a typical switch mode power supply (SMPS) of a television receiver the AC mains supply voltage is coupled to a bridge rectifier. An unregulated direct current (DC) input supply voltage is produced. A pulse width modulator controls the duty cycle of a chopper transistor switch that applies the unregulated supply voltage across a primary winding of a flyback transformer. A flyback voltage at a frequency that is determined by the modulator is developed at a secondary winding of the transformer and is rectified to produce DC output supply voltages such as a voltage B+ that energizes a horizontal deflection circuit of the television receiver and a voltage that energizes a remote control unit.
During normal operation, the DC output supply voltages are regulated by the pulse width modulator in a negative feedback manner. During standby operation, the SMPS is required to generate the DC output supply voltage that energizes the remote control unit. However, most other stages of the television receiver are inoperative and do not draw supply currents. Consequently, the average value of the duty cycle of the chopper transistor may have to be substantially lower during standby than during normal operation.
Because of, for example, storage time limitation in the chopper transistor, it may not be possible to reduce the length of the conduction interval in a given cycle below a minimum level. Thus, in order to maintain the average value of the duty cycle low, it may be desirable to operate the chopper transistor in an intermittent or burst mode, during standby. During standby, a long dead time interval occurs between consecutively occurring burst mode operation intervals. Only during the burst mode operation interval switching operation occurs in the chopper transistor. The result is that each of the conduction intervals is of a sufficient length.
In accordance with an aspect of the invention, burst mode operation intervals are initiated and occur at a rate that is determined by a repetitive signal at the frequency of the AC mains supply voltage. For example, when the mains supply voltage is at 50 Hz, each burst mode operation interval, when switching cycles occur, may last 5 milliseconds and the dead time interval when no switching cycles occur, may last during the remainder portion or 15 milliseconds. Such arrangement that is triggered by a signal at the frequency of the mains supply voltage simplifies the design of the SMPS.
The burst mode operation intervals that occur in standby operation are synchronized to the 50 Hz signal. During each such interval, pulses of current are produced in transformers and inductances of the SMPS. The pulses of current occur in clusters that are repetitive at 50 Hz. The pulses of current occur at a frequency that is equal to the switching frequency of the chopper transistor within each burst mode operation interval. Such qurrent pulses might produce an objectionable sound during power-off or standby operation. The objectionable sound might be produced due to possible parasitic mechanical vibrations as a result of the pulse currents in, for example, the inductances and transformers of the SMPS.
In accordance with another aspect of the invention, the change in the AC mains supply voltage during each period causes the length of the conduction interval in consecutively occurring switching cycle during the burst mode operation interval to increase progressively. Such operation that occurs during each burst mode operation interval may be referred to as soft start operation. The soft start operation causes, for example, gradual charging of capacitors in the SMPS. Consequently, the parasitic mechanical vibrations are substantially reduced. Also, the frequency of the switching cycles within each burst mode operation interval is maintained above the audible range for further reducing the level of such audible noise during standby operation.
A switch mode power supply, embodying an aspect of the invention, for generating an output supply voltage during both a standby-mode of operation and during a run-mode of operation includes a source of AC mains input supply voltage. A control signal at a given frequency is generated. A switching arrangement energized by the input supply voltage and responsive to the first control signal produces a switching current during both the standby-mode of operation and the run-mode operation. The output supply voltage is generated from the switching current. An arrangement coupled to the switching arrangement and responsive to a standby-mode/run-mode control signal and to a signal at a frequency that is determined by a frequency of the AC mains input supply voltage controls the switching arrangement in a burst mode manner during the standby-mode of operation. During a burst interval, a plurality of switching cycles are performed and during an alternating dead time interval no switching cycles are performed. The two intervals alternate at a frequency that is determined by the frequency of the AC mains input supply voltage.
1. A chopped power supply control circuit intended to receive periodic
regulation control signals and to produce periodic square waves enabling
a main switch of the power supply, the square waves having a variable
width as a function of their regulation control signals, which circuit
comprises:
means for detecting the presence of regulation control signals,
a
very low frequency oscillator controlled by the detection means, this
oscillator producing, in the absence of regulation signals, a succession
of very low frequency periodic cycles, the oscillator being inhibited
by the regulation control signal detection means,
a high
frequency oscillator producing chopping signals palliating the absence
of regulation signals for producing enabling square waves,
an
inhibition means for allowing transmission of the chopping siganls to
the switch only during a first phase of each very low frequency periodic
cycle and for preventing such transmission during the rest of the
cycle, the first phase of each cycle having a duration which is long
compared with the period of the high frequency oscillator and short
compared with the period of the very low frequency oscillator.
2.
The control circuit as claimed in claim 1, wherein said high frequency
oscillator has a free oscillation period slightly greater than the
period of the regulation control signals and it is synchronized by these
signals when they are present.
3. The control circuit as claimed
in claim 1, wherein the regulation control signals comprise a positive
pulse followed by a negative pulse, one of them being used for
synchronizing the high frequency oscillator, the positive pulse being
transmitted through the inhibition means to a set input of a flip flop
for triggering off the beginning of conduction of the main switch, and
the negative pulse being transmitted to a reset input of the flip flop
for causing stopping of the conduction of the switch.
4. The control circuit according to claim 1 further comprising:
a
threshold comparator for receiving a signal measuring the current in
said switch and for outputting a signal stopping the conduction of said
switch when a threshold is exceeded;
means for varying the
threshold of said comparator including a means for producing a first
threshold value during normal operation of said circuit, a means for
producing a second threshold value at the beginning of said first phase
of said very low frequency cycle, said second threshold corresponding to
a current in said switch which is lower than during said normal
operation, and a means for producing a gradually decreasing threshold
during said first phase of said very low frequency cycle.
5.
The control circuit as claimed in claim 4, wherein said very low
frequency oscillator is a relaxation oscillator delivering a saw tooth
signal and the means for varying the threshold is driven by the output
of the very low frequency oscillator.
6. The control circuit as
claimed in one of claims 4 and 5, wherein another threshold converter is
provided receiving a signal of measurement of the current in the main
switch and delivering a signal for complete inhibition of enabling of
the switch when the current in the switch exceeds a third threshold
value higher than the first value.
7. The control circuit as
claimed in claim 6, wherein said inhibition signal delivered by the
other comparator is cancelled out when the circuit, after having
partially or totally ceased to be supplied with power, is again normally
supplied.
Description:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to stabilized power supplies called chopped power supplies.
A
chopped power supply operates in the following way: a transformer
primary winding receives a current which comes for example from a
rectifier bridge receiving the power from the AC mains. The current in
the transformer is chopped by a switch (for example a power transistor)
placed in series with the primary winding.
A circuit controlling
the transistor establishes periodic square waves for enabling the
transistor. For the duration of the square wave the current is allowed
to pass; outside the square wave, the passage of the current is
prevented.
On one (or more) secondary windings of the transformer
an AC voltage is then collected. This voltage is rectified and filtered
so as to obtain a DC voltage which is the DC output voltage of the
chopped power supply.
To stabilize the value of this DC voltage,
the cyclic periodic conduction ratio of the switch is adjusted, that is
to say the ratio between the conduction time and the disablement time in
a chopping period.
2. Discussion of Background
In a
chopped power supply architecture proposed by the applicant and shown in
FIG. 1, two integrated circuits are used. One of the circuits, CI1,
serves for controlling the base of a power transistor Tp for applying
thereto periodic enabling and disabling control signals. The space
control circuit CI1 is placed on the primary winding side (EP) of the
transformer (TA) for reasons which will be better understood further on
in the description. The integrated circuit, regulation circuit CI2, is
on the contary placed on the secondary side (winding ES1) and its serves
for examining the output voltage Vs of the power supply for elaborating
regulation signals which it transmits to the first integrated circuit
through a small transformer TX. The first integrated circuit CI1 uses
these regulation signals for modifying the cyclic conduction ratio of
the switching transistor TP and thus for regulating the output voltage
Vs of the power supply.
We will come back in more detail hereafter to the circuit shown in FIG. 1.
Numerous problems arise during designing of a chopped power supply, and the problems with which we will be particulary concerned here are problems of starting up the power supply and problems of safety should over voltages or over currents occur at different points in the circuit. The first problem which is met with is that of starting up the power supply : on switching on, the regulation circuit CI2 will tend to cause the base control circuit CI1 to generate square waves of maximum cyclic ratio until the power supply has reached its nominal output voltage. This is all the more harmful since there is then a heavy current drain on the side of the secondary windings which are connected to initially discharged filtering capacitors. There is a risk of destruction of the power transistor through over-currents during the start-up phase.
Progressive start-up circuits have already been proposed which limit the duration of the enabling square waves during a start-up phase, on switching on the device; the U.S. Pat. No. 3,959,714 describes such a circuit in which charging of a capacitor from switch-on defines initially short square waves which gradually increase in duration until these square waves reach the duration which the regulation circuit normally assigns thereto. The short square waves have priority; but, since they become gradually longer during the start-up phase, after a certain time they cease to have priority; this time is defined by the charging time constant of the capacitor.
Another problem which arises is the risk of accidental overcurrents, or sometimes overvoltages which may occur in the circuit. These over-currents and over-voltages may cause damage and often result in the destruction of the power transistor if nothing is done to eliminate them. In particular, a short circuit at the output of the stabilized power supply rapidly destroys the power transistor. If the short circuit occurs on start-up of the power supply, it is not the gradual start-up system with short square waves which gradually increase which will allow the over-currents resulting from this short circuit to be efficiently accomodated.
Finally, another problem, particularly important in an architecture such as the one shown in FIG. 1, is the risk of disappearance of the regulation signals which should be emitted by the regulation circuit CI2 and received by the base control circuit CI1: these signals determine not only the width of the square waves for enabling the power transistor but also their periodicity; in other words, they serve for establishing the chopping frequency, possibly synchronized from a signal produced on the secondary side of the transformer. The disappearance of these signals causes a particular disturbance which must be taken into account.
Furthermore, the architecture of FIG. 1, in which the secondary circuits have been voluntarily separated galvanically from the primary circuits, is such that the base control circuit may function rapidly after switch on, as will be explained further on, whereas the regulation circuit CI2 can only function if the chopped power supply is in operation; consequently, at the beginning, the base control circuit CI1 does not receive any regulation signals and this difficulty must be taken into account.
SUMMARY OF THE INVENTION
In an attempt to resolve as well as possible the whole of these different problems which relate to safety against accidental disturbances in the operation of the power supply (initial start-up being able to be considered moreover as transitory disturbed operating phase), the present invention proposes an improved chopped power supply control circuit which accomplishes a function of gradual start-up of the power supply on switch-on and a function of passing to the safety mode should a malfunction occur such as a disappearance of appropriate regulation signals: the safety mode consists of a succession of very low frequency periodic cycles, each cycle consisting in a gradual start-up attempt during a first phase which is short compared with the period of the cycle and long compared with the chopping period of the chopped power supply, the first phase being followed by a pause at the end of the cycle, and periodic cycles succeeding each other until normal operation of the power supply is established or re-established; a very low frequency oscillator establishes these cycles when the power supply is not normal operating conditions (start up or malfunction); this oscillation is disabled when normal operation is ascertained; a high frequency oscillator generates a burst of chopping signals palliating the absence of regulation signals; these signals are transmitted solely during the first phase of each cycle; they are inhibited during the second phase.
According to a very important characteristic of the invention; gradual start-up operates not by limiting the duration of the square waves from the charging of a capacitor with a fixed time constant, but by limiting the current in the power transistor to a maximum value, this maximum value increasing gradually during the start-up phase, overshooting of this current value causing interruption of the power transistor.
Thus, even in the case of a quasi short circuit, the value of a current in the transistor is limited, which was not the case in gradual start-up circuits of the prior art.
More precisely, the chopped power supply control circuit, intended to receive periodic regulation control signals and to produce periodic square waves for enabling a main switch of the power supply, the square waves having a variable width depending on the regulation control signals; comprises:
a means for detecting the presence of regulation control signals,
a very low frequency oscillator controlled by the detection means, this oscillator establishing, in the case of absence of regulation signals, a succession of very low frequency periodic cycles, the oscillator being inhibited by the detection means when regulation control signals are present,
a high frequency oscillator producing chopping signals palliating the absence of regulation signals for producing enabling square waves,
an inhibition means only allowing chopping signals to be transmitted to the switch during a first phase of each very low frequency periodic cycle and for preventing such transmission during the rest of the cycle, the first phase of each cycle having a duration which is long compared with the period of the high frequency oscillator and short compared with the period of the very low frequency oscillator.
Preferably, the high frequency oscillator has a free oscillation period slightly greater than the period of the regulation control signals and it is synchronized by these signals when they are present.
The regulation control signals may comprise a positive pulse followed by a negative pulse, one of them serving for synchronizing the high frequency oscillator, the positive pulse being transmitted through the inhibition means to a set input of a flip flop for enabling the switch, whereas the negative pulse is transmitted to the reset input of this flip flop for disabling.
In so far as limiting the current to a gradually increasing value during the start-up cycles is concerned, a threshold comparator (92) is preferably provided receiving a signal for measuring the current in the switch in order to generate a signal for disabling the switch should the threshold be exceeded and a means (90) for causing the threshold of the comparator to vary in the following way:
under normal operating conditions the threshold is fixed at a first value;
at the beginning of the first phase of each very low frequency periodic cycle, the threshold passes suddenly from the first value to a second value corresponding to a lower current in the switch;
during the first phase of each cycle the threshold passes gradually back from the second value to the first one.
BRIEF DESCRIPTION OF THE DRAWINGS
Other features and advantages of the invention will be clear from the following detailed description made with reference to the accompanying drawings in which:
FIG. 1 shows a general chopped power supply diagram using two integrated circuits placed respectively on the primary side and on the secondary side of a transformer,
FIG. 2 shows a diagram of an integrated circuit for controlling the power transistor placed on the primary side,
FIGS. 3 to 6 show timing diagrams of signals at different points of the circuit, and
FIG. 7 shows a circuit detail for producing a variable threshold.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring again to FIG. 1, which represents a chopped power supply architecture given by way of example illustrating the utility of the invention, the line of the public electric mains has been designated by the reference 10 (mains at 100 or 220 volts, 50 or 60 hertz). This line is connected through a filter 12 to the input of a rectifier bridge 14 whose output is connected on the one hand to a primary electric ground, shown throughout by a black triangle pointing downward and, on the other hand, to one end of the primary winding EP of the power transformer TA.
A filtering capacitor 16 is placed in parallel across the outputs of the rectifier bridge 14. The other end of the primary winding is connected to the collector of a switching transistor TP whose emitter is connected to the primary ground through a small current measuring resistor 18.
The transformer has several secondary windings which are preferably isolated galvanically from the mains and connected for exmaple to a secondary electric ground isolated galvanically from the primary ground.
Here, each of the secondary windings has one end connected to the secondary ground. The other end feeds a respective low pass filtering capacitor through a respective rectifier diode.
The description hereafter will refer to a single secondary winding ES1, connected by a diode 20 to a capacitor 22. The DC output voltage of the chopped power supply is the voltage Vs at the terminals of the capacitor 22; but of course other DC output voltages may be obtained at the terminals of the other filtering capacitors connected to secondary windings. These output voltages forms stabilized power supply voltages for user circuits not shown. By way of example, a secondary winding ES2 supplies a stabilized voltage of a few volts for the integrated regulation circuit CI2, which has already been discussed. It can be verified therefore in this connection that this circuit is not fed with power and cannot therefore deliver signals as long as the chopped power supply is not operating.
The same goes a priori for the integrated circuit CI1 controlling the base of the power transistor TP, which circuit is supplied with a stabilized voltage delivered from a secondary winding ES3, a diode 24 and a capacitor 26 (it will be noted in passing that this winding, although a secondary winding, is connected to the primary ground and not to the secondary ground, for the very simple reason that the integrated circuit CI1 is necessarily coupled galvanically to the primary).
However, since start-up of the chopped power supply must be ensured, it is provided for the power supply terminal 28 of the integrated circuit CI1 to be also connected directly to the mains through a high resistor 30 and a diode 32; this is possible since the integrated circuit CI1 is connected to the primary gorund; this is not possible for the integrated circuit CI2 which must remain galvanically isolated from the mains. As soon as the chopped power supply is operating normally, the stabilized DC voltage delivered by winding ES3 and diode 24 take precedence over the voltage from the mains and diode 32; this diode 32 is disabled and the direct supply from the mains no longer occurs after the initial start-up phase.
The role of integrated circuits CI1 and CI2 will now be described.
The regulation circuit CI2 receives, from a divider bridge 34 placed at the terminals of the capacitor 22 that is to say at the output of the stabilized power supply, information concerning the value of the voltage to be stabilized Vs.
This information is compared with a reference value and applied to a pulse width modulator which produces periodic square waves of variable width depending on the value of the output voltage Vs; the lower Vs the wider the square waves.
The square waves are produced at the chopping frequency of the chopped power supply. This frequency is therefore established on the secondary side of the circuit; it is generated either inside circuit CI2, or outside in a circuit not shown, in the form of a saw tooth voltage at the chosen chopping frequency. This saw tooth voltage is used in a way known per se for obtaining width modulation.
The variable width square waves, at the chopping frequency, are applied to a primary winding 36 of a small transformer TX whose secondary winding 38, isolated galvanically from the primary, delivers positive and negative pulses at the rising and falling fronts respectively of the variable width square waves.
It is these pulses, whose position and frequency are determined by the regulation circuit CI2, which form regulation signals applied to an input 40 of the base control circuit CI1.
Transformer TX is formed by a few turns wound on a ferrite rod, the turns of the primary and the turns of the secondary being sufficiently spaced apart from each other for complying with the standards of galvanic isolation between primary circuits and secondary circuits in the chopped power supply.
The integrated base control circuit CI1 comprises different inputs among which have already been mentioned a power supply input 28 and a regulation signal input 40; a current measuring input 44 is connected to the current measuring resistor 18; an inhibition input monitors the magnetization condition of a transformer. Finally, inputs may be provided for connecting elements (resistors, capacitors) which should form part of the integrated circuit itself but which, for technological reasons (space) or for practical reasons (possiblities of adjustment by the user) are mounted on the outside.
The integrated circuit CI1 finally comprises an output 46 which is intended to be coupled by direct galvanic coupling to the base of the power transistor Tp. This output delivers square waves for enabling and disabling the transistor Tp.
FIG. 2 shows the general architecture of the integrated circuit CI1, limited to the elements which relate more particularly to the invention.
The output 46 of the circuit is the output of a push-pull amplification stage designated as a whole by the reference 48, this stage comprising preferably two separate amplifiers one of which receives enabling square waves and the other of which receives disabling signals formed by enabling square waves inverted and delayed by a few microseconds. Such amplifiers are now well known.
The enabling signals are delivered by a logic flip flop 50 having a set input 52 and a reset input 54. The set input causes the power transistor to be enabled. The reset input causes it to be disabled.
The set input 52 receives the pulses which pass through a logic AND gate 58, so that enabling only occurs if several conditions are simultaneously satisfied; one unsatisfied condition will be sufficient to inhibit enabling.
The reset input 54 receives the pulses which pass through a logic OR gate 60, so that disabling (after enabling) will occur as soon as a disabling signal is present at one of the inputs of this gate.
In the diagram of FIG. 2, the AND gate 58 has three inputs. One of these inputs receives periodic pulses from an output 62 of a high frequency oscillator 64; the other inputs serve for inhibiting the transmission of these pulses.
The oscillator defines the periodicity of the chopping of the power supply (20 kilohertz for example). Under normal operating conditions, the oscillator is synchronized by the regulation signals; under start-up conditions, it is self oscillating at a free frequency defined by the values of a resistor Ro and a capacitor Co external to the integrated circuit CI1 and connected respectively to an access terminal 66 and an access terminal 68. The free frequency fo is in theory slightly lower than the normal chopping frequency.
Oscillator 64 is a relaxation oscillator which produces at an output 70 a saw tooth whose zero return is caused by the appearance of a positive pulse arriving at terminal 40. This is why oscillator 64 is shown with one input connected to an output 72 of a separation and shaping circuit 74 which receives the regulation signals from terminal 40 and shapes them while separating the positive pulses from the negative pulses. The shaping circuit 74 has two outputs; 72 for the positive pulses, 76 for the negative pulses (the notation of positive pulses, negative pulse will be kept for distinguishing the enabling pulses and the disabling pulses even if the shaping circuit produces pulses of the same sign at both its outputs 72 and 76).
Oscillator 64 has two outputs: one output 70 delivering a saw tooth and one output 62 delivering a short pulse at the time of the zero return of the saw tooth.
A pulse width modulator 78 is connected on the one hand to the output 70 of the oscillator and on the other to a reference voltage adjustable by means of a resistor R1 external to the integrated circuit and connected to a terminal 80 giving access to the circuit. Modulator 78 delivers periodic square waves synchronized with the signals of the oscillator, these square waves defining a maximum conduction duration Tmax beyond which the power transistor must be disabled in any case for safety reasons. These square waves and modulator 78 are applied to an input of the OR gate 60. The duration Tmax is adjustable by means of the external resistor R1.
The elements which have just been described ensure the essential part of the operation under normal conditions of the integrated circuit CI1. The following elements are more specifically provided for controlling abnormal operation or start-up of the power supply.
A very low frequency oscillator 82 is connected to an external capacitor C2 through an access terminal 86. This external capacitor allows the very low frequency oscillation to be adjusted. The frequency may be 1 hertz for example.
Oscillator 82 is a relaxation oscillator delivering a saw tooth. This saw tooth is applied on the one hand to a threshold comparator 88 which causes periodic square waves to be produced synchronized with the very low frequency saw tooth of the oscillator. These square waves have a brief duration compared with the period of a saw tooth; this duration is fixed by the threshold of comparator 88; it may be for example be 10% of the period; it must be long compared with the free oscillation period of the high frequency oscillator 64 so that a burst of numerous pulses from the high frequency oscillator may be emitted and used during this 10% of the very low frequency period; this burst defines at start-up attempt during the first part of a start-up cycle; it is followed by a pause during the rest of the period, i.e. during the remaining 90%.
The oscillator only serves at start up; it is inhibited when regulation signals appear at terminal 40 and indicate that the chopped power supply is operating. This is why a control has been shown for inhibiting this oscillator, connected to the output 72 of the shaping circuit 74 through a flip flop 89. This flip flop switches under the action of the pulses appearing at the output 72. It is brought back to its initial state by the output 62 of oscillator 64 when there are no longer any pulses at output 71.
The saw teeth of the very low frequency oscillator are further transmitted to a circuit 90 producing a variable threshold whose purpose is to produce a threshold signal (current or voltage) having a first value Vs1 under normal operating conditions, and a threshold cyclically variable between a first value and a second value under start-up conditions. The method of varying this threshold will be described further on, but it may already be noted that the variation is driven by the very low frequency saw tooth.
The threshold signal produced by circuit 90 is applied to an input of a comparator 92 another input of which is connected to the terminal 44 already mentioned, for receiving at this input a signal representative of the amplitude of the current flowing through the power switch. The output of comparator 92 is applied to an input of the OR gate 60. It therefore acts for disabling the power transistor Tp, after it has been enabled, disabling occurring as soon as overshooting of the threshold (fixed or variable) defined by circuit 90 has been detected.
Another threshold comparator 94 has one input connected to the current measuring terminal 44 whereas another input receives a signal representing a third threshold value Vs3. The third value Vs3 corresponds to a current in the switch higher than the first value Vs1 defined by the circuit 90. The output of comparator 94 is connected through a storage flip flop 96 to an input of the AND gate 58 so that, if the current in the power switch exceeds the third threshold value Vs3, disabling of transistor Tp is not caused (such disabling being caused by the comparator 92) but any new enabling of the transistor is inhibited. Such inhibition lasts until the flip flop 96 is switched back to its initial state corresponding to normal operation.
In theory, this resetting will only take place when the integrated circuit CI1 has ceased to be supplied normally with power and is again switched on. For example, resetting of flip flop 96 is caused through a hysteresis threshold comparator 98 which compares a fraction of the power supply voltage Vcc of the circuit (taken from terminal 28) with a reference value and which resets the flip flop when Vcc first passes above this reference after dropping below another reference value lower than the first one (hysteresis).
Finally, it may be stated that the output of the flip flop 89 (which detects the presence of regulation signals at terminal 40 therefore normal operation of the power supply), is connected to an input of an OR gate 100 which receives at another input the output of comparator 88 so that the output of comparator 88 ceases to inhibit enabling of transistor Tp (inhibition during 90% of the very low frequency cycles) as soon as operation of the power supply has become normal.
OPERATION OF THE BASE CONTROL CIRCUIT
This operation will be described by illustrating it with voltage wave forms inside the chopped power supply and inside the integrated circuit CI1.
(a) Start-up on switching on
At the outset, the integrated circuit is not supplied with power at all.
The voltage at the power supply terminal 28 increases from 0 to a value Vaa which is not the nominal value Vcc but which is a lower value supplied by diode 32 and resistor 30 (cf. FIG. 1) as long as the chopped power supply does not deliver its nominal output voltage Vcc at terminal 28. Vaa is a voltage sufficient for ensuring practically normal operation of all the elements of the circuit CI1. Vaa is also sufficient for reinitializing the flip flop 96 which, as soon as that happens, no longer inhibits enabling of the power transistor Tp.
There are no regulation signals at the input 40. Consequently, the high frequency oscillator oscillates with its free frequency and the very low frequency oscillator also oscillates (it is not inhibited by the flip flop 89 since this latter does not receive any regulation signals from the output 72 of the shaper circuit 74).
The very low frequency oscillator 82 and comparator 88 define periodic cycles of start-up attempts repeated at a very low frequency.
Each cycle comprises a first part defined by the square waves of short duration at the output of comparator 88, and a second part formed by the end of the very low frequency period; the first part is an effective attempt at start-up. The second part is a pause if the effective attempt has failed. The pause lasts much longer than the effective attempt so as to limit power consumption.
During the first part of the cycle, the enabling signals delivered by the high frequency oscillator 64 are allowed to pass through the AND gate 58. They are then prevented from passing. Each pulse from the output 62 of the oscillator 64 enables the transistor Tp. There is therefore a burst of enabling pulses which is emitted for about 10% of the very low frequency period.
During start-up, the current intensities in the transistor tend to be very high. It is essentially comparator 92 which causes interruption of the conduction, after each enabling pulse delivered by oscillator 64, as soon as the current exceeds the threshold imposed by the variable threshold elaboration circuit 90. If comparator 92 does not cause enabling, modulator 78 will do so in any case at the end of the time Tmax.
The threshold elaboration circuit, which delivers to the comparator 90 a first fixed threshold value Vs1 under normal operating conditions (i.e. when the very low frequency oscillator 82 is disabled by the flip flop 89), delivers a variable threshold as a function of the saw tooth of the very low frequency oscillator in in the following way:
at the initial outset of a start-up attempt cycle (beginning of the saw tooth or zero return of the preceding saw tooth), the threshold passes suddenly from the first value Vs1 to a second value Vs2 corresponding to a lower current than the first value, then this threshold increases gradually (because driven by the very low frequency saw tooth) from the second value to the first. The growth time coincides preferably with the duration of a start-up attempt square wave (i.e. about 10% of the very low frequency period).
Then the threshold is stabilized at the first value Vs1 until the end of the period, but in any case if the circuit has not started up at that time, comparator 88 closes gate 58, through the OR gate 100 and inhibits any further enabling of the power transistor during the rest of the very low frequency period (90%). It is then the second part of the start-up attempt cycle which takes place: a pause during which the pulses of oscillator 64 are not transmitted through the AND gate 58.
Thus, the start-up cycles act from two points of view: on the one hand, a burst of enabling pulses is emitted (10% of the time) then stopped (90% of the time) until the next cycle; on the other hand, during this burst, the current limitation threshold passes gradually from its second relatively low value to its normal higher value.
Consequently, if the peak amplitude of the current in transistor Tp is observed during the start-up bursts, it can be seen that in practice it increases linearly from the second value to the first. Thus gradual start-up is obtained by a much more efficient action than that which consists simply for example in causing the duration Tmax to increase from a low value to a nominal value.
If start-up is not successful, a new burst of enabling pulses is transmitted during the first part of the next cycle (it will be recalled that this cycle is repeated about once per second and that the burst may last 100 milliseconds).
If start-up is successful, regulation signals appear at terminal 40. These signals are shaped by circuit 74. They cause the very low frequency oscillator 82 to be stopped by the flip flop 89 which prevents the zero return of the saw tooth. Furthermore, flip flop 89 sends through the OR gate 100 a signal for cancelling out the inhibition effect imposed by the comparator 88. Finally, as soon as start-up is successful, the regulation signals cause the high frequency oscillator 64 to be synchronized.
FIG. 3 illustrates the high frequency signals during the start-up period:
line a: saw tooth at the output 70 of the oscillator 64 (free oscillation at frequency fo, period To),
line b: pulses for enabling the transistor Tp : these pulses coincide with the zero return of the saw tooth signal (output 62 of oscillator 64);
line c: output square waves from modulator 78 defining the maximum cyclic conduction time of the transistor,
line d: pulses delivered comparator 92 when the current in the switch exceeds the threshold (gradually increasing during start up) defined by the circuit 90.
The conduction of transistor Tp, after being enabled by a pulse from line b, is stopped either by the square waves of line c if the current threshold is not exceeded, or by an output pulse from comparator 92.
FIG. 4 shows the very lwo frequency signals during the start-up cycles. The diagrams are not to the same time scale as in FIG. 3 since it will be recalled that an example of the frequency of the high frequency oscillator 64 is 20 kilohertz whereas an example of the very low frequency of oscillator 82 is 1 hertz. The high frequency pulses have however been shown symbolically in FIG. 4, in number more limited than in reality for facilitating the representation.
line e: saw tooth output of the very low frequency oscillator (frequency f2, period T2),
line f: output of comparator 88 showing the first phase (start-up attempt by allowing conduction of transistor Tp) and the second phase (pause by inhibiting the conduction of each very low frequency start up cycle,
line g: pulses delivered by the freely oscillating high frequency oscillator,
line h: bursts of enabling pulses at the output of the AND gate 58,
line i: diagram of the cyclic variation of the threshold produced by circuit 90 during the start-up cycles: fixed value Vs1 in theory, sudden drop to Vs2 at the beginning of the very low frequency saw tooth, and gradual rise from Vs2 to Vs1, driven by the linear growth of the saw tooth, during the start-up burst.
(b) Operation of the power supply under normal established operating
conditions
The very low frequency oscillator is not operating.
The high frequency oscillator is synchronized by the regulation signals.
The zero return of the high frequency saw tooth, coinciding with the positive pulses of the regulation signals, causes enabling of transistor Tp (no inhbition by the AND gate 58 during normal operating conditions). The negative pulses cause disabling, through the OR gate 64, except if such disabling has been caused:
either by overshooting of the first current threshold value, detected by the comparator 92,
or by the modulator 78 if the time interval between the positive pulse and the negative pulse which immediately follows it is greater than the maximum duration Tmax which is allowed.
FIG. 5 shows the high frequency signals under normal operating conditions,
line j: alternate positive and negative pulses received at the input 40 of the circuit (these are the regulation signals defining the times at the beginning and end of conduction of the power transistor Tp),
line k: shaped pulses at the output 72 of the separation and shaping circuit 74: they correspond to the positive pulses only of the regulation signals,
line l: saw tooth at the output 70 of oscillator 62; the saw tooth is synchronized with the regulation signals in that its zero return coincides with the pulses of line k,
line m: pulses at output 62 of oscillator 64; these pulses are emitted during zero returns of the saw tooth of line l,
line n: output square waves of modulator 78 further defining the maximum conduction time of the power transistor;
line o: pulses from the output 76 of the separation and shaping circuit 74: these pulses correspond to the negative pulses of the regulation signals,
line p: as a reminder, pulses have been shown at the output of comparator 92 in the case where the current in the power transistor exceeds the threshold corresponding to Vs1.
The conduction of transistor Tp, after being enabled by a pulse of line k, is normally stopped by the pulse from line o which immediately follows it, or, more exceptionally by the pulses from line p if the threshold Vs1 is exceeded before the apearance of the pulse of line o, or else, by the square waves of line n if the threshold is not exceeded and if the pulse of line o appears after the beginning of a square wave of line n.
FIG. 6 shows the very low frequency signals at the time of passing over from start-up conditions to normal operating conditions (same scale as FIG. 4).
line q: regulation signals at the input 40; these signals are initially absent and appear at a certain moment,
line r: output of the flip flop 89 indicating the absence then the presence of regulation signals,
line s: very low frequency saw tooth which rises to its high level and does not drop again if the output o the flip flop 89 is at the high level (indicating the presence of regulation signals)
line t: output of the OR gate 100 showing initially a square wave of short duration, delivered by comparator 88 and causing a start-up burst (cf. FIG. 4), then blocking at the high level which prevents subsequent inhibition of the AND gate 58 by the comparator 88.
(c) Safety mode in the case of a malfunction
The safety mode consists in fact in establishing start-up cycles as during switch on.
These cycles are triggered by start up of the very low frequency oscillator 82 when the regulation signals disappear at input 40.
Flip flop 89 returns to an intial state when it no longer receives pulses from the output 72 of the separation and shaping circuit 74. Thus, oscillator 82 will be able to oscillate again and the above described cycles are established.
(d) Serious incident: very high over current
Whatever the operating conditions, normal or start-up, over-currents in transistor Tp are detected by the comparator 92 and cause interruption of the conduction. But if there is for example a short circuit at the output of the power supply, an over-current may occur such that the current continues to increase before the conduction has time to be completely interrupted. In this case, it is provided for the threshold comparator 94 to deliver an order inhibiting the enabling when the current in transistor Tp exceeds a third threshold value which is for example greater by 30% than the first value. This inhibition order is stored by flip flop 96 which switches under the action of the comparator and disables the AND gate 58; flip flop 96 can only come back to its initial state when the integrated circuit, after having partially or totally ceased to be supplied with power, is again normally supplied. For example, the power supply must be switched off and switched on again to allow pulses to pass again for enabling the transistor Tp.
To
finish this description, there has been shown in FIG. 7 one example of
the circuit 90 which produces a variable threshold for the comparator
92: the very low frequency saw tooth deliveredy by the oscillator is
applied to a voltage/current converter 102 which produces a saw tooth
current increasing from 0 to a maximum value.
This current is
applied to a series assembly of a voltage source 104 (value Vs2) and a
resistor 106. A voltage clipper, represented by a Zener diode 108 (value
of the conduction threshold: Vs1) is connected in parallel across the
assembly 104, 106. The junction point between the output of the
converter 102, resistor 106 and the voltage clipper 108 forms the output
of circuit 90 and is connected to the input of comparator 92. Thus,
when the saw tooth returns to zero, the output voltage of circuit 90 is
Vs2. Then it increases as the current in the resistor 106 increases
(linearly). When the voltage at the terminals of resistor 106 reaches
and exceeds the value Vs1-Vs2, the voltage clipper conducts and diverts
the current surplus so that the output voltage remains limited to Vs1.
THOMSON TEA2162 / TEA2164 / TEA2165 WORKING OF CONTROL CIRCUIT FOR A CHOPPED POWER SUPPLY WITH PROGRESSIVE START UP :
A chopped power supply control circuit is provided intended to receive regulation control signals and to produce square waves for enabling a switch. A current comparator measures the current in the switch and opens the switch when the threshold is exceeded. Under normal operating conditions the threshold is fixed. Under start-up conditions of should a malfunction occur a threshold variation circuit causes the threshold to vary gradually from a low value to its normal value. Thus the risk of over-current at start-up is reduced.
1.
A chopped power supply control circuit intended to receive regulation
control signals and to produce square waves for enabling a mains switch
of the power supply, wherein said square waves having a variable width
depending on the signals received, said circuit comprising:
a
current limiting circuit including a threshold comparator receiving at
one input a signal and at another input a threshold signal;
a
means for said comparator to generate a signal for disabling the switch
when the threshold is exceeded, in order to ensure gradual start-up of
the chopped power supply at the beginning of its operation and in the
case of a disturbance of operation;
a means for establishing a variable threshold signals in response to circuit means which
establish a first fixed threshold value under normal established operating conditions,
establish periodically a threshold variation cycle in the opposite case, this cycle comprising
means
to cause the threshold to pass to a second value at a time representing
the beginning of a periodic threshold variation cycle, the second
threshold value corresponding to a lower current in the switch,
means to bring the threshold gradually back from the second value to the first in a first part of the threshold variation cycle,
means for maintaining the threshold at the first value until the end of the current cycle,
means
to begin a second start-up cycle again at the end of the current cycle
if regulation control signals are still not received at the end of the
first cycle,
means for stopping the establishment of threshold variation cycles when regulation control signals are received.
2.
The control circuit as claimed in claim 1 wherein the first part of
each periodic cycle corresponds to a short time compared with the period
of the cycle and a long time compared with the switching period of the
chopped power supply.
3. The control circuit as claimed in claim
1, wherein a very low frequency oscillator is provided for defining the
periodic two phase threshold variation cycles, said oscillator being
inhibited by the reception of appropriate regulation control signals.
4.
The control circuit as claimed in claim 3, wherein said very low
frequency oscillator is a relaxation oscillator delivering a saw tooth
signal driving the threshold establishment means for establishing:
a sudden variation of the threshold at the time of the zero return of the saw tooth,
a slow linear increase of the threshold at the beginning of the saw tooth.
5.
The control circuit as claimed in claim 4, wherein a high frequency
oscillator is provided producing chopping signals palliating the absence
of regulation signals for the production of square waves enabling the
switch and an inhibition means for allowing transmission of these
signals only during the first phase of each periodic cycle.
6.
The control circuit as claimed in claim 5, wherein said high frequency
oscillator has a free oscillation period slightly greater than the
period of the regulation control signals and it is synchronized by these
signals when they are received.
7. The control circuit as
claimed in claim 1, wherein a second threshold comparator is provided
for receiving a signal representative of the current in the switch and
delivering a signal completely inhibiting enabling of the switch in the
case where the current in the switch exceeds a third threshold value
greater than the first value, the signal only ceasing when the circuit,
after having partially or totally ceased to be supplied with power, is
again normally supplied.
Description:
BACKGROUND OF THE INVENTION
The present invention relates to stabilized power supplies called chopped supplies.
A
chopped power supply operates in the following way: a primary transfer
winding receives a current which is for example delivered by a rectifier
bridge receiving the power of the AC mains. The current in the
transformer is chopped by a switch (for example a power transistor)
placed in series with the primary winding.
A circuit for
controlling the transistor produces periodic square waves for enabling
the transistor. A current is allowed to pass for the duration of the
square waves; outside the square wave, the current cannot pass.
On
one (or more) secondary windings of the transformer, an AC voltage is
collected. This is rectified and filtered so as to obtain a DC voltage
which is the output DC voltage of the chopped power supply.
For
stabilizing the value of this DC voltage, the cyclic period conduction
ratio of the switch is adjusted, that is to say the ratio between the
duration of conduction and the duration of non conduction in a chopping
period.
In
chopped power supply architecture proposed by the applicant and shown
in FIG. 1, two integrated circuits are used. One of the circuits CI1,
serves for controlling the base of a power transistor Tp for applying
thereto periodic enabling and disabling control signals. The base
control circuit CI1 is placed on the primary winding side (EP) of the
transformer (TA) for reasons which will be better understood in the rest
of the description. The other integrated circuit, regulation circuit
CI2, is on the contrary placed on the secondary side (winding ES1) and
it serves for examining the output voltage Vs of the power supply for
forming regulation signals which it transmits to the first integrated
circuit through a small transformer TX. The first integrated circuit CI1
uses these regulation signals for modifying the cyclic conduction ratio
of the switching transistor Tp and thus regulating the output voltage
Vs of the power supply.
We will come back further on in more detail to the circuit of FIG. 1.
Numerous problems arise during the design of a chopped power supply, and here we will consider more particularly the problems of starting up the supply and the problems of safety in the case of over voltages or over currents at different points in the circuit.
The first problem which is met with is that of starting up the power supply: at switch on, the regulation circuit CI2 will tend to cause the base control circuit CI1 to generate maximum cyclic ratio square waves until the power supply has reached its nominal output voltage. This is all the more harmful since there is a high current drain on the side of the secondary windings which are connected to initially discharged filtering capacitors. There is a risk of destruction of the power transistor through an overcurrent during the start up phase.
Circuits for gradual start up have already been proposed which limit the duration of the enabling square waves during a start up phase, on switching on the device; the U.S. Pat. No. 3,959,714 describes such a circuit in which charging of a capacitor from switch-on defines initially short square waves of gradually increasing duration until these square waves reach the duration which the regulation circuit normally assigns to them. The short square waves have priority; but, since they become gradually longer during the start up phase, they cease to have priority after a certain time; this time is defined by the charging time constant of the capacitor.
Another problem to be reckoned with is the risk of accidental over-currents, or sometimes over-voltages which may occur in the circuit. These overcurrents and over-voltages may be very detrimental and often result in the destruction of a power transistor if nothing is done to eliminate them. In particular, a short circuit at the output of the stabilized power supply rapidly destroys the power transistor. If this short circuit occurs on switching-on of the supply, it is not the gradual start up system with short and progressively increasing square waves which can efficiently accomodate the over-currents which result from this short circuit.
Finally, another problem particularly important in an architecture such as the one shown in FIG. 1, is the risk of disappearance of the regulation signal which should be emitted by the regulation circuit CI2 and received by the base control circuit CI1: these signals determine not only the width of the square waves enabling the power transistor but also their periodicity; in other words, they serve for establishing the chopping frequency, possibly synchronized from a signal produced on the secondary side of the transformer. The appearance of these signals causes a particular disturbance which must be taken into account.
Furthermore, the architecture shown in FIG. 1, in which the secondary circuits have been voluntarily separated galvanically from the primary circuits, is such that the base control circuit may operate rapidly after switch-on, as will be explained further on, whereas the regulation circuit CI2 can only operate if the chopped power supply is operating; consequently, at the beginning, the base control circuit CI1 does not receive any regulation signals and this difficulty must be taken into account.
SUMMARY OF THE INVENTION
To try and overcome as well as possible all these different problems which relate to security against accidental disturbances in the operation of the power supply (the initial start up being more-over considered as a transitory disturbed operating phase), the present invention provides an improved chopped power supply control circuit which provides a function of gradual start-up power supply on switch on and a function of passing to a safety mode in the case of an operating defect such as a disappearance of appropriate regulation signals; the safety mode consists of a succession of periodic cycles at a very low frequency, each cycle consisting of a gradual start-up attempt during a first phase which is short in comparison with the period of the cycle and long compared with the chopping period of the chopped power supply, the first phase being followed by a pause until the end of the cycle, and periodic cycles succeeding each other until normal operation of the power supply is established or re-established; a very low frequency oscillator establishes these cycles when the power supply is not operating under normal conditions (start-up or operating defect); this oscillator is disabled should normal operation be ascertained; a high frequency oscillator generates a burst of chopping signals palliating the absence of regulation signals; these signals are transmitted solely during the first phase of each cycle; they are inhibited during a second phase.
According to a very important characteristic of the invention, the gradual start up operates not by limiting the duration of the square waves from the charging of a capacitor with a fixed time constant, but by limiting the current in the power transistor to a maximum value, this maximum value increasing progressively during the start up phase, over-shooting of this current value causing interruption in the conduction of the power transistor.
Thus, even in the case of a quasi short circuit, the value of the current in the transistor is limited, which was not the case in the gradual start up circuits of the prior art.
More precisely, the chopped power supply control circuit of the invention is intended to receive regulation control signals and to produce square waves for enabling a main switch of the power supply, the square waves having a variable width depending on the signals received, and this circuit comprises a current limiting circuit including a threshold comparator receiving at one input a signal representative of the current flowing through the switch and at another input a threshold signal, the comparator generating a signal for stopping the switch from conducting should over shooting of the threshold occur; furthermore, in order to ensure gradual start-up of the chopped power supply at the beginning of its operation and should this operation be disturbed, the control circuit comprises a means for producing a variable threshold signal for the comparator, this means being adapted for:
establishing a first fixed threshold value under normal operating conditions,
establishing a periodic threshold variation cycle outside normal operating conditions, this cycle consisting in:
causing the threshold to pass suddenly from the first value to a second value, at a time representing the beginning of the cycle, the second value corresponding to a lower current in the switch,
bringing the threshold gradually back from the second value to the first in a first part of the threshold variation cycle,
holding the threshold at the first value until the end of the current cycle,
beginning again a second threshold variation cycle at the end of the current cycle,
stopping the production of threshold variation cycles when normal operating conditions have again been established.
Normal operating conditions will in general be defined by the presence of appropriate regulation signals and by the absence of an over-current in the switch.
The periodic cycle is at very low frequency (for example 1 hz), and the duration of a first part of the cycle is preferably small with respect to the period of the cycle (for example a tenth of this period, followed by a pause during the nine remaining tenths); it is long with respect to the chopping period of the power supply.
In order to provide even more complete safety, a second threshold comparator is preferably provided receiving at one input a signal respresentative of the measurement of the current in the switch and at another input a third threshold value corresponding to a current greater than that of the first threshold value, the comparator delivering a signal for complete inhibition of the switching of the power switch should over-shooting of this third value occur, the inhibition only ceasing when the circuit, after having partially or completely ceased to be supplied with power, is again normally supplied.
BRIEF DESCRIPTION OF THE DRAWINGS
Other features and advantages of the invention will be clear from reading the following detailed description made with reference to the accompanying drawings in which:
FIG. 1 shows a general chopped power supply diagram using two integrated circuits placed respectively on the primary side and on the secondary side of a transformer,
FIG. 2 shows a diagram of the integrated control circuit of the power transistor placed on the primary side,
FIGS. 3 to 6 show timing diagrams of signals at different points on the circuit, and
FIG. 7 shows a detail of a circuit for elaborating a variable threshold.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Referring to FIG. 1 which shows a chopped power supply architecture given by way of example and well illustrating the utility of the invention, the electric mains line has been designated by the reference 10 (mains at 110 to 220 volts, 50 or 60 hertz). This line is connected through a filter 12 to the input of a rectifier bridge 40 whose output is connected on the one hand to a primary electric ground, represented everywhere by a downward pointing black triangle, and on the other hand to one end of the primary winding EP of the power supply transformer TA.
A filtering capacitor 16 is placed in parallel across the outputs of the rectifier bridge 14. The other end of the primary winding is connected to the collector of a switching transistor TP whose emitter is connected to the primary ground through a small current measuring resistor 18.
The transformer has several secondary windings which are preferably isolated galvanically from the mains and connected for example to a secondary electric ground isolated galvanically from the primary ground.
Here, each of the secondary windings has one end connected to the secondary ground. The other end feeds a respective low-pass filtering capacitor through a respective rectifier diode.
We will be concerned in what follows with a single secondary winding ES1, connected by a diode 20 to a capacitor 22. The DC output voltage of the chopped power supply is the voltage Vs at the terminals of the capacitor 22; but of course, other DC output voltages may be obtained at the terminals of the other filtering capacitors connected to the secondary windings. These output voltages form stabilized power supply voltages for user circuits not shown. By way of example, a secondary winding ES2 supplies a stabilized power supply voltage of a few volts for the integrated regulation circuit CI2 already mentioned. It can therefore be seen in this connection that this circuit is not supplied with power and cannot therefore supply signals as long as the chopped power supply is not operating.
The same goes a priori for the integrated circuit CI1 controlling the base of the power transistor TP, which circuit is supplied with a stabilized voltage delivered by a secondary winding ES3, a diode 24 and a capacitor 26 (it will be noted in passing that this winding, although being a secondary winding, is connected to the primary ground and not to the secondary ground, for the very simple reason that the integrated circuit CI1 is necessarily coupled galvanically to the primary).
However, since start up of the chopped power supply must be provided, the power supply terminal 28 of the integrated circuit CI1 is also connected directly to the mains through a high resistor 30 and a diode 32; this is possible since the integrated circuit CI1 is connected to the primary ground; it is not possible for the integrated circuit CI2 which must remain galvanically isolated from the mains. As soon as the chopped power supply is operating normally, the stabilized DC voltage from winding ES3 and diode 24 takes precedence over the voltage coming from the mains and from diode 32; this diode 32 is disabled and the direct supply by the mains only takes place after the initial start up phase.
The role of the integrated circuits CI1 and CI2 will now be described.
The regulation circuit CI2 receives from a divider bridge 34, placed at the terminals of capacitor 22, i.e. at the output of the stabilized power supply, information concerning the value of the voltage to be stabilized Vs.
This information is compared with a reference value and applied to a pulse width modulator which forms periodic square waves of variable width depending on the value of the output voltage Vs: the lower Vs the wider the square waves will be.
The square waves are established at the chopping frequency of the chopped power supply. This frequency is therefore established on the secondary side of the circuit; it is generated either inside the circuit CI2, or outside in a circuit not shown, in the form of a saw tooth voltage at the chosen chopping frequency. This saw tooth voltage is used in a way known per se for providing width modulation.
The variable width square waves, at the chopping frequency, are applied to a primary winding 36 of a small transformer TX whose secondary winding 38, isolated galvanically from the primary, delivers positive and negative pulses at the rising and falling fronts respectively of the variable width square waves.
It is these pulses, whose position and frequency are determined by the regulation circuits CI2, which form regulation signals applied to an input 40 of the base control circuit CI1.
The transformer TX is formed by a few turns wound on a ferrite rod, the turns of the primary and the turns of the secondary being sufficiently spaced apart from each other for complying with standards of galvanic isolation between primary circuits and secondary circuits of the chopped power supply.
The integrated base control circuit CI1 comprises different inputs among which have already been mentioned a power supply input 28 and a regulation signal input 40; a current measuring input 44 is connected to the current measuring resistor 18; an inhibition input for monitoring the magnetization condition of a transformer. Finally, inputs may be provided for connecting elements (resistors, capacities) which should form part of the integrated circuit itself but which for technological reasons (space limitation) or for practical reasons (possibilities of adjustment by the user) are mounted outside.
The integrated circuit CI1 finally comprises an output 46 which is intended to be connected by direct galvanic coupling to the base of the power transistor Tp. This output delivers square waves for enabling and disabling the transistor Tp.
FIG. 2 shows the general architecture of the integrated circuit CI1, limited to the elements which more especially concern the invention.
The output 46 of the circuit is the output of a push-pull amplification stage designated as a whole by the reference 48, this stage comprising preferably two separate amplifiers one of which receives enabling square waves and the other receives disabling signals formed by the inverted enabling signals delayed by a few microseconds. Such amplifiers are now well known.
The enabling signals are provided by a logic flip flop 50 having a set input 52 and a reset input 54. The set input causes enabling of the power transistor. The reset input causes disabling.
The set input 52 receives the pulses which pass through a logic AND gate 58, so that conduction only occurs if several conditions are satisfied simultaneously; one unsatisfied condition, will be sufficient to inhibit enabling of the conduction.
The reset input 54 receives the pulses which pass through a logic OR gate 60, so that stopping of the conduction (after enabling) will occur as soon as a stop signal is present at one of the inputs of this gate.
In the diagram of FIG. 2, the AND gate 58 has three inputs. One of these inputs receives periodic pulses from an output 62 of a high frequency oscillator 64; the other inputs serve for inhibiting the transmission of these pulses.
The oscillator defines the periodicity of the chopping of the power supply (20 kilohertz for example). Under normal operating conditions, the oscillator is synchronized by the regulation signals; under start-up conditions it is self-oscillating at a free frequency defined by the values of a resistor Ro and a capacitor Co external to the integrated circuit CI1 and connected respectively to an access terminal 66 and an access terminal 68. The free frequency fo is generally slightly lower than the normal chopping frequency.
Oscillator 64 is a relaxation oscillator which produces at an output 70 a saw tooth whose return to zero is caused by the appearance of a positive pulse at terminal 40. This is why oscillator 64 is shown with one input connected to an output 72 of a shaping and separation circuit 74 which receives the regulation signals from terminal 40 and shapes them while separating the positive pulses from the negative pulses. The shaping circuit. 74 has two outputs: 72 for the positive pulses, 76 for the negative pulses (the notation positive pulse and negative pulse will be kept for distinguishing the pulses causing conduction and the pulses stopping conduction even if the shaping circuit establishes pulses of the same sign at both its outputs 72 and 76).
The oscillator 64 has two outputs: one output 70 delivering a saw tooth and one output 62 delivering a short pulse during the zero return of the saw tooth.
A pulse width modulator 78 is connected on the one hand to the output 70 of the oscillator and on the other to a reference voltage adjustable by means of a resistor R1 external to the integrated circuit and connected to a terminal 80 giving access to the circuit. Modulator 78 supplies periodic square waves synchronized with the signals of the oscillator, these square waves defining a maximum conduction time Tmax beyond which the power transistor must be disabled in any case for safety's sake. These square waves of modulator 78 are applied to one input of the OR gate 60. The time Tmax is adjustable by means of the external resistor R1.
The elements which have just been described ensure the essential part of the operation under normal conditions of the integrated circuit CI1. The following elements are more specifically provided for controlling the abnormal operation or start-up of the power supply.
A very low frequency oscillator 82 is connected to an external capacitor C2 through an access terminal 86. This external capacitor allows the very low oscillation frequency to be adjusted. The frequency may be 1 hertz for example.
Oscillator 82 is a relaxation oscillator delivering a saw tooth. This saw tooth is applied on the one hand to a threshold comparator 88 which allows periodic square waves to be established synchronized with the very low frequency saw tooth of the oscillator. These square waves have a very short duration compared with the period of the saw tooth; this duration is set by the threshold of the comparator 88; it may for example be 10% of the period; it must be long compared with the free oscillation period of the high frequency oscillator 64 so that a burst of numerous pulses from the high frequency oscillator may be emitted and used during this 10% of this very low frequency period; this burst defines a start-up attempt during the first part of a start-up cycle; it is followed by a pause for the rest of the period, i.e. during the remaining 90%.
The oscillator only serves at start-up; it is inhibited when regulation signals appear at terminal 40 and indicate that the chopped power supply is operating. This is why an inhibition control of this oscillator has been shown connected to the output 72 of the shaping circuit 74 through a flip flop 89. This flip flop changes state under the action of the pulses appearing at output 72. It is brought back to its initial state by the output 62 of oscillator 64 when there are no longer any pulses at output 72.
The saw teeth of the very low frequency oscillator are further fed to a variable threshold elaboration circuit 90 whose purpose is to establish a threshold signal (current or voltage) having a first value Vsl under normal operating conditions, and a cyclically variable threshold between the first value and a second value under start-up conditions. The mode of variation of this threshold will be described further on, but it may already be noted that the variation is driven by the very low frequency saw tooth.
The threshold signal produced by circuit 90 is applied to one input of a comparator 92, another input of which is connected to the terminal 44 already mentioned, for receiving at this input a signal representative of the amplitude of the current flowing through the power switch. The output of comparator 92 is applied to an input of the OR gate 60. It operates then for causing the power transistor Tp to be disabled, after being enabled, disablement occurring as soon as overshooting of the threshold (fixed or variable) defined by circuit 9 has been detected.
Another threshold comparator 94 has one input connected to the current measuring terminal 44 whereas another input receives a signal representing a third threshold value Vs3. The third value Vs3 corresponds to a current in the switch higher than the first value Vsl defined by circuit 90. The output of comparator 94 is connected through a storage flip flop 96 to one input of the AND gate 58 so that, if the current in the power switch exceeds the third threshold value Vs3, transistor Tp is not disabled (such disablement is caused by comparator 92) but the transistor is inhibited from being enabled again. This inhibition lasts until the flip flop 96 is brought back to its initial state corresponding to normal operation.
In theory, such re-setting will only take place when the integrated circuit CI1 has ceased to be normally supplied with power and has again power applied thereto.
For example, re-setting of flip flop 96 takes place through a hysteresis threshold comparator 98 which compares a fraction of the supply voltage Vcc of the circuit (taken from terminal 28) with a reference value and which re-sets the flip flop the first time that Vcc passes above this reference after a drop of Vcc below another reference value lower than the first one (hysteresis). Finally, it should be mentioned that the output of the flip flop 89 (which detects the presence of regulation signals at terminal 40 so normal operation of the power supply), is connected to one input of an OR gate 100 which receives at another input the output of the comparator 88 so that the output of comparator 88 ceases to inhibit the re-enabling of transistor Tp (inhibition during 90% of the very low frequency cycles) as soon as the operation of the power supply has become normal.
OPERATION OF THE BASE CONTROL CIRCUIT
This operation will be described by illustrating it with voltage wave forms within the chopped power supply and within the integrated circuit CI1.
(a) Start-up on switching on
At the beginning the integrated circuit is not at all supplied with power.
The voltage at the power supply terminal 28 increases from 0 to a value Vaa which is not the nominal value Vcc but which is a lower value supplied by diode 32 and resistor 30 (compare FIG. 1) as long as the chopped power supply does not deliver its nominal output voltage Vcc at terminal 28. Vaa is a sufficient voltage for ensuring practically normal operation of all the elements of the circuit CI1. Vaa is also sufficient for reinitializing the flip flop 96 which, from then on, no longer inhibits the enabling of the power transistor Tp.
There are no regulation signals at the input 40. Consequently, the high frequency oscillator oscillates at its free frequency and the very low frequency oscillator also oscillates (it is not inhibited by the flip flop 89 since this latter does not receive any regulation signals from the output 72 of the shaping circuit 74).
The very low frequency oscillator 82 and the comparator 88 define periodic cycles of start-up attempts repeated at very low frequency.
Each cycle comprises a first part defined by the square waves of short duration at the output of the comparator 88, and a second part formed by the end of the very low frequency period; the first part is an effective attempt at start-up. The second part is a pause if the effective attempt has failed. The pause lasts much longer than the effective attempt so as to limit power consumption. During the first part of the cycle, passage of the enabling signals from the high frequency oscillator 64 is allowed through the AND gate 48. Then it is prohibited. Each pulse from the output 62 of the oscillator 64 triggers off the enabling of transistor Tp. There is then a burst of triggering pulses which is emitted for about 10% of the verylow frequency period.
During start up, the current intensities in the transistor tend to be high. It is essentially the comparator 92 which causes interruption of the conduction, after each enabling pulse supplied by oscillator 64, as soon as the current exceeds the threshold imposed by the variable threshold elaboration circuit 90. If the comparator 92 does not trigger off interruption of the conduction, the modulator 78 will do it in any case at the end of the duration Tmax.
The threshold elaboration circuit which supplies the comparator 90 with a first fixed threshold value Vs1 under normal operating conditions (i.e. when the very low frequency oscillator 82 is disabled by the flip flop 89), delivers a variable threshold as a function of the saw tooth of the very low frequency oscillator in the following way:
at the initial time of a start-up attempt cycle (start of the saw tooth or return to zero of the preceding saw tooth), the threshold passes suddenly from the first value Vs1 to a second value Vs2 corresponding to a smaller current than for the first value, then this threshold increases progressively (because driven by the very low frequency saw tooth) from the second value to the first one. The duration of the increase coincides preferably with the duration of a start-up attempt square wave (namely about 10% of the very low frequency period).
Then the threshold stabilizes at the first value Vs1 until the end of the period but, in any case, if the circuit has not started up at that time, the comparator 88 closes gate 58 through the OR gate 100 and inhibits any subsequent enabling of the power transistor for the rest of the very low frequency period (90%). It is in this case the second part of the start up attempt cycle which takes place: a pause during which the pulses of the oscillator 64 are not transmitted through the AND gate 58.
Thus the start up cycles act on two levels: on the one hand a burst of enabling pulses is emitted (10% of the time) then stopped (90% of the time) until the next cycle; on the other hand, during this burst, the current limitation threshold passes progressively from its second relatively low value to its normal higher value.
Consequently, if we observe the peak amplitude of the current in transistor Tp during the start-up bursts, it can be seen that it increases practically linearly from the second value to the first value. Therefore gradual start-up is obtained by a much more efficient action than that which consists simply for example in causing the time Tmax to increase from a low value to a nominal value. If start up is not successful, a new burst of enabling pulses is transmitted during the first part of the next cycle (it will be recalled that this cycle is repeated about once per second and that the burst may last 100 milliseconds).
If start-up is successful, regulation signals appear at terminal 40. These signals are shaped by circuit 74. They cause the very low frequency oscillator 82 to stop through the flip flop 89 which prevents the zero return of the saw tooth. Moreover, flip flop 89 sends through the OR gate 100 a signal for cancelling out the inhibition effect imposed by the comparator 88. Finally, as soon as start-up is successful, the regulation signals synchronize the high frequency oscillator 64.
FIG. 3 illustrates the high frequency signals during the start-up period:
line a: saw tooth at the output 70 of the oscillator 64 (free oscillation at frequency fo, period To),
line b: pulses for enabling the transistor Tp : these pulses coincide with the zero return of the saw tooth signal (output 62 of oscillator 64),
line c: output square waves from modulator 78 defining the maximum cyclic conduction time of the transistor,
line d: pulses delivered by the comparator 92 when the current in the switch exceeds the threshold (gradually increasing during start-up) defined by circuit 90.
Conduction of transistor Tp, after being triggered by a pulse from line b, is stopped either by square waves of line c if the current threshold is not exceeded, or by an output pulse from comparator 92.
FIG. 4 shows the very low frequency signals during the start up cycles. The diagrams are not to the same time scale as in FIG. 3 since it will be recalled that an example of the frequency of the high frequency oscillator 64 is 20 kilohertz whereas an example of the very low frequency of oscillator 82 is 1 hertz. The high frequency pulses have however been shown symbolically in FIG. 4, in a more limited number than in reality for facilitating the representation.
line e: saw tooth output of the very low frequency oscillator (frequency f2, period T2),
line f: output of the comparator 88 representing the first phase (start-up attempt by causing transistor Tp to be enabled) and the second phase (pause through inhibiting such enabling) during each very low frequency start-up cycle,
line g: pulses from the freely oscillating high frequency oscillator,
line h: bursts of enabling pulses at the output of the AND gate 58,
line i: diagram of the cyclic variation of the threshold elaborated by circuit 90 during the start up cycles: fixed value Vs1 in theory, sudden drop to Vs2 at the beginning of the very low frequency saw tooth, and gradual rise of Vs2 to Vs1, driven by the linear growth of the saw tooth, during the start-up burst.
(b) Operation of the power supply under normal established operating conditions
The very low frequency oscillator is not operating.
The high frequency oscillator is synchronized by the regulation signals.
The zero return of the high frequency saw tooth, coinciding with the positive pulse of the regulation signals, causes transistor Tp to be enabled (no inhibition by the AND gate under normal operating conditions). The negative pulses cause disablement, through the OR gate 64, unless such disablement has been caused:
either by an overshoot of the first current threshold value, detected by comparator 92,
or by the modulator 78 if the time interval between the positive pulse and the negative pulse which immediately follows it is greater than the maximum duration Tmax which is permitted.
FIG. 5 shows the high frequency signals under normal operating conditions.
line j: alternate positive and negative pulses received at the input 40 of the circuit (these are the regulation signals defining the times at which the power transistor Tp is enabled and disabled),
line k: shaped pulses at the output 72 of the separation and shaping circuit 74: they correspond to the positive pulses only of the regulation signals,
line l: saw tooth at the output 70 of oscillator 64; the saw tooth is synchronized with the regulation signals n so that its zero return coincides with the pulses of line k,
line m: pulses at the output 62 of oscillator 64; these pulses are emitted during zero returns of the saw tooth of line 1,
line n: output square waves of modulator 78, again defining the maximum duration of conduction of the power transistor,
line o: pulses coming from the output 70 of the separation and shaping circuit 74: these pulses correspond to the negative pulses of the regulation signals,
line p: as a reminder, pulses have been shown at the output of comparator 92 in the case where the current in the power transistor overshoots the threshold corresponding to Vs1.
Transistor Tp after being enabled by a pulse from line k is normally disabled by the pulse from line o which immediately follows it, or, more exceptionally by the pulses from line p if the threshold Vs1 has been exceeded before the appearance of the pulse from line o, or else, by the square waves of line n if the threshold has not been exceeded and if the pulse from line o appears after the beginning of a square wave of line n.
FIG. 6 shows the very low frequency signals at the time of going over from start-up conditions to normal operating conditions (same scale as in FIG. 4).
line q: regulation signals at the input 40; these signals are initially absent and appear at a certain moment,
line r: output of the flip flop 89 indicating the absence or the presence of regulation signals,
line s: very low frequency saw tooth which rises to its high level and does not drop again if the output of the flip flop 89 is at the high level (indicating the presence of regulation signals),
line t: output of the OR gate 100 showing initially a square wave of short duration, coming from comparator 88 and allowing a start-up burst (cf. FIG. 4), then blocking at the high level which prevents subsequent inhibition of the AND gate 58 by the comparator 88.
(c) Safety mode in the case of a malfunction
The safety mode consists in fact in establishing start-up cycles as for switching on.
These cycles are triggered off by starting up the very low frequency oscillator 82 when the regulation signals disappear at input 40.
The flip flop 89 goes back to an initial state when it no longer receives pulses from the output 72 of the separation and shaping circuits 74. Thus oscillator 82 will be able to oscillate again and the above described cycles are established.
(d) Serious malfunction: very high over current.
Whatever the operating conditions, normal or start-up, the over-currents in the transistor Tp are detected by the comparator 92 and cause interruption of the conduction.
But if there is for example a short circuit at the output of the power supply, an over-current may occur such that the current continues to increase before the conduction can be completely interrupted. In this case, it is provided for the threshold comparator 94 to supply an enabling inhibition order when the current in transistor Tp exceeds a third threshold value which is for example higher by 30% than the first value. This inhibition order is stored by the flip flop 96 which switches under the action of the comparator and disables the AND gate 58; the flip flop 96 can only come back to its initial state when the integrated circuit, after having partially or totally ceased to be supplied with power, is again normally supplied with power. For example, the power supply must be switched off and switched on again to again allow the passage of pulses for enabling the transistor Tp.
To finish this description, there has been shown in FIG. 7 an example of circuit 90 which elaborates a variable threshold for the comparator 92: the very low frequency saw tooth delivered by the oscillator is applied to a voltage/current converter 102 which produces a current increasing in saw tooth fashion from zero to a maximum value.
This current is applied to a series assembly of a voltage source 104 (value Vs2) and a resistor 106. A voltage clipper, shown by a Zener diode 108 (value of the conduction threshold: Vs1) is placed in parallel across the assembly 104, 106. The junction point between the output of the converter 102, the resistor 106 and the voltage clipper 108 forms the output of circuit 90 and is connected to the input of comparator 92. Thus, at zero return of the saw tooth, the output voltage of circuit 90 is Vs2. Then it increases as the current in resistor 106 increases (linearly). When the voltage at the terminals of resistor 106 reaches and exceeds the value Vs1-Vs2, the voltage clipper conducts and diverts the current surplus so that the output voltage remains limited to Vs1.
THOMSON
TEA2164/TEA2165
EXTENDED OVERLOAD PROTECTION CIRCUIT FOR A SWITCH MODE POWER SUPPLY
HAVING CYCLE DETECTOR, MEMORY AND FLIP-FLOP INHIBITION:
means for detecting cycles for which the first protection circuit is active and interrupts the on state of the main switch prior to the arrival of the order for the off state of the regulation signal;
memorization means accumulating at each cycle a value proportional to the duration between a signal from the detection means and the set signal associated with the regulation signal of the following cycle; and
inhibition means for inhibiting the set input of the flip-flop when the memorization means has accumulated a signal higher than a predetermined threshold;
wherein the means for detecting includes a second flip-flop, a third flip-flop and an AND gate, the second flip-flop receiving at its reset input the starting output of the regulation signal, the set input of the second flip-flop receiving the output of the AND gate and the output of the second flip-flop controlling the memorization means; the third flip-flop having its set input connected to the reset input of the second flip-flop, the reset input of the third flip-flop connected to the reset regulation signal and the output of the third flip-flop connected to a first input of the AND gate; the second input of the AND gate being connected to the output of the first protection circuit.
2. A device for protection according to claim 1, wherein the memorization means comprise a capacitor permanently discharged by a discharging means and temporarily charged by a charging means only when the detection means supplies a signal.
3. A device for protection according to claim 2, wherein the charge and discharge means are current supplies and the charge current supply is connected to the capacitor through a controlled switch actuated by the output of the second flip-flop of the detection means.
4. A device for protection according to claim 1, wherein the inhibition means comprise a comparator comparing the signal accumulated by the memorization means with a reference value, the output signal of this comparator inhibiting the set input of the first flip-flop when the memorized signal becomes higher than a reference value.
5. A device for protection according to claim 4, wherein the output of said comparator is connected to the set input of a fourth flip-flop of which the output is connected to the set input of the first flip-flop through an AND gate of which the other input receives the sginal for triggering the regulation signal.
6. A device for protection according to claim 5, wherein the AND gate connected to the validation input of the first flip-flop receives other inhibition signals issuing from other switch mode power circuits, such as automatic starting control circuits.
Description:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention concerns stabilized power supplies known as "switch mode power supplies".
A switch mode supply functions in the following manner: a primary transformer winding receives a current that is, for example, issuing from a rectifying bridge receiving power from the alternating power mains. The current in the transformer is chopped by a switch (for example a power transistor) placed in series with the primary winding.
A control circuit of the transistor establishes periodic square pulses to turn on the transistor. During the square pulse period current passage is authorized; outside of this square pulse period current passage is prohibited.
On one (or several) secondary winding(s) of the transformer, an alternating voltage is thus received. This voltage is rectified and filtered in order to produce a direct voltage that is the output direct voltage of the switch mode supply.
In order to stabilize the value of this direct voltage, the duty cycle of the switch is modified, i.e. the ratio between the conduction duration and the blocking duration in a chopped period.
FIG. 1 represents by way of example a switch mode power structure manufactured by the applicant in which two integrated circuits are used. One of the circuits, CI1, acts to control the base of a power switching transistor Tp for applying thereto periodic control signals for putting under conduction and blocking control. This base control circuit CI1 is placed on the side of the primary winding EP of the transformer TA for reasons which will become apparent from the description given herein-below. The other integrated circuit, regulation circuit CI2, is on the contrary placed on the side of the secondary winding ES1 and is used to examine the output voltage Vs of the power supply in order to produce regulation signals that it transmits to the first integrated circuit through a small transformer TX. The first integrated circuit CI1 uses these regulation signals to modify the duty cycle of conduction of the switching transistor Tp and thus of adjusting the output voltage Vs of the power supply.
FIG. 1 shows the line of the public electric distribution mains under reference 10 (local supply circuit or mains at 110 or 220 volts, 50 or 60 hertz). This line is connected through a filter 12 to the input of a rectifying bridge 14, the output of which is connected on the one hand to a primary electric mass, represented throughout by a black triangle pointing downwards, and on the other hand to one end of the primary winding EP of the supply transformer TA.
A filtering capacitor 16 is placed in parallel on the outputs of the rectifying bridge 14. The other end of the primary winding is connected to the collector of the switching transistor Tp, the emitter of which is connected to the primary mass through a small current measuring resistance 18.
The transformer is provided with several secondary windings that are preferably galvanically insulated from the mains and connected for example to a secondary electric mass galvanically insulated from the primary mass.
In the present description, each of the secondary windings has one end connected to the secondary mass. The other end supplies a respective low-pass filtering capacitor through a respective rectifying diode.
Reference in the following description will be made to a single secondary winding ES1, connected by a diode 20 to a capacitor 22. The direct output voltage of the switch mode supply is the voltage Vs at the terminals of the capacitor 22; but it is well understood that other direct output voltages can be obtained at the terminals of the other filtering capacitors connected to the secondary windings. These output voltages constitute stabilized power supplies for utilization circuits (not represented). By way of example, a secondary winding ES2 supplies a stabilized power voltage of several volts for the regulation integrated circuit CI2 to which reference was made herein-above. It is thus checked that the circuit is not powered and therefore cannot supply signals as long as the switching does not function.
The same is true a priori for the base control integrated circuit CI1 of the power transistor Tp, which circuit is powered by a stabilized voltage supplied from a secondary winding ES3, from a diode 24 and from a capacitor 26 (it will be noted that this winding, although being a secondary winding is connected to the primary ground and not to the secondary mass, this for the very simple reason that the integrated circuit CI1 is necessarily galvanically connected to the primary).
However, as it is necessary to ensure starting of the chopped power supply, it has been foreseen that the power terminal 28 of the integrated circuit CI1 is also directly connected to the mains through a high resistance 30 and a diode 32; this is possible since the integrated circuit CI1 is connected to the primary ground; it is not possible for the circuit CI2 which must remain galvanically insulated from the mains. Once the switch mode power supply functions normally, the stabilized direct voltage issuing from the winding ES3 and from the diode 24 has priority over the voltage issuing from the mains and from the diode 32; this diode 32 is blocked and the direct power supply through the mains no longer intervenes after the initial starting phase.
The role of the integrated circuits CI1 and CI2 will now be defined.
The regulation circuit CI2 receives from a divider bridge 34, placed at the terminals of the capacitor 22, i.e. at the output of the stabilized power supply, data as to the value of the voltage to be stabilized Vs.
This data is compared with a desired value and applied to a pulse width modulator that establishes periodic square pulses having variable width in function of the value of the output voltage Vs; the lower is Vs the larger will be the width of the square pulses.
The square pulses are established at the switching frequency of the switch mode supply. This frequency is thus established on the side of the secondary of the circuit; it is generated either inside the circuit CI2, or outside in a circuit (not shown) in the form of a saw-tooth shaped voltage at the selected switching frequency. This saw-tooth voltage is used in a manner known per se to perform the width modulation.
The variable width square pulses, at the switching frequency, are applied to a primary winding 36 of a small transformer TX, the secondary winding, 38, of which is galvanically insulated from the primary, supplies positive and negative pulses to the rising and descending edges, respectively of the variable width square pulses.
It is these position and frequency pulses determined by the regulation circuit CI2, which constitute regulation signals applied to an input 40 of the base control circuit CI1.
The transformer TX is constituted by several coil turns wound on a ferrite rod, the turns of the primary and the turns of the secondary being sufficiently spaced apart from one another to respect the galvanic insulation standards between primary circuits and secondary circuits of the switch mode supply.
The base control integrated circuit CI1 comprises various inputs among which have been mentioned herein-above a power input 28 and a regulation signal input 40; a current measuring input 44 connected to the current measuring resistor 18; and an inhibition input allowing to check the magnetization state of a transformer. Furthermore, inputs can be provided to connect the elements (resistors, capacitors) that should form part of the integrated circuit itself but which for technological reasons (of bulk) or for practical reasons (possibilities of adjustment by the user) are externally mounted.
The integrated circuit CI1 furthermore comprises an output 46 which is intended to be connected by a direct galvanic connection to the base of the power transistor Tp. This output supplies square pulses for bringing the transistor Tp to the on or off state.
FIG. 2 represents partially the general structure of the integrated circuit CI1.
The output 46 of the circuit, intended for the base control of the transistor Tp, is the output of a push-pull amplification stage designated by the reference 48, this stage preferably comprising two separated amplifiers one of which receives square pulses which are inverted and delayed by several microseconds for to producing to the on state. Such amplifiers are well known.
The signals for switching to the on stae are issued from a logic flip-flop 50 having a set input 52 and a reset input 54. The set input triggers the on state of the power transistor. The reset input triggers the off state.
The set input 52(S) receives the pulses that pass through an AND gate 58, so that the triggering of the on state only occurs when several conditions are simultaneously satisfied; if a single condition is not satisfied, this is sufficient to inhibit the triggering of the on state.
The reset input 54(R) receives the pulses which pass through an OR gate 60, so that the interruption of the on state (after triggering of the on state) occurs once a halt signal is present on one of the inputs of this gate.
On the diagram of FIG. 2, the AND gate 58 has three inputs. One of these inputs receives periodic pulses issuing from an output 62 of a high frequency oscillator 64; the other inputs act to inhibit the transmission of these pulses.
The oscillator defines the switching period of the power supply (20 kilohertz for example). In normal operating state the oscillator 64 is synchronized by the regulation signals. In starting state it is self-oscillating at a free frequency defined by the values of a resistor Ro and of a capacitor Co outside the integrated circuit CI1 and respectively connected to an access terminal 66 and an access terminal 68. The free frequency Fo is as a rule slightly lower than the normal switching frequency.
The oscillator 64 is a relaxation oscillator that produces on an output 70 a saw-tooth, the reset to zero of which is set by the appearance of a positive pulse arriving at the terminal 40. This is the reason why the oscillator 64 is represented with an input connected to an output 72 of a separation and shaping circuit 74 that receives the regulation signals from the terminal 40 and shapes them by separating the positive pulses from the negative pulses. The shaping circuit 74 has two outputs: 72 for the positive pulses, 76 for the negative pulses (the notation of positive pulse and negative pulse will be retained in order to distinguish the triggering pulses for the on state and the triggering pulses for the off state even if the shaping circuit establishes pulses of a single sign on its two outputs 72 and 76).
The oscillator 64 has two outputs; an output 70 supplying a saw-tooth signal and an output 62 supplying a short pulse when the saw-tooth is reset to zero.
A pulse width modulator 78 is connected on the one hand to the output 70 of the oscillator and on the other hand to an adjustable reference voltage through a resistor R1 outside the integrated circuit and connected to an access terminal 80 to the circuit. The modulator 78 supplies periodic square pulses synchronized with the oscillator signals, these square pulses defining a maximal duration of the on state Tmax beyond which the off state of the power transistor must be triggered in any case as a matter of security. These square pulses of modulator 78 are applied to an input of the OR gate 60. The duration Tmax is adjustable through the external resistor R1.
The elements that have been described herein-above ensure the essential of the operating at normal condition of the integrated circuit CI1. The following elements are more specifically provided for controlling the anomalous operating or the starting of the power supply.
A very low frequency oscillator 82 is connected to an external capacitor C2 through an access terminal 86. This external capacitor adjusts the very low oscillation frequency. The frequency can be 1 hertz, for example.
The oscillator 82 is a relaxation oscillator supplying a saw-tooth signal which is applied on the one hand to a threshold comparator 88 which establishes periodic square pulses which are synchronized on the saw-tooth at a low frequency of the oscillator. These square pulses have a brief duration compared to the saw-tooth period. This duration is fixed by the threshold of the comparator 88. It can be for example of 10% of the period. It must be long with respect to the free oscillation period of the high frequency oscillator 64 so that a burst of numerous pulses of the high frequency oscillator can be emitted and utilized during this 10% of the period at very low frequency. This burst defines an attempt at starting during the first part of a starting cycle. It is followed by a pause during the remainder of the period, i.e. during the remaining 90% of the period.
The oscillator 82 only functions for the starting. It is inhibited when the regulation signals appear on the terminal 40 and indicate that the switch mode supply is functioning. This is the reason why an inhibition control of this oscillator has been represented, connected to the output 72 of the shaping circuit 74 through a flip-flop 89 which changes its condition under the effect of the pulses appearing at the output 72. It is returned to its initial condition by the output 62 of the oscillator 64 when there are no more pulses on the output 71.
The saw-tooth signals of the oscillator at very low frequency are furthermore transmitted to a circuit 90 for producing a variable threshold whose function is to establish a threshold signal (current or voltage) having a first value Vs1 in normal operating condition, and a cyclically variable threshold between the first value and a second value at starting condition.
The threshold signal established by the circuit 90 is applied to an input of a comparator 92, the other input of which is connected to the terminal 44 already mentioned, in order to receive on this input a signal that is representative of the amplitude of the current flowing through the power switching device. The output of the comparator 92 is applied to an input of the OR gate 60. It thus triggers the off state of the power transistor Tp, after an on state firing, the off state occuring, when exceeding the threshold (fixed or variable) defined by the circuit 90 has been detected.
Another threshold comparator 94 has an input connected to the current measuring terminal 44 while another input receives a signal representing a third threshold value Vs3. The third value Vs3 corresponds to a current in the switch which is higher than the first value vs1 defined by the circuit 90. The output of the comparator 94 is connected through a latch 96 to an input of the AND gate 58 whereby if the current in the power switch exceeds the third threshold value Vs3, an interruption of the on state of the transistor Tp is not triggered (this interruption is triggered by the comparator 92) but an inhibition of any firing of the transistor. This inhibition lasts until the flip-flop 96 is reset to its initial state corresponding to a normal operating.
As a rule, this return will only occur when the integrated circuit CI1 will have ceased to be normally supplied with power and will be again set under voltage. For example, the return of the latch 96 occurs through a hysteresis threshold comparator 98 which compares one fraction of the power supply voltage Vcc of the circuit (drawn off from the terminal 28) with a reference value and which resets the latch during the first passage of Vcc above this reference after a drop of Vcc below another reference value that is lower than the first one (hysteresis).
Moreover, it can be specified that the output of the flip-flop 89 (which detects the presence of regulation signals on the terminal 40 thus the normal operating of the power supply) is connected to an input of an OR gate 100 which receives on another input the output of the comparator 88 so that the output of the comparator 88 ceases to inhibit the firing of the transistor Tp (inhibition during 90% of the very low frequency cycles) once the operating of the power circuit becomes normal.
OBJECT OF THE INVENTION
Therefore, in the device previously manufactured by the applicant and described in detail herein-above, particular procedures for the starting phases and particular protective procedures in the case of functioning incidents are foreseen.
The present invention aims at further improving the operating safety by detecting operating deficiencies over a longer period of time than was the case with circuits of the prior art. Although the invention presents a novel and distinct contribution with respect to the process of the prior art, the prior device has been described in full detail herein-above in order to render apparent the numerous restrictions which are imposed during production of a novel safety device which must take into account all the possible types of operating foreseen in an already existing circuit without introducing deficiencies or blockages in the normal operating of the circuit in its differnt modes. Consequently, any novel contribution to a complex structure such as that described herein-above requires numerous selections and very numerous attempts between various solutions that could appear a priori as simple must be carried out.
SUMMARY OF THE INVENTION
Therefore, the present invention provides a device for protection against extended overloading in switch mode power supplies comprising a main switch controlled by output signals from a flip-flop of which the inputs for setting to 1 and for resetting to zero receive regulation control signals, a first protection circuit supplying on the input for resetting to zero signals which have priority with respect to the regulation signals when the current in the main switch exceeds a predetermined threshold, further comprising a second protection circuit itself comprising:
means for detecting cycles for which the first protection circuit operates and interrupts the on state of the main switch prior to the arrival of the switching off order of the regulation signal;
memorization means accumulating at each cycle a value proportional to the duration between a signal of the detection means and the setting to 1 signal associated to the regulation signal of the following cycle; and
inhibition means for inhibiting the set input of the flip-flop when the memorization means have accumulated a signal higher than a predetermined threshold.
According to one embodiment of the present invention, the detection means comprise a second flip-flop, a third flip-flop and an AND gate:
the second flip-flop receiving at its reset input the output for starting the regulation, the set input of this flip-flop receiving the output of the AND gate and the output of this flip-flop controlling the memorization means;
the third flip-flop having its set input connected to the reset input of the second flip-flop, its reset input connected to the reset signal of the regulation signal, and its output connected to a first input of the AND gate,
the second input of the AND gate being connected to the output of the first protection circuit.
According to one embodiment of the present invention, the memorization means comprise a capacitor permanently discharged by discharging means and temporarily charged by charging means only when the detection circuit supplies a signal.
According to another embodiment of the invention, the inhibition means comprise a comparator comparing the signal accumulated by the memorization means with a reference value, the output signal of this comparator inhibiting the set input of the flip-flop when the memorized signal becomes higher than a reference value.
BRIEF DESCRIPTION OF THE DRAWING
These objects, features and advantages and others of the present invention will become apparent from the following embodiment given by way of non-limitative illustration with reference to the appended drawing in which:
FIGS. 1 and 2 illustrate a switch mode power supply according to the prior art and have been described herein-above;
FIG. 3 is a simplified representation of a protection circuit against the overloading of a switch mode power supply according to the prior art;
FIG. 4 illustrates the protection circuit against overloads of long duration according to the present invention for switch mode power supplies; and
FIGS. 5-a to to 5-b are time charts intended to illustrates the functioning of the circuits represented in FIGS. 3 and 4.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
FIG. 3 once again represents in a simplified manner the essential components of the circuit represented in FIG. 2 constituting a protection circuit against the excess currents in the main transistor Tp. The on state in the transistor Tp is normally controlled by a signal available on a terminal 40, resulting from a pulse width modulation circuit which controls a flip-flop 50 through a shaping circuit 74. The flip-flop 50 energizes the base of the power transistor Tp through a preamplification circuit (driver) 48 and an access terminal 46. When the current in the power transistor exceeds a given threshold, the voltage at the terminals of a resistor 18 available at the terminal 44 is compared with a threshold voltage Vs by a comparator 92 and, should this voltage exceed the threshold, the reset input R of the flip-flop 50 is energized through an OR gate 60, the other input of which receives an output signal from the shaping circuit 74.
This protection device effectively protects the switch Tp against a current overloading but does not always allow good protection of the power supply, for example in the case of long duration overloading. In fact, there is no protection against excessive heating of the transformer TA or of the rectifying diodes 20 (cf. FIG. 1) or of other components of the circuit connected to the secondary of the main transformer and it is generally necessary to over-size these components in order to take into account long duration overloadings which could occur as a result, for example, of short-circuiting on the secondary winding.
The invention which will be described herein-below with respect to FIGS. 4 and 5 concerns a device which, added to the conventional current limitation circuit described herein-above, provokes the total and definitive shut down of the power supply in the case of long duration functioning of the current limitation system. Expensive over-sizing of certain components is thus avoided and the operating safety of the power supply is as a whole increased.
The restarting of the power supply can be obtained by the momentary setting out of voltage of the system or at least of the device concerned.
As represented on FIG. 4, the present invention comprises a circuit 100 for detecting the operating of an overload circuit, comprising flip-flops FF2 and FF3 and an AND gate 101, and a circuit 102 for memorization and inhibition of the switch mode power supply. The circuit 102 operates the above described base current control flip-flop 50 through an AND gate 58.
The memorization and inhibition circuit 102 comprises a capacitor 103, a discharge system constituted by a current supply 104 functioning permanently, a system for charging this capacitor constituted by a current supply 105 controlled in all or nothing by a switch 107 receiving the output of the detection circuit 100. When the detection circuit 100 indicates that the current limitation circuit in the power switch Tp does not function, only the discharge system 104 functions and the capacitor 103 remains discharged. When the current limitation system 100 is energized, the charge system (current supply 105) is activated. The ratio between the discharge current and the charge current is selected so that overall the capacitor 103 is charged. When the voltage at the terminals of the capacitor reaches a determined value, fixed by a comparator 106, a flip-flop FF4 is triggered which definitively inhibits the on state of the switch Tp.
In the circuit 100 for detecting the functioning of the current limitation circuit, the flip-flop FF2 has its reset input R2 connected to the output 72 of the form shaping circuit 74, its set input S2 connected to the output of the AND gate 101 and its output Q2 connected to the control terminal of the switch 107 of the circuit 102. The second flip-flop FF3 has its set input S3 connected to the output 72 of the shaping circuit 74, its reset input R3 connected to the output 76 of this shaping circuit and its output Q3 connected to a first input of the AND gate 101 of which the other input is connected to the output of the comparator 92 detecting the excess currents in the power transistor Tp.
FIG. 5 indicates a time chart of the signals appearing in different points of the circuit in four particular operating cases. In FIG. 5
the line a indicates the signals present at the terminal 40 or more exactly the control signals from which result the signals at the terminal 40 following the action of the insulating transformer TX (cf. FIG. 1). Those signals correspond to more or less long square pulses according to the error signal detected;
the line b indicates the signal present at the output 76 of the shaping circuit 74, normally provoking the setting to 1 of the flip-flop 50;
the line c indicates the signal at the output 76 of the shaping circuit 74, normally controlling the reset of the flip-flop 50;
the line d indicates the signal at the output Q2 of the flip-flop FF2 controlling the switch 107;
the line e indicates the signal Q3 at the output of the flip-flop FF3;
the line f indicates the signal at the input R of the flip-flop 50, i.e. the signal at the output of the OR gate 60. This signal corresponds to the rising edge of the pulse at the output 76 of the shaping circuit 74 or at the output of the comparator 92;
the line g indicates the current in the power transistor that corresponds to the signal present on the input 44 of the comparator 92;
the line h indicates the signal at the output of the comparator.
The operating of this circuit in four possible functioning modes will now be studied.
1. Normal operating without overloading
No signal is supplied to the output of the comparator 92 and it is the outputs 72 and 76 (signals of lines b and c) that control the inputs S and R of the flip-flop 50. The circuit 102 not receiving any output signal from the circuit 100 supplies to the output Q4 of the flip-flop FF4 a high level signal and the AND gate 58 is validated thereby allowing the output signal 72 of the shaping circuit 74 to reach the input S of the flip-flop 50.
2. Functioning in lower overloading limit
As shown by line g of FIG. 5, it concerns the case where the reset pulse of the flip-flop 50 tends to bring the switch Tp at the off state prior to an overloading detection (current in Tp higher than I Max) occuring, but where an overloading occurs between the off state order and the effective off state of the power transistor. This delay is due to the blocking period or storing time ts of the switch which is not nil in particular in the case where a high voltage bipolar transistor is utilized. The current limitation comparator 92 is thus energized. However, the output signal of the comparator 92 does not reach the flip-flop FF2 to supply an output signal Q2 since the flip-flop FF3 has been previously reset by the signal 76 and blocks the AND gate 101. the flip-flop FF2 thus remains at zero and as in the preceding case, the circuit 102 is not energized and the regulation circuit continues to operate normally. It would in fact be inconvenient to shut down the operating of the chopping power supply in this particular case.
3. Operating in moderate overloading
As in the previous case, it is the output signal 72 of the shaping circuit 74 that provokes the bringing to the on state of the power transistor but, as shown by line g, the overload level of the power transistor Tp is reached prior to the normal off state signal of the transistor (line c) occuring. In this case, the comparator 92 supplies a signal which is transmitted through AND gate 101 enabled by the flip-flop FF3 to the flip-flop Q2 which is set to 1. The switch 107 of the memorization and inhibition circuit 102 is thus closed and the charge process of the capacitor 103 begins.
It will be noted that the signal Q2 (line d) remains at high level until the triggering pulse of the following cycle (bringing of the output 72 at high level). Therefore, the earlier overloading arrives in the cycle, the more the signal Q2 is present during a long period. After several functioning cycles, the voltage accumulated on the capacitor 103 will be higher than the reference voltage VRef applied to the second terminal of the comparator 106. Subsequently, the flip-flop FF4 supplies a signal at low level to its output Q4 and the AND gate 58 invalidates the input S of the flip-flop 50. This occurs only if the overloading lasts over a certain number of cycles. Thus, the functioning of the switch mode power supply is definitively brought to the off state indicating an operating failure of the device, for example a short-circuiting of a secondary winding of the transformer TA (cf. FIG. 1). To start up again the switch mode power supply, it is necessary to apply a new signal to the input R4 of the flip-flop FF4. This input can for example be connected to an initialization device when the whole of the switch mode power supply is powered.
4. Operating under strong overloading
This operating mode is illustrated on the right side of FIG. 5. It is as a whole identical to the case of a moderate overloading but it has been represented only to show the elongation of the pulses Q2 when the overloading occurs very early in an operating cycle of the switch mode power supply.
The various advantages of the present invention thus become apparent. On the one hand; the operating delay time is easily programmable by means of a single component, for example the value of the capacity of the capacitor 103. On the other hand, automatically, due to the elongation of the pulse Q2 when the overloading occurs early in a cycle, the action delay is modulated in function of the intensity of the overloading. Therefore, the greater is the overloading, the shorter is the operating delay time.
Another advantage lies in the perfect simultaneity of the triggering of the timing of the device according to the invention and of the operating of the conventional limitation of the current as described in the description of the prior art. This results in very good operating security. The risk of spurious triggering of the device close to the lower current limit is thus prevented.
On the other hand, as has been seen, the device according to the invention operates well with a power switch constituted by a bipolar transistor in which the storage time is relatively long, but this circuit is perfectly adaptable to a switch of which the off state delay tends towards zero such as a MOS power transistor.
Similarly, accordng to another advantage of the invention, this circuit is perfectly compatible with the other protection and starting assistance circuits which utilized the circuits according to the prior art. Indeed, it will be noted that the components of the circuit according to the invention are perfectly compatible with the components of the current limitation circuit described herein-above. Furthermore, the AND gate 58 that has the circuit at the off state when it is not operating bears the same reference as the AND gate 58 described in relation with FIG. 2. In fact, it can be the same gate comprising simply a supplementary input. Herein lies another advantage of the invention, i.e. it is perfectly compatible with the automatic starting circuit described in relation with FIGS. 1 and 2. In this automatic starting mode, which may be called burst mode, it is also desired to be able to detect and stop the power supply in the case of overloading. However, as mentioned herein-above in the initial burst method, the circuit operates only with a duty cycle of about 10%. In this case, the capacitor 103 risks to be insufficiently charged during this brief action period and to discharge during the 90% of non-operating. To overcome this, it is foreseen according to the present invention to inhibit the discharging of the capacitor 103 by providing a controlled switch (not represented) in series with the discharge current supply 104 and energized by a signal indicative of the fact that operating is taking place in the burst mode. Therefore, in the case of overloading in the burst method, the capacitor is charged a little at each burst and retains its voltage between the bursts. It is therefore possible to reach the voltage VRef after a certain number of burst.
I'll examine the operation of the line output stage, whose basic job is to generate a sawtooth current in the line scan coils so that the beams are deflected horizontally across the picture tube's screen. The beams are deflected from the left-hand side to the right-hand side to give the forward line scan: this is followed by a rapid, blanked flyback to the left-hand side ready to trace out the next viewed line. Because of the way in which the flyback is achieved, the line output transformer generates various pulse voltages which are rectified to produce the e.h.t. required by the tube and other supplies. The line output stage is not just any sort of amplifier. The active device, almost always a transistor though valves, thyristors and gate -controlled switches have been used in the past, operates as a switch, the inductive components in the stage being mainly responsible for generating the sawtooth current waveform. Tuning is used to generate and control the flyback. The line drive waveform controls the output transistor's on/off switching and thus determines the timing of the cycle of operations, keeping them phase synchronised with the transmitted picture signal.
Basic Operation
Fig. 1 shows in most basic form the main elements in the line output stage, the active device (transistor) being shown as a switch. When the switch is closed, capacitor C and diode D are shorted out and the 150V supply is connected across coil L. Now it's a basic law of inductance that when a d.c. voltage is connected across a coil the current flowing through the coil builds up linearly from zero. Fig. 2(a) shows this as a positive -going ramp that starts at time t 1 , when the switch is closed. After about 26psec (t2), roughly the time required to deflect the beams from screen centre flows via the large -value capacitor CR, charging the tuning capacitor C with the result that the voltage at its 'upper' plate (the one connected to the coil) rises to a relatively high positive value. When all the energy in coil L has been transferred to capacitor C (time t3) the latter begins to discharge, passing the energy back the other way to L via CR which, as far as the circuit's a.c. operation is concerned, can be regarded as a short-circuit. At time t4 the capacitor has discharged, having transferred the energy back to the coil. This to-and-fro interchange of energy between L and C, which from the a.c. point of view are in parallel (CR representing a short-circuit), is the normal action of a tuned/resonant/oscillatory circuit. The resonant frequency is determined by the values of L and C. These are selected so that when time t4 is reached, i.e. after a half cycle of oscillation, the sawtooth current has passed through zero to a negative point on the ramp and the beams have been deflected to the left-hand side of the screen ready for the next active line scan. To complete the oscillatory cycle (the normal resonant circuit action) the voltage at the upper plate of capacitor C would have to move negatively with respect to chassis. It can't do so because of the presence of diode D, which is called the efficiency diode - we'll explain that in a minute. When the voltage at the cathode of D tries to swing negatively it conducts, i.e. switches on, providing a discharge path for the coil. Once again because of the inductance in the circuit there's a gradual, linear current discharge, the enegery being returned to the supply's reservoir capacitor CR. During this discharge, the beams are deflected back towards the centre of the screen (times t4 to t5). At this point the magnetic flux (energy) in L has been dissipated. C is still in its discharged state, being shorted out by diode D. So at time t5, with the beams at screen centre (zero deflection), the switch has to be closed so that the cycle of operation can be repeated. The action of diode D has, with the inductance in the circuit, provided half the scan power while in the process returning the energy (minus inevitable circuit losses) to the reservoir capacitor. No wonder it's called the efficiency diode. It's important to note that the beam flyback period t2 to t4 is governed by the time -constant of L and C, consisting of one half cycle of oscillation. To achieve a flyback time of 12μsec the duration of one cycle needs to be 24μsec: so the resonant frequency of L and C works out at 41.67kHz. Fig. 3 illustrates the four phases in the operation of the line output stage. Now the voltage developed across an inductor is propor- tional to the rate of change of the current flowing through it. Thus the voltage across L is relatively low during the forward scan period but correspondingly high during the flyback, when the current flow is faster because of the circuit resonance. The voltage developed at the positive plate of capacitor C is shown in Fig. 2(b), typically peaking at 1,200V. Both the line output transistor and the efficiency diode must be capable of withstanding this high reverse voltage. As we've seen, the circuit action is highly efficient as the energy stored in L is returned to the supply during the first half of the forward scan: indeed with 'perfect' components there would be no net demand on the power supply at all! In practice because of the resistance of the inductor and the losses in the diode, switch and capacitor the circuit takes out a little more than it puts back, while the practice of loading the transformer with rectifier circuits to provide power for other sections of the set increases the stage's current demand. To make up for these losses, the line output transistor is switched on slightly before instead of at the centre of the forward scan. In a practical circuit L is the primary winding of the line output transformer and the deflection coils are connected across it via a d.c. blocking capacitor, CB, as shown in Fig. 4. This coupling capacitor also provides scan -correction (often referred to as S -correction). Why is this required? If a linear deflection current was used to control the scanning with a relatively flat -faced picture tube the sides of the picture would be stretched out in comparison with the centre section. Hence S -correction: the value of the coupling capacitor is chosen so that it resonantes with the inductance of the scan coils at about 5kHz. This has the effect of adding a sinewave component to the sawtooth current, as shown in Fig. 5. Thus the deflection power is tailored to suit the length of the beam paths as the screen is scanned, correcting the horizontal linearity of the display. At the line scanning frequency the scan coils behave as an almost perfect inductor, but their small d.c. resistance is in series with the fixed voltage that should be present across the coil. It has the effect of introducing an asymmetric sensitivity loss during the forward scan. To counteract it a further component is added in series with the scan coils - an inductor with a saturable magnetic core, biased by a permanent magnet so that its inductance falls as the scan current increases. The voltage drop across this inductor, which is known as the linearity coil, varies in the opposite sense to that produced by the resistance of the coils, thus providing an equal -but -opposite cancellation effect. In some TV sets the permanent magnet can be adjusted to trim the linearity correction, though many modern sets use components with such tight tolerances that a sealed linearity -correction coil can be used. With some very small -screen sets the horizontal non -linearity effect is small enough to be ignored.
Practical Line Output Stage
Fig. 6 shows a relatively simple line output stage circuit used with a 90° -deflection tube. Tr5 is the line output transistor, which incorporates the efficiency diode in the same package. The primary winding of the line output trans- former T4 is the section between pins 2 and 10, C95 being the flyback tuning capacitor. Scan coil coupling and S - correction are provided by C94, the line linearity coil L14 being connected in series on the chassis side of the scan current path. L14 is damped by R110 to prevent it ringing when the line flyback pulse occurs - the effect of an undamped linearity coil is velocity modulation of the beams at the beginning of their sweeps, showing up as black -and - white vertical striations at the left-hand side of the screen. C92 is the reservoir capacitor, the h.t. feed being via 8105. 8106 and R109 feed pulses to the second phase -locked loop (APC2) in the sync chip - we dealt with this in last month's instalment. A second pulse feed from the same point goes to the colour decoder chip to provide line blanking, burst gating and PAL switch drive - this particular set doesn't use the sandcastle pulse approach.
Secondary Supplies
So much for the generation and control of the sawtooth scanning current. The rest of the components in this circuit are used to harness the energy in the transformer to provide power supplies for other sections of the receiver. The winding between pins 4 and 8 pulse energises the picture tube's heaters at 6.3V r.m.s. The other supplies make use of the transformer as the heart of a d.c.-to-d.c. converter system, by means of secondary windings that provide pulse feeds to diode/capacitor rectifier circuits. Small -value (0.680) resistors in the 25V and 200V supplies provide surge limiting and protection (by going open -circuit) in the event of a short-circuit in one of these supplies. The most significant supply is obtained from the diode - split winding that starts at pin 9. Although not shown in full detail it consists of several 'cells', each of which consists of an electrically isolated secondary winding, a built-in high - voltage rectifier diode and, as the reservoir capacitor, the carefully contrived capacitance that's present between adjacent, highly -insulated winding layers. These cells are connected in series to form a voltage -multiplier system capable of providing an e.h.t. supply for the tube's final anode of typically 24kV - it may be as high as 30kV in some designs. There's a built-in surge limiter resistor at the output end of the chain of cells. An important part of the e.h.t. multiplier system is the final reservoir capacitor that split chain provides about 8kV to a built-in potential -divider chain that contains two presets: the one at the top provides the supply for the tube's focus electrode while the one near the bottom provides its first anode supply of about 800V. The bottom of the diode -split chain (pin 9) is returned to chassis via a diode/capacitor/resistor network (not shown here). The voltage developed across this network is proportional to the total beam current, since this flows from the tube's cathodes via the e.h.t. connector and the diode -split chain to chassis. Above a certain threshold the voltage at pin 9 reduces the picture brightness and/or contrast via the colour decoder/matrixing chip, limiting the beam current and hence the dissipation in the tube's shadowmask to safe levels. The winding between pins 10 and 7 of the transformer produces 50-70V pulses that sit on the h.t. voltage present at pin 10. When rectified by D23 and C100 a 200V supply is provided for the RGB output stages that drive the tube's cathodes. Secondary winding 4-6 feeds D24 and C99 which provide a 25V supply for the field timebase. In some designs supplies for the audio output stage and the signal sections of the receiver are also obtained from the line output transformer: in this particular chassis they are obtained from the chopper transformer in the power supply instead. Incidentally there have been one or two designs, the Ferguson/philco TX10 chassis being a well-known example, where the e.h.t. is also obtained from the chopper transformer, the line output transformer then acting mainly as a load for the line output transistor. In earlier designs a separate diode - capacitor multiplier unit (tripler) was fed from a single line output transformer overwiding to provide the e.h.t.
Scan Rectification
The e.h.t., focus and 200V supplies derived from the transformer are relatively lightly loaded, i.e. no great current demand is placed on them. They can therefore be obtained by rectifying the pulses present during the flyback period (time t2 -t4 in Fig. 2), which is about twenty per cent of the scan cycle. Where the current demand is greater, e.g. in a supply for the field timebase or an audio output stage, the phasing of the relevant transformer winding is often arranged so that the rectifier diode conducts during the scan rather than the flyback period. Although the voltage available is much lower, it's present for a longer period (about eighty per cent of the scan/duty cycle). As a result the output regulation is much better. The relatively high peak reverse voltage has to be taken into account in the rectifier diode's specification.
EHT Regulation
The internal impedance of a diode -split e.h.t. supply is typically about 1MOhm. Thus with a total beam current of lmA, present when a bright picture is being displayed on a 22in. picture tube, the e.h.t. voltage will drop by about 1kV or five per cent. The result of this is some ballooning, i.e. increase in picture size. Compensation can be provided by reducing the line scanning power. Careful choice of the value of the resistor that feeds the line output transformer - R105 in Fig. 6 - gives automatic compensation in the horizontal direction, while deriving the supply for the field output stage from the line output transformer tends to cancel out the ballooning in the vertical plane. Various 'anti -breathing' arrangements are used in TV receiver design. Most operate via the diode -modulator circuit we'll come to shortly. With any line output stage circuit the picture width and e.h.t. voltage depend on the stage's h.t. supply, so this must be well regulated and set up correctly. In the circuit shown in Fig. 6 the h.t. voltage has to be 119V with a 20in. tube and 145V with a 22in. tube.
Pincushion Distortion
The raster produced on an almost -flat faced picture tube by constant -amplitude scan currents has pincushion distortion at all four sides. This is because of the disparity between the image plane and the screen's profile - . As a general rule the deflection yokes used with modern 90° tubes have built-in correction for both NS (vertical) and EW (horizontal) pincushion distortion while 110° tubes (generally above 22in. screen size) have in -yoke correction for NS distortion but cannot fully compensate for the pincushion effect at the sides of the screen. Thus with these the line scan current has to be amplitude -modulated by a parabolic waveform at field frequency as shown in Fig. 7. With present-day tube designs a modulation depth of about seven per cent is required. the peak -to -peak scan current being typically 4.1A at the top and bottom of the screen and 4.4A towards the centre of the screen, where the deflection power is greatest. Amplitude modulation of the line scan current can be achieved by including a saturable -reactance transformer in series with the scan coils, but this is expensive. You could put a suitably -shaped ripple on the supply to the line output stage, but the parabola would be superimposed on any secondary supplies derived from the line output transformer. The most widely used solution is to employ a diode -modu- lator circuit, since this gives full control of the raster shape and scan amplitude while providing a constant load current and flyback time.
The Diode Modulator
Fig. 8 shows the essence of a diode -modulator arrange- ment. The efficiency diode is split in two, DI and D2, which perform the same clamping action as before. The flyback tuning capacitor is also split in two, Cl and C2: the upper one tunes the transformer and scan coils (L1) as before while the lower one tunes a bridge coil, L2, via C4 to the same flyback frequency of about 42kHz. C3 is the scan coupling capacitor, which corresponds with CB in Fig. 4. Modulation is achieved by using transistor Tr2, whose conduction governs the scan width, to vary the load across C4. When Tr2 is off, the scan energy is shared between the the two series LC combinations C3/L1 and L2/C4. The charge on C3 and C4 is in the ratio of about 7:1, the scan current being reduced in proportion. When Tr2 is fully conductive, C4 is effectively shorted out and acquires no charge. Thus a greater proportion of the energy is present in C3/L1 and the scan current and picture width are increased. By varying the conduction of Tr2 during the forward scan in a parabolic manner, EW pincushion correction is achieved. The basic picture width can be controlled by varying Tr2's standing bias. Choke L3 and the large -value capacitor C5 filter the line -frequency energy so that it doesn't reach Tr2. And because both sections of the load (L 1/C1 and L2/C2) are individually tuned to the flyback frequency the flyback time, and hence the e.h.t. and the other line output transformer -derived supplies, remain constant over the field period despite the line scan current variation. There are several different versions of the diode -modu- lator arrangement. Some tube/yoke combinations have a scan -geometry characteristic such that when the line scan current is modulated by a simple parabolic waveform as described above the raster has inner pincushion distortion as shown in Fig. 9.
Diode Modulator Drive
The parabolic EW drive waveform required is easily obtained by feeding the field -scan sawtooth waveform to a double integrator. By adding a sawtooth component the shape of the parabolic waveform can be tilted in either direction to give keystone -distortion correction if required - this is not generally necessary with modern tube/yoke designs. These EW correction characteristics are adjustable by preset resistors or, in the case of bus -programmable sets, remote control commands to the deflection processor. Very often the EW modulator is used to correct the previously mentioned picture breathing effect: this is done by feeding to the EW modulator's control circuit a voltage that's proportional to beam current.
MIVAR 28V2E TVD CHASSIS TV3536/1 Synchronized switch-mode power supply:
In a switch mode power supply, a first switching transistor is coupled to a primary winding of an isolation transformer. A second switching transistor periodically applies a low impedance across a second winding of the transformer that is coupled to an oscillator for synchronizing the oscillator to the horizontal frequency. A third winding of the transformer is coupled via a switching diode to a capacitor of a control circuit for developing a DC control voltage in the capacitor that varies in accordance with a supply voltage B+. The control voltage is applied via the transformer to a pulse width modulator that is responsive to the oscillator output signal for producing a pulse-width modulated control signal. The control signal is applied to a mains coupled chopper transistor for generating and regulating the supply voltage B+ in accordance with the pulse width modulation of the control signal.
Description:
The invention relates to switch-mode power supplies.
Some television receivers have signal terminals for receiving, for example, external video input signals such as R, G and B input signals, that are to be developed relative to the common conductor of the receiver. Such signal terminals and the receiver common conductor may be coupled to corresponding signal terminals and common conductors of external devices, such as, for example, a VCR or a teletext decoder.
To simplify the coupling of signals between the external devices and the television receiver, the common conductors of the receiver and of the external devices are connected together so that all are at the same potential. The signal lines of each external device are coupled to the corresponding signal terminals of the receiver. In such an arrangement, the common conductor of each device, such as of the television receiver, may be held "floating", or conductively isolated, relative to the corresponding AC mains supply source that energizes the device. When the common conductor is held floating, a user touching a terminal that is at the potential of the common conductor will not suffer an electrical shock.
Therefore, it may be desirable to isolate the common conductor, or ground, of, for example, the television receiver from the potentials of the terminals of the AC mains supply source that provide power to the television receiver. Such isolation is typically achieved by a transformer. The isolated common conductor is sometimes referred to as a "cold" ground conductor.
In a typical switch mode power supply (SMPS) of a television receiver the AC mains supply voltage is coupled, for example, directly, and without using transformer coupling, to a bridge rectifier. An unregulated direct current (DC) input supply voltage is produced that is, for example, referenced to a common conductor, referred to as "hot" ground, and that is conductively isolated from the cold ground conductor.
A pulse width modulator controls the duty cycle of a chopper transistor switch that applies the unregulated supply voltage across a primary winding of an isolating flyback transformer. A flyback voltage at a frequency that is determined by the modulator is developed at a secondary winding of the transformer and is rectified to produce a DC output supply voltage such as a voltage B+ that energizes a horizontal deflection circuit of the television receiver. The primary winding of the flyback transformer is, for example, conductively coupled to the hot ground conductor. The secondary winding of the flyback transformer and voltage B+ may be conductively isolated from the hot ground conductor by the hot-cold barrier formed by the transformer.
It may be desirable to synchronize the operation of the chopper transistor to horizontal scanning frequency for preventing the occurrence of an objectionable visual pattern in an image displayed in a display of the television receiver.
A synchronized switch mode power supply, embodying an aspect of the invention, includes a transfromer having first and second windings. A first switching arrangement is coupled to the first winding for generating a first switching current in the first winding to periodically energize the second winding. A source of a synchronizing input signal at a frequency that is related to a deflection frequency is provided. A second switching arrangement responsive to the input signal and coupled to the second winding periodically applies a low impedance across the energized second winding that by transformer action produces a substantial increase in the first switching current. A periodic first control signal is generated. The increase in the first switching current is sensed to synchronize the first control signal to the input signal. An output supply voltage is generated from an input supply voltage in accordance with the first control signal.
MIVAR CHASSIS TV3536/1 - Deflection power processing with TEA2029C
DESCRIPTION
The THOMSON TEA2029C is a complete (horizontal and vertical)
deflection processor with secondary to primary
SMPS control for color TV sets.
DEFLECTION .CERAMIC 500kHz RESONATOR FREQUENCY
REFERENCE .NO LINE AND FRAME OSCILLATOR ADJUSTMENT
.DUAL PLL FOR LINE DEFLECTION .HIGH PERFORMANCE SYNCHRONIZATION .SUPER SANDCASTLE OUTPUT .VIDEO IDENTIFICATION CIRCUIT .AUTOMATIC 50/60Hz STANDARD IDENTIFICATION
.EXCELLENT INTERLACING CONTROL .SPECIALPATENTED FRAME SYNCHRO DEVICE
FOR VCR OPERATION .FRAME SAW-TOOTH GENERATOR .FRAME PHASE MODULATOR FOR THYRISTOR
SMPS CONTROL .ERROR AMPLIFIER AND PHASE MODULATOR
.SYNCHRONIZATION WITH HORIZONTAL
DEFLECTION .SECURITY CIRCUIT AND START UP PROCESSOR
.OUTPUT PULSES ARE SENT TO THE PRIMARY
SMPS IC (TEA2261) THROUGH A
LOW COST TRANSFORMER
GENERAL DESCRIPTION
This integrated circuit uses I2L bipolar technology
and combines analog signal processing with digital
processing.
Timing signals are obtainedfrom a voltage-controlled
oscillator (VCO) operatingat 500KHzby means
of a cheap ceramic resonator. This avoids the
frequency adjustment normally required with line
and frame oscillators.
A chain of dividers and appropriate logic circuitry
produce very accurately defined sampling pulses
and the necessary timing signals.
The principal functions implemented are :
- Horizontal scanning processor.
- Frame scanning processor. Two applications are
possible :
- D Class : Power stage using an external
thyristor.
- B Class : Powerstageusing an externalpower
amplifier with fly-back generator
such as the TDA8170.
- Secondary switch mode power regulation.
The SMPS output synchronize a primary I.C.
(TEA2260/61)at the mains part.
This concept allows ACTIVE STANDBY facilities.
- Dual phase-locked loop horizontal scanning.
- High performance frameand line synchronization
with interlacing control.
- Video identification circuit.
- Super sandcastle.
- AGC key pulse output.
- Automatic 50-60Hz standard identification.
- VCR input for PLL time constant and frame synchro
switching.
- Frame saw-tooth generator and phase modulator.
- Switchingmode regulated power supplycomprising
error amplifier and phase modulator.
- Security circuit and start-up processor.
- 500kHzVCO
The circuit is supplied in a 28 pin DIP case.
VCC = 12V.
Synchronization Separator
Line synchronization separator is clamped to
black level of input video signal with synchronization
pulse bottom level measurement.
The synchronization pulses are divided centrally
between the black level and the synchronization
pulse bottom level, to improve performance on
video signals in noise conditions.
Frame Synchronization
Frame synchronization is fully integrated (no external
capacitor required).
The frame timing identification logic permits automatic
adaptation to 50 - 60Hz standards or non-interlaced
video.
An automatic synchronization window width system
provides :
- fast frame capture (6.7ms wide window),
- good noise immunity (0.4ms narrow window).
The internal generator starts the discharge of the
saw-tooth generator capacitor so that it is not disturbed
by line fly back effects.
Thanks to the logic control, the beginning of the
charge phase does not depend on any disturbing
effect of the line fly-back.
A 32ms timing is automatically applied on standardized
transmissions, for perfect interlacing.
In VCR mode, the discharge time is controlled by
an internal monostable independent of the line
frequency and gives a direct frame synchronization.
Horizontal Scanning
The horizontalscanningfrequencyis obtainedfrom
the 500kHz VCO.
The circuit uses two phase-locked loops (PLL) :
the first one controls the frequency, the second one
controls the relative phase of the synchronization
and line fly-back signals.
The frequency PLL has two switched time constants
to provide :
- capture with a short time constant,
- good noise immunity after capture with a long
time constant.
The output pulse has a constant duration of 26ms,
independent of VCC and any delay in switching off
the scanning transistor.
Video Identification
The horizontal synchronization signal is sampled
by a 2ms pulse within the synchronization pulse.
The signal is integrated by an external capacitor.
The identification function provides three different
levels :
- 0V : no video identification
- 6V : 60Hz video identification
- 12V : 50Hz video identification
This information may be used for timing research
in the case of frequency or voltage synthetizer type
receivers, and for audio muting.
Super Sandcastle with 3 levels : burst, line flyback,
frame blanking
In the event of vertical scanning failure, the frame
blanking level goes high to protect the tube.
Frame blanking time (start with reset of Frame
divider) is 24 lines.
VCR Input
This provides for continuous use of the short time
constant of the first phase-locked loop (frequency).
In VCR mode, the frame synchronization window
widens out to a search window and there is no
delay of frame fly-back (direct synchronization).
Frame Scanning
FRAME SAW-TOOTH GENERATOR. The current
to charge the capacitoris automatically switched to
60Hz operation to maintain constant amplitude.
FRAME PHASE MODULATOR (WITH TWO DIFFERENTIAL
INPUTS). The output signal is a pulse
at the line frequency, pulse width modulatedby the
voltage at the differential pre-amplifier input.
This signal is used to control a thyristor which
provides the scanning current to the yoke. The
saw-tooth output is a low impedance,however, and
can therefore be used in class B operation with a
power amplifier circuit.
Switch Mode Power Supply (SMPS) Secondary
to Primary Regulation
This power supply uses a differential error amplifier
with an internal reference voltage of 1.26V and a
phase modulator operating at the line frequency.
The powertransistor is turnedoff bythe falling edge
of the horizontal saw-tooth.
The ”soft start” device imposes a very small conduction
angle on starting up, this angle progressively
increases to its nominal regulation value.
The maximum conductionangle may be monitored
by forcing a voltage on pin 15. This pin may also
be used for current limitation.
The outputpulse is sent to the primaryS.M.P.S. I.C.
(TEA2261) via a low cost synchro transformer.
Security Circuit and Start Up Processor
When the security input (pin 28) is at a voltage
exceeding 1.26V the three outputs are simultaneously
cut off until this voltagedrops below the 1.26V
threshold again. In this case the switch mode
power supply is restarted by the ”soft start” system.
If this cycle is repeated three times, the three
outputs are cut off definitively. To reset the safety
logic circuits, VCC must be zero volt.
This circuit eliminates the risk to switch off the TV
receiver in the event of a flash affecting the tube.
On starting up, the horizontal and vertical scanning
functions come into operation at VCC = 6V. The
power supply then comes into operation progressively.
On shutting down, the three functions are interrupted
simultaneously after the first line fly-back.
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TDA8170 TV VERTICAL DEFLECTION OUTPUT CIRCUIT:
DESCRIPTION
The TDA8170 is a monolithic integrated circuit in
HEPTAWATTTM package. It is a high efficiency
power booster for direct driving of verticalwindings
of TV yokes. It is intended for use in Colour and B
&Wtelevision receivers as well as in monitorsand
displays.
The functions incorporated are :
.POWERAMPLIFIER
.FLYBACKGENERATOR
.REFERENCE VOLTAGE
.THERMAL PROTECTION
The power dissipated in the circuit must be removed
by adding an external heatsink.
Thanks to the HEPTAWATTTM package attaching
the heatsink is very simple, a screwa compression
spring (clip) being sufficient. Betweenthe heatsink
andthe packageit isbetter to insert a layerof silicon
grease, to optimizethe thermal contact ; no electrical
isolation is needed between the two surfaces.
ABSOLUTE MAXIMUMRATINGS
Symbol Parameter Value Unit
VS Supply Voltage (pin 2) 35 V
V5, V6 Flyback Peak Voltage 60 V
V3 Voltage at Pin 3 + Vs
V1, V7 Amplifier Input Voltage + Vs, – 0.5 V
Io Output Peak Current (non repetitive, t = 2 msec) 2.5 A
Io Output Peak Current at f = 50 or 60 Hz, t 3 10 msec 3 A
Io Output Peak Current at f = 50 or 60 Hz, t > 10 msec 2 A
I3 Pin 3 DC Current at V5 < V2 100 mA
I3 Pin 3 Peak to Peak Flyback Current at f= 50 or 60 Hz, tfly 31.5msec 3 A
Ptot Total Power Dissipation at Tcase = 90 °C 20 W
Tstg, Tj Storage and Junction Temperature – 40, +150 °C.
TDA8145 TV EAST/WEST CORRECTION CIRCUIT FOR SQUARE TUBES
FEATURES SUMMARY
■ LOW DISSIPATION
■ SQUARE GENERATOR FOR PARABOLIC
CURRENT SPECIALLY DESIGNED FOR
SQUARE C.R.T. CORRECTION
■ EXTERNAL KEYSTONE ADJUSTMENT
(symmetry of the parabola)
■ INPUT FOR DYNAMIC FIELD CORRECTION
(beam current change)
■ STATIC PICTURE WIDTH ADJUSTMENT
■ PULSE-WIDTH MODULATOR
■ FINAL STAGE D-CLASS WITH ENERGY
REDELIVERY
■ PARASITIC PARABOLA SUPPRESSION,
DURING FLYBACK TIME OF THE VERTICAL
SAWTOOTH
DESCRIPTION
The TDA8145 is a monolithic integrated circuit in a
8 pin minidip plastic package designed for use in
the square C.R.T. east-west pin-cushion correction
by driving a diode modulator in TV and monitor
applications.
CIRCUIT OPERATION
(see the shematic diagram)
A differential amplifier OP1 is driven by a vertical
frequency sawtooth current of ± 33µA which is
produced via an external resistor fromthe sawtooth
voltage. The non–inverting input of this amplifier
is connected with a reference voltage
corresponding to the DC level of the sawtooth voltage.
This DC voltage should be adjustable for the
keystone correction. The rectified output current of
this amplifier drives the parabola networkwhich
provides a parabolic output current.
This output current produces the corresponding
voltage due to the voltage drop across the external
resistor at pin 7.
If the input is overmodulated (> 40µA) the internal
current is limited to 40µA. This limitation can be
used for suppressing the parasitic parabolic current
generated during the flyback time of the frame
sawtooth.
A comparator OP2 is driven by the parabolic current.
The second input of the comparator is connected
with a horizontal frequency sawtooth
voltage the DC level of which can be changed by
the external circuitry for the adjustment of the picture
width.
The horizontal frequency pulse–width modulated
output signal drives the final stage. It consists of a
class D push–pull output amplifier that drives, via
an external inductor, the diode modulator.
PHILIPS TDA3566A PAL/NTSC decoder,
GENERAL DESCRIPTION
The TDA3566A is a decoder for the
PAL and/or NTSC colour television
standards. It combines all functions
required for the identification and
demodulation of PAL/NTSC signals.
Furthermore it contains a luminance
amplifier, an RGB-matrix and
amplifier. These amplifiers supply
output signals up to 4 V peak-to-peak
(picture information) enabling direct
drive of the discrete output stages.
The circuit also contains separate
inputs for data insertion, analog and
digital, which can be used for text
display systems.
FEATURES
• A black-current stabilizer which
controls the black-currents of the
three electron-guns to a level low
enough to omit the black-level
adjustment
• Contrast control of inserted RGB
signals
• No black-level disturbance when
non-synchronized external RGB
signals are available on the inputs
• NTSC capability with hue control.
APPLICATIONS
• Teletext/broadcast antiope
• Channel number display.
FUNCTIONAL DESCRIPTION
The TDA3566A is a further
development of the TDA3562A. It has
the same pinning and nearly the
same application. The differences
between the TDA3562A and the
TDA3566A are as follows:
• The NTSC-application has largely
been simplified. In the event of
NTSC the chrominance signal is
now internally coupled to the
demodulators, automatic
chrominance control (ACC) and
phase detectors. The chrominance
output signal (pin 28) is thus
suppressed. It follows that the
external switches and filters which
are required for the TDA3562A are
not required for the TDA3566A.
There is no difference between the
amplitudes of the colour output
signals in the PAL or NTSC mode.
• The clamp capacitor at pins 10, 20
and 21 in the black-level
stabilization loop can be reduced to
100 nF provided the stability of the
loop is maintained. Loop stability
depends on complete application.
The clamp capacitors receive a
pre-bias voltage to avoid coloured
background during switch-on.
• The crystal oscillator circuit has
been changed to prevent parasitic
oscillations on the third overtone of
the crystal. Consequently the
optimum tuning capacitance must
be reduced to 10 pF.
• The hue control has been improved
(linear).
Luminance amplifier
The luminance amplifier is voltage
driven and requires an input signal of
450 mV peak-to-peak (positive
video). The luminance delay line must
be connected between the IF
amplifier and the decoder.
The input signal is AC coupled to the
input (pin 8). After amplification, the
black level at the output of the
preamplifier is clamped to a fixed DC
level by the black level clamping
circuit. During three line periods after
vertical blanking, the luminance
signal is blanked out and the black
level reference voltage is inserted by
a switching circuit.
This black level reference voltage is
controlled via pin11 (brightness). At
the same time the RGB signals are
clamped. Noise and residual signals
have no influence during clamping
thus simple internal clamping circuitry
is used.
Chrominance amplifiers
The chrominance amplifier has an
asymmetrical input. The input signal
must be AC coupled (pin 4) and have
a minimum amplitude of
40 mV peak-to-peak.
The gain control stage has a control
range in excess of 30 dB, the
maximum input signal must not
exceed 1.1 V peak-to-peak,
otherwise clipping of the input signal
will occur.
From the gain control stage the
chrominance signal is fed to the
saturation control stage. Saturation is
linearly controlled via pin 5. The
control voltage range is 2 to 4 V, the
input impedance is high and the
saturation control range is in excess
of 50 dB.
The burst signal is not affected by
saturation control. The signal is then
fed to a gated amplifier which has a
12 dB higher gain during the
chrominance signal. As a result the
signal at the output (pin 28) has a
burst-to-chrominance ratio which is
6 dB lower than that of the input
signal when the saturation control is
set at −6 dB.
The chrominance output signal is fed
to the delay line and, after matrixing,
is applied to the demodulator input
pins (pins 22 and 23). These signals
are fed to the burst phase detector. In
the event of NTSC the chrominance
signal is internally coupled to the
demodulators, ACC and phase
detectors.
Oscillator and identification circuit
The burst phase detector is gated
with the narrow part of the sandcastle
pulse (pin 7). In the detector the
(R−Y) and (B−Y) signals are added to
provide the composite burst signal
again.
This composite signal is compared
with the oscillator signal
divided-by-2 (R−Y) reference signal.
The control voltage is available at
pins 24 and 25, and is also applied to
the 8.8 MHz oscillator. The 4.4 MHz
signal is obtained via the divide-by-2
circuit, which generates both the
(B−Y) and (R−Y) reference signals
and provides a 90° phase shift
between them.
The flip-flop is driven by pulses
obtained from the sandcastle
detector. For the identification of the
phase at PAL mode, the (R−Y)
reference signal coming from the PAL
switch, is compared to the vertical
signal (R−Y) of the PAL delay line.
This is carried out in the H/2 detector,
which is gated during burst.
When the phase is incorrect, the
flip-flop gets a reset from the
identification circuit. When the phase
is correct, the output voltage of the
H/2 detector is directly related to the
burst amplitude so that this voltage
can be used for the ACC.
To avoid 'blooming-up' of the picture
under weak input signal conditions
the ACC voltage is generated by peak
detection of the H/2 detector output
signal. The killer and identification
circuits receive their information from
a gated output signal of H/2 detector.
Killing is obtained via the saturation
control stage and the demodulators to
obtain good suppression.
The time constant of the saturation
control (pin 5) provides a delayed
switch-on after killing. Adjustment of
the oscillator is achieved by variation
of the burst phase detector load
resistance between pins 24 and 25
(see Fig.8).
With this application the trimmer
capacitor in series with the 8.8 MHz
crystal (pin 26) can be replaced by a
fixed value capacitor to compensate
for unbalance of the phase detector.
Demodulator
The (R−Y) and (B−Y) demodulators
are driven by the colour difference
signals from the delay-line matrix
circuit and the reference signals from
the 8.8 MHz divider circuit. The (R−Y)
reference signal is fed via the
PAL-switch. The output signals are
fed to the R and B matrix circuits and
to the (G−Y) matrix to provide the
(G−Y) signal which is applied to the
G-matrix. The demodulation circuits
are killed and blanked by by-passing
the input signals.
NTSC mode
The NTSC mode is switched on when
the voltage at the burst phase
detector outputs (pins 24 and 25) is
adjusted below 9 V.
To ensure reliable application the
phase detector load resistors are
external. When the TDA3566A is
used only for PAL these two 33 kΩ
resistors must be connected to +12 V
(see Fig.8).
For PAL/NTSC application the value
of each resistor must be reduced to
20 kΩ (with a tolerance of 1%) and
connected to the slider of a
potentiometer (see Fig.9). The
switching transistor brings the voltage
at pins 24 and 25 below 9 V which
switches the circuit tot the NTSC
mode.
The position of the PAL flip-flop
ensures that the correct phase of the
(R−Y) reference signal is supplied to
the (R−Y) demodulator.
The drive to the H/2 detector is now
provided by the (B−Y) reference
signal. In the PAL mode it is driven by
the (R−Y) reference signal. Hue
control is realized by changing the
phase of the reference drive to the
burst phase detector.
This is achieved by varying the
voltage at pins 24 and 25 between
7.0 V and 8.5 V, nominal position
7.65 V. The hue control characteristic
is shown in Fig.6.
RGB matrix and amplifiers
The three matrix and amplifier circuits
are identical and only one circuit will
be described.
The luminance and the colour
difference signals are added in the
matrix circuit to obtain the colour
signal, which is then fed to the
contrast control stage.
The contrast control voltage is
supplied to pin 6 (high-input
impedance). The control range is
+5 dB to −11.5 dB nominal. The
relationship between the control
voltage and the gain is linear (see
Fig.3).
During the 3-line period after blanking
a pulse is inserted at the output of the
contrast control stage. The amplitude
of this pulse is varied by a control
voltage at pin 11. This applies a
variable offset to the normal black
level, thus providing brightness
control.
The brightness control range is 1 V to
3.6 V. While this offset level is
present, the black-current input
impedance (pin 18) is high and the
internal clamp circuit is activated. The
clamp circuit then compares the
reference voltage at pin 19 with the
voltage developed across the
external resistor network RA and
RB(pin 18) which is provided by
picture tube beam current.
The output of the comparator is
stored in capacitors connected from
pins 10, 20 and 21 to ground which
controls the black level at the output.
The reference voltage is composed
by the resistor divider network and the
leakage current of the picture tube
into this bleeder. During vertical
blanking, this voltage is stored in the
capacitor connected to pin 19, which
ensures that the leakage current of
the CRT does not influence the black
current measurement.
The RGB output signals can never
exceed a level of 10.6 V. When the
signal tends to exceed this level the
output signal is clipped. The black
level at the outputs (pins 13, 15 and
17) will be approximately 3 V. This
level depends on the spread of the
guns of the picture tube. If a beam
current stabilizer is not used it is
possible to stabilize the black levels at
the outputs, which in this application
must be connected to the black
current measuring input (pin 18) via a
resistor network.
Data insertion
Each colour amplifier has a separate
input for data insertion.
A 1 V peak-to-peak input signal
provides a 3.8 V peak-to-peak output
signal.
To avoid the black-level of the
inserted signal differing from the black
level of the normal video signal, the
data is clamped to the black level of
the luminance signal. Therefore AC
coupling is required for the data
inputs.
To avoid a disturbance of the blanking
level due to the clamping circuit, the
source impedance of the driver circuit
must not exceed 150 Ω. The data
insertion circuit is activated by the
data blanking input (pin 9). When the
voltage at this pin exceeds a level of
0.9 V, the RGB matrix circuits are
switched off and the data amplifiers
are switched on.
To avoid coloured edges, the data
blanking switching time is short. The
amplitude of the data output signals is
controlled by the contrast control at
pin 6. The black level is equal to the
video black level and can be varied
between 2 and 4 V (nominal
condition) by the brightness control
voltage at pin 11.
Non-synchronized data signals do not
disturb the black level of the internal
signals.
Blanking of RGB and data signals
Both the RGB and data signals can
be blanked via the sandcastle input
(pin 7). A slicing level of 1.5 V is used
for this blanking function, so that the
wide part of the sandcastle pulse is
separated from the remainder of the
pulse. During blanking a level of +1 V
is available at the output. To prevent
parasitic oscillations on the third
overtone of the crystal the optimum
tuning capacitance should be 10 pF.
THE PHILIPS TDA3562 / TDA3566A Circuit arrangement for the control of a picture tube :
1. Circuit arrangement for the control of at least one beam current in a picture tube by a picture comprising
a control loop which in one sampling interval obtains a measuring
signal from the value of the beam current on the occurrence of a given
reference level in the picture signal, stores a control signal derived
therefrom until the next sampling interval and thereby adjusts the beam
current to a value preset by a reference signal.
and a trigger
circuit which suppresses auxiliary pulses used to generate the beam
current after the picture tube has been started up and issues a
switching signal for the purpose of closing the control loop during the
sampling intervals and for releasing the control of the beam current by
the picture signal after the measuring signal has exceeded the threshold
value,
a change detection arrangement which delivers a change
signal when the stored signal has assumed a largely constant value, and
a logic network which does not release the control of the beam current
by the picture signal outside the sampling intervals until the change
signal has also been issued after the switching signal.
2. Circuit arrangement as set forth in claim 1, in
which the picture signal comprises several color signals for the control
of a corresponding number of beam currents for the display of a color
picture in the picture tube and the control loop stores a part measuring
signal or a part control signal derived therefrom for each color
signal, characterized in that the change detection arrangement includes a
change detector for each color signal which delivers a part change
signal when the relevant stored signal has assumed a largely constant
value, and the logic network does not release the control of the beam
currents by the color signals outside the sampling intervals until the
part change signals have been delivered by all change detectors.
3. Circuit arrangement as set forth in claim 1,
including a comparator arrangement which compares the measuring signal
with the reference signal and derives the control signal from this
comparison, characterized in that the change detection arrangement
detects a change in the control signal with respect to time and issues
the change signal when the control signal has assumed a largely constant
value.
4. Circuit arrangement as set forth in claims 1, 2, 3
including a control signal memory which contains at least one
capacitor, characterized in that the change detection arrangement
delivers the change signal when a charge-reversing current of the
capacitor occuring during the starting up of the picture tube falls
below a limit value.
5. Circuit arrangement as set forth in claim 2,
including a comparator arrangement which compares the measuring signal
with the reference signal and derives the control signal from this
comparison, characterized in that the change detection arrangement
detects a change in the control signal with respect to time and issues
the change signal when the control signal has assumed a largely constant
value.
The invention relates to a circuit arrangement for the control of at least one beam current in a picture tube by a picture signal with a control loop which in one sampling interval obtains a measuring signal from the value of the beam current on the occurrence of a given reference level in the picture signal, stores a control signal derived therefrom until the next sampling interval and by this means adjusts the beam current to a value preset by a reference signal, and with a trigger circuit which suppresses auxiliary pulses used to generate the beam current after the picture tube is turned on and issues a switching signal for the purpose of closing the control loop during the sampling intervals and releasing the control of the beam current by the picture signal after the measuring signal has exceeded a threshold value.
Such a circuit arrangement has been described in Valvo Technische Information 820705 with regard to the integrated color decoder circuit PHILIPS TDA3562A and is used in this as a so-called cut-off point control. In the known circuit arrangement, such a cut-off point control provides automatic compensation of the so-called cut-off point of the picture tube, i.e. it regulates the beam current in the picture tube in such a way that for a given reference level in the picture signal the beam current has a constant value despite tolerances and changes with time (aging, thermal modifications) in the picture tube and the circuit arrangement, thereby ensuring correct picture reproduction.
Such a blocking point control is particularly advantageous for the operation of a picture tube for the display of color pictures because in this case there are several beam currents for different color components of the color picture which have to be in a fixed ratio with one another. If this ratio changes, for example, as the result of manufacturing tolerances or ageing processes, distortions of the colors occur in the reproduction of the color picture. The beam currents, therefore, have to be very accurately balanced. The said cut-off point control prevents expensive adjustment and maintenance time which is otherwise necessary.
Conventional picutre tubes are constructed as cathode-ray tubes with hot cathodes which require a certain time after being turned on for the hot cathodes to heat up. Not until a final operating temperature has been reached do these hot cathodes emit the desired beam currents to the full extent, while gradually rising beam currents occur in the time interval when the hot cathodes are heating up. The instantaneous values of these beam currents depend on the instantaneous temperatures of the hot cathodes and on the accelerating voltages for the picture tube which build up simultaneously with the heating process and are undefined until the end of the heating time. After the picture tube is turned on, these values initially produce a highly distorted picture until the beam currents have attained their final value. These picture distortions after the picture tube is turned on are even further intensified by the fact that the cut-off point control is not yet adjusted to the beam currents which flow after the heating time is over.
For the purpose of suppressing distorted pictures during the heating time of the hot cathodes, the known circuit arrangement has a turn-on delay element operating as a trigger circuit which, in essence, contains a bistable flip-flop. When the picture tube and the circuit arrangement controlling the beam currents flowing in it are turned on, the flip-flop is switched into a first state in which it interrupts the supply of the picture signal to the picture tube. Thus, during the heating time the beam currents are suppressed, and the picture tube does not yet display any picture. In sampling intervals which are provided subsequent to flybacks of the cathode beam into an initial position on the changeover from the display of one picture to the display of a subsequent picture and even within the changeover, that is outside the display of pictures, the picture tube is controlled for a short time in such a way that beam currents occur when the hot cathodes are sufficiently heated up and an accelerating voltage is resent. If these currents exceed a certain threshold value, the flip-flop circuit switches into a second state and releases the picture signal for the control of the beam currents and the cut-off point control.
It is found, however, that the picture displayed in the picture tube immediately after the switching over of the flip-flop is still not fault-free. Because, in fact, the beam currents are supported during the heating time of the hot cathodes, the cut-off point control cannot respond yet. This response of the cut-off point control takes place only after the beam currents are switched on, i.e. after the flip-flop is switched into the second state and therefore at a time in which the picture signal already controls the beam currents. In this way the response of the blocking point control makes its presence felt in the picture displayed.
With the known circuit arrangement the brightness of the picture gradually increases, during the response of the cut-off point control, from black to the final value.
This slow increase in the picture brightness after the tube is turned on is disturbing to the eyes of the viewer not only in the case of the black-and-white picture tubes with one hot cathode, but especially so in the case of colour picture tubes which usually have three hot cathodes. With a color picture tube, color purity errors can also occur in addition to the change in the picture brightness if, as a result of different speeds of response of the cut-off point control for the three beam currents, there are found to be intermittent variations from the interrelation between the beam currents required for a correct picture reproduction.
SUMMARY OF THE INVENTION
The aim of the invention is to create a circuit arrangement which suppresses the above-described disturbances of brightness and color of the displayed picture when the picture tube is being started.
The invention achieves this aim in that a circuit arrangement of the type mentioned in the preamble contains a change detection arrangement which emits a change signal when the stored signal has assumed an essentially constant value, and a logic network which does not release the control of the beam current by the picture signal until the change signal has also been emitted after the switching signal.
In the circuit arrangement according to the invention, therefore, the display of the picture is suppressed after the picture tube is turned on until the cut-off point control has responded. If the picture signal then starts to control the beam current, a perfect picture is displayed immediately. In this way, all the disturbances of the picture which affect the viewer's pleasure are suppressed. The circuit arrangement of the invention is of simple design and can be combined on one semiconductor wafer with the existing picture signal processing circuits and also, for example, with the known circuit arrangement for cut-off point control. Such an integrated circuit arrangement not only requires very little space on the semiconductor wafer, but also needs no additional external leads. Thus the circuit arrangement of the invention can be arranged, for example, in an integrated circuit which has precisely the same external connections as known integrated circuits. This means that an integrated circuit containing the circuit arrangement of the invention can be directly incorporated in existing equipment without the need for additional measures.
In one embodiment of the said circuit arrangement, in which the picture signal contains several color signals for the control of a corresponding number of beam currents for representing a color picture in the picture tube and, for each color signal, the control loop stores a part measuring signal or a part control signal derived from it, the change detection arrangement contains a change detector for each color signal which emits a part change signal when the relevant stored signal has assumed an essentially constant value, and the logic network does not release the control of the beam currents by the color signals outside the sampling intervals until the part change signals have been emitted from all change detectors.
In principle, therefore, such a circuit arrangement has three cut-off point controls for the three beam currents controlled by the individual color signals. To reduce the cost of the circuitry, the measuring stage is common to all the cut-off point controls, as in the known circuit arrangement. All three beam currents are then measured successively by this measuring stage. In this way, a part measuring signal or a part control signal derived from it is obtained for each beam current and is stored sesparately according to which of the beam currents it belongs. Changes in the part measuring signal or part control signal are detected for each beam current by one of the change detectors each time. Each of these change detectors issues a part change signal to the logic network. The latter does not release the control of the beam currents by the picture signal outside the sampling intervals until all the part change signals indicate that the part measuring signal or the part control signal, as the case may be, remains constant. This ensures that the cut-off point controls for the beam currents of all color signals have responded when the picture appears in the picture tube.
In a further embodiment of the circuit arrangement according to the invention with a comparator arrangement which compares the measuring signal with the reference signal and derives the control signal from this comparison, the change detection arrangement detects a change in the control signal with respect to time and issues the change signal when the control signal has assumed an essentially constant value. In the case of the representation of a color signal the comparator arrangement derives several part control signals, whose changes with time are detected by the change detectors, from a corresponding comparison of the part measuring signals with the reference signal. In this embodiment of the circuit arrangement of the invention, preference is given to storage of only the control signal or the part control signals for the purpose of controlling the beam currents.
In another embodiment of the circuit arrangement of the invention which includes a control signal memory which contains at least one capacitor in which a charge or voltage corresponding to the control signal is stored, the change detection arrangement issues the change signal when a charge-reversing current of the capacitor occurring during the turning on of the picture tube has fallen below a limit value and has thus at least largely decayed. Such a detection of the steady state of the cut-off point control is independent of the actual magnitude of the control signal and therefore independent of, for example, the level of the picture tube cut-off voltage, circuit tolerances or ageing processes in the circuit arrangement or the picture tube.
Detection of whether or not the charge-reversing current exceeds the limit value is performed preferentially by a current detector which is designed with a current mirror system which is arranged in a supply line to a capacitor acting as a control signal store. A current mirror arrangement of this kind supplies a current which coincides very precisely with the charging current of the capacitor. This current is then compared, preferably in a further device contained in the change detection arrangement, with a current representing a limit value or, after conversion into a voltage, with a voltage representing the limit value. The change signal is obtained from the result of this comparison.
On the other hand, digital memories may also be used as control signal memories, especially when the picture signal is supplied as a digital signal and the blocking point control is constructed as a digital control loop. In such a case, the comparator arrangement, the change detection arrangement and the trigger circuit are also designed as digital circuits. Then, the change detection arrangement advantageously forms the difference of the signals stored in the control signal memory in two successive sampling intervals and compares this with the limit value formed by a digital value. If the difference falls short of the limit value, the change signal is issued.
BRIEF DESCRIPTION OF THE DRAWINGS
An embodiment of the invention is described in greater detail below with the aid of the drawings in which:
FIG. 1 shows a block circuit diagram of the embodiment,
FIG. 2 shows a somewhat more detailed block circuit diagram of the embodiment,
FIG. 3 shows time-dependency diagrams of some signals occurring in the circuit diagram shown in FIG. 2, and
FIG. 4 shows a somewhat moredetailed block circuit diagram of a part of the circuit diagram shown in FIG. 2.
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows a block circuit diagram of a circuit arrangement to which a picture signal is fed via a first input 1 of a combinatorial stage 2. From the output 3 of the combinatorial stage 2 the picture signal is fed to the picture signal input of a controllable amplifier 5 which at an output 6 issues a current controlled by the picture signal. This current is fed via a measuring stage 7 to a hot cathode 8 in a picture tube 9 and forms therein a beam current of a cathode ray by means of which a picture defined by the picture signal is displayed on a fluorescent screen of the picture tube 9.
The measuring stage 7 measures the current fed to the hot cathode 8, i.e. the the beam current in the picture tube 9, and at a measuring signal output 10, issues a measuring signal corresponding to the magnitude of this current. This is fed to a measuring signal input 11 of a comparator arrangement 12 to which a reference signal is supplied at a reference signal input 13. In a preferably periodically recurring sampling interval during the occurrence of a given reference level in the picture signal, the comparator arrangement 12 forms a control signal from the value of the measuring signal fed to the measuring signal input 11 at this time, on the one hand, and the reference signal, on the other, by means of substraction and delivers this at a control signal output 14. From there the control signal is fed to an input 15 of a control signal memory 16 and is stored in the latter. The control signal is fed via an output 17 of the control signal memory 16 to a second input 18 of combinatorial stage 2 in which it is combined with the picture signal, e.g. added to it.
The combinatorial stage 2, the controllable amplifier 5, the measuring stage 7, the comparator arrangement 12 and the control signal memory 16 form a control loop with which the beam current is guided towards the reference signal in the sampling interval during the occurrence of the reference level in the picture signal. For the reference level, use is made in particular of a black level or a level with small, fixed distance from the black level, i.e. a value in the picture signal which produces a black or almost back picture area in the displayed picture in the picture tube. In this case the control loop, as described, forms a cut-off point control for the picture tube. If the reference level is away from the black level, the control loop is also designated as quasi-cut-off-point control.
The circuit arrangement as shown in FIG. 1 also has a trigger circuit 19 to which the measuring signal from the measuring signal output 10 of measuring stage 7 is fed at a measuring signal input 20. When the circuit arrangement and therefore the picture tube are turned on, the trigger circuit 19 is set in a first state in which by means of a first connection 21 it blocks the comparator arrangement 12 in such a way that the latter delivers no control signal or a control signal with the value zero at its control signal output 14. This prevents the control signal memory 16 from storing undefined values for the control signal at the moment of turning on or immediately thereafter.
The circuit arrangement shown in FIG. 1 also has a logic network 22 which is connected via a second connection 23, by means of which a switching signal is supplied, with the trigger circuit 10 and via a third connection 24 with the controllable amplifier 5. Like the trigger circuit 19, the logic network 22 also finds itself controlled, when the circuit arrangement is being turned on, by the switching signal in a first stage in which by way of the third connection 24 it blocks the controllable amplifier 5 with a blocking signal in such a way that no beam currents controlled by the picture signal can yet flow in the picture tube 9. Thus the picture tube 9 is blanked; no picture is displayed yet.
When picture tube 9 is turned on, the hot cathode 8 is still cold so that no beam current can flow anyhow. The hot cathode 8 is then heated up and, after a certain time, begins gradually to emit electrons as the result of which a cathode ray and therefore a beam current can form. However, during the heating up of the hot cathode 8, and because the cut-off point control has not yet responded, this would be undefined and is therefore suppressed by the controllable amplifier 5. Only in time intervals which are provided immediately subsequent to flybacks of the cathode rays into an initial position at the changeover from the display of one image to that of a subsequent image, but even before the start of the display of the subsequent image, the controllable amplifier 5 delivers a voltage in the form of an auxiliary pulse for a short time at its output 6, and when the hot cathode 8 in the picture tube 9 is heated up sufficiently, this voltage produces a beam current. The time interval for the delivery of this voltage is selected in such a way that a cathode ray produced by its does not produce a visible image in the picture tube 9, and coincides for example with the sampling interval.
The measuring stage 7 measures the short-time cathode current produced in the manner described and, at its measuring signal output 10, delivers a corresponding measuring signal which is passed via measuring signal output 20 to the trigger circuit 19. If the measuring signal exceeds a definite preset threshold value, the trigger circuit 19 is switched into a second state in which it releases the comparator arrangement 12 via the first connection 12 and, by means of the second connection 23, uses the switching signal to also bring the logic network 22 into a second state. The comparator arrangement 12 now evaluates the measuring signal supplied to it via the measuring signal input 11, i.e. it forms the control signal as the difference between the measuring signal and the reference signal supplied via the reference signal input 13. The control signal is transferred via the control signal output 14 and the input 15 into the control signal memory 16. It is subsequently fed via the output 17 of the control signal memory 16 to the second input 18 of the combinatorial stage 2 and is there combined with the picture signal at the first input 1, e.g. is superimposed on it by addition. This superimposed picture signal is fed to the picture signal input 4 of the controllable amplifier 5 via the output 3 of the combinatorial stage 2.
In the second state of the logic network 22 the controllable amplifier 5 is switched via the third connection 24 by the blocking signal in such a way that the picture signal controls the beam currents only during the sampling intervals and that, for the rest, no image appears yet in the picture tube. The cut-off point control now gebins to respond, i.e. the value of the control signal is changed by the control loop comprising the combinatorial stage 2, the controllable amplifier 5, the measuring stage 7, the comparator arrangement 12 and the control signal memory 16 until such time as the beam current in the picture tube 9 at the blocking point or at a fixed level with respect to it is adjusted to a value preset by the reference signal. For this purpose the sampling interval, in which the picture signal controls the beam current via the controllable amplifier 5 is selected in such a way that within it the picture signal just assumes a value corresponding to the cut-off point or to a fixed level with respect to it.
During the response of the cut-off point control the control signal fed to the control signal memory 16 changes continuously. Between the control signal output 14 of the comparator arrangement 12 and the input 15 of the control signal memory 16 is inserted a changed detection arrangement 25 which detects the variations of the control signal. When the cut-off point control has responded, i.e. the control signal has assumed a constant value, the change detection arrangement 25 delivers a change signal at an output 26 which indicates that the steady stage of the cut-off point control is achieved and the said signal is fed to a change signal input 27 of the logic network 22. The logic network then switches into a third state in which via the third connection 24 it enables the controllable amplifier 5 in such a way that the beam currents are now controlled without restriction by the picture signal. Thus a correctly represented picture appears in the picture tube 9.
A shadow-like representation of individual constituents of the circuit arrangement in FIG. 1 is used to indicate a modification by which this circuit arrangement is equipped for the representation of color pictures in the picture tube 9. For example, three color signals are fed in this case as the picture signal via the input 1 to the combinatorial stage 2. Accordingly, the input 1 is shown in triplicate, and the combinatorial stage 2 has a logic element, e.g. an adder, for example of these color signals. The controllable amplifier 5 now has three amplifier stages, one for each of the color signals, and the picture tube now contains three hot cathodes 8 instead of one so that three independent cathode rays are available for the three color signals.
However, to simplify the circuit arrangement and to save on components, only one measuring stage 7 is provided which measures all three beam currents successively. Also, the comparator arrangement 12 forms part control signals from the successively arriving part measuring signals for the individual beam currents with the reference signal, and these part control signals are allocated to the individual color signals and passed on to three storage units which are contained in the control signal memory 16. From there, the part control signals are sent via the second input 18 of the combinatorial stage 2 to the assigned logic elements.
The circuit arrangement thus forms three independently acting control loops for the cut-off point control of the individual color signals, in which case only the measuring stage 7 and to some extent at least the comparator arrangement 12 are common to these control loops.
The change detection arrangement 25 now has three change detectors each of which detects the changes with time of the part control signals relating to a color signal. Then via the output 26 each of these change detectors delivers a part change signal to the change signal input 27 of the logic network 22. These part change signals occur independently of one another when the relevent control loop has responded. The logic network 22 evaluates all three part change signals and does not switch into its third stage until all part change signals indicate a steady state of the control loops. Only then, in fact, is it ensured that all the color signals from the beam currents controlled by them are correctly reproduced in the picture tube, and thus no distortions of the displayed image, especially no color purity errors, occur. The color picture displayed then immediately has the correct brightness and color on its appearance when the picture tube is turned on.
FIG. 2 shows a somewhat more detailed block circuit diagram of an embodiment of a circuit arrangement equipped for the processing of a picture signal containing three colour signals. Three color signals for the representation of the colors red, green and blue are fed to this circuit arrangement via three input terminals 101, 102, 103. A red color signal is fed via the first input terminal 101 to a first adder 201, a green colour signal is fed via the second input terminal to a second adder 202, and a blue colour signal is fed via the third input terminal 103 to a third adder 203. From outputs 301, 302 and 303 of the adders 201, 202, 203 the color signals are fed to amplifier stages 501, 502 and 503 respectively. Each of the amplifier stages contains a switchable amplifier 511, 512 and 513, an output amplifier 521, 522 and 523 as well as a measuring transistor 531, 532 and 533 respectively. The emitters of these measuring transistors 531, 532, 533 are each connected to a hot cathode 801, 802, 803 of the picture tube 9 and deliver the cathode currents, whereas the collectors of measuring transistors 521, 532, 533 are connected to one another and to a first terminal 701 of a measuring resistor 702 the second terminal of which 703 is connected to earth. The current gain of the measuring transistors 531, 532 and 533 is so great that their collector currents coincide almost with the cathode currents. By measuring the voltage drop produced by the cathode currents at the measuring resistor 802 it is then possible to measure the cathode currents and therefore the beam currents in the picture tube 9 with great accuracy.
The falling voltage at the measuring resistor 702 is fed as a measuring signal to an input 121 of a buffer amplifier 120 with a gain factor of one, at the output 122 of which the unchanged measuring signal is therefore available at low impedance. From there it is fed to a first terminal 131 of a reference voltage source 130 which is connected with its second terminal 132 to inverting inputs 111, 112 and 113 of three differential amplifiers 123, 124, 125 respectively. The differential amplifiers 123, 124, 125 also each have a non-inverting input 114, 115, and 116 respectively. These are connected to each other at a junction 117, to earth via a leakage current storage capacitor 126 and to the output 122 of the buffer amplifier 120 via decoupling resistor 118 and a leakage current sampling switch 119. In addition, the input 121 of the buffer amplifier 120 can be connected to earth via a short-circuiting switch 127.
From outputs 141, 142, and 143 respectively of the differential amplifiers 123, 124 and 125, part control signals relating to the individual color signals are fed in the form of electrical voltages (or, in some cases, charge-reversing currents) via control signal sampling switches 154, 155 and 156, in the one instance, to first terminals 151, 152 and 153 respectively of control signal storage capacitors 161, 162, 163 which form the storage units of the control signal memory 16 and store inside them charges corresponding to these voltages (or formed by the charge-reversing currents). In the other instance, the part control signals are fed to second inputs 181, 182 and 183 of the first, second or third adders 201, 202, 203 respectively and are added therein to the color signals from the first, second or third input terminals 101, 102 or 103 respectively.
The operation of the comparator arrangement 12 which consists mainly of the buffer amplifier 120, the reference voltage source 130 and differential amplifiers 123, 124, 125 will be explained below with the aid of the pulse diagrams in FIG. 3. FIG. 3a shows a horizontal blanking signal for a television signal which, as the picture signal, controls the beam currents in the picture tube 9. In this diagram, H represents horizontal blanking pulses which follow one another in the picture signal at the time interval of one line duration and by means of which the beam currents are switched off during line flyback between the display of the individual picture lines in the picture tube. FIG. 3b shows a vertical blanking pulse V by means of which the beam currents are switched off during the change ober from the display of one picture to the display of the next picture. FIG. 3c shows a measuring signal control pulse VH which is formed from a vertical blanking pulse lengthened by three line duration.
The short-circuiting switch 127 is now controlled in such a way that it is non-conducting only throughout the duration of the measuring signal control pulse VH and during the remaining time short-circuits the input 121 of the buffer amplifier 120 to earth. This means that a measuring signal only reaches the comparator arrangement 12 during frame change so that the parts of the picture signal which control the beam currents producing the picture in the picture tube exert no influence on comparator arrangement 12 and therefore on the blocking point control.
Throughout the duration of the measuring signal control pulse VH, the measuring signal from output 122, reduced by a reference voltage issued by the reference voltage source 130 between its first 131 and its second terminal 132, is present at the inverting inputs 111, 112, 113 of differential amplifiers 123, 124, 125. If the differential amplifiers 123, 124, 125 were not present, this difference would be fed directly as part control signals to the control signal storage capacitors 161, 162, 162. The differential amplifiers 123, 124, 125 amplify the difference and thus form the control amplifiers of the control loops.
The comparator arrangement 12 further contains a device for compensation of the influence of any leakage currents occurring in the picture tube 9. For this purpose, a voltage to which the leakage current storage capacitor 126 is charged is fed to the non-inverting inputs 114, 115, 116 of the three differential amplifiers 123, 124 and 125. The charging is performed by the measuring signal from output 122 of the buffer amplifier 120 via the decoupling resistor 118 and the leakage current sampling switch 119 which is closed only within the period of the vertical blanking pulse V, and in certain cases only during part of the latter. Within this time the beam currents are, in fact, totally switched off by the picture signal so that in certain cases only a leakage current flows through the measuring resistor 702. Consequently, throughout the duration of the vertical blanking pulse V the measuring signal corresponds to this leakage current. Because the leakage current also flows during the remaining time, even outside the duration of the vertical blanking pulse the measuring signal contains a component originating from the leakage current which therefore is also contained in the voltage fed to the inverting inputs 111, 112, 113 of differential amplifiers 123, 124, 125 and is subtracted out in the differential amplifiers 123, 124, 125.
The part control signal is fed from output 141 of differential amplifier 123 by the first control signal sampling switch 154 to the first terminal 151 of the first control signal storage capacitor 161 during the period of a storage pulse L1 and is stored in the said capacitor. Similarly, the part control signal from output 143 of differential amplifier 125 is fed to the third control signal storage capacitor 163 during the period of a storage pulse L2 and the part control signal from output 142 of differential amplifier 124 is fed to the second control signal storage capacitor 162 during a storage pulse L3. The storage pulses L1, L2 and L3 are illustrated in FIGS. 3d, e and f. They lie in sequence in one of the three line periods by which the measuring signal control pulse VH is longer than the vertical blanking pulse V. These three line periods form the sampling interval for the measuring signal or the part measuring signals, as the case may be. During the remaining periods the outputs, 141, 152, 143 of the differential amplifiers 123, 124, 125 are isolated from the control signal storage capacitors 161, 162, 163 so that no interference can be transmitted from there and any distortion of the stored part control signals caused thereby is eliminated. For the duration of storage pulses L1, L2 and L3 the color signals at the input terminals 101, 102, 103 are at their reference level i.e. in the present embodiment at a level, corresponding to the blocking point or at a fixed level with respect to it so that the control loops can adjust to this level.
The switchable amplifiers 511, 512, and 513 each receive at each input 241, 242, 243 a blanking signal BL1, BL2, BL3 respectively, the curves of which are shown in FIGS. 3g, h, i. These blanking signals interrupt the supply of the color signals during line flybacks and frame change, i.e. during the period of the measuring signal control pulse VH, and thus the beam currents in these time intervals are switched off. Naturally, the red color signal is let through during the first line period after the end of the vertical blanking pulse V, the blue color signal during the second line period after the end of the vertical blanking pulse V and the green color signal during the third line period after the end of the vertical blanking pulse V by the switchable amplifiers 511, 512, 513 respectively so that they can control the beam currents. Blanking signals BL1, BL2 and BL3 also provide for interruptions in the frame change blanking pulse, which corresponds to the measuring signal control pulse, in the corresponding time intervals. In these time intervals the beam currents are measured and part control signals are determined from the part measuring signals and stored in the control signal storage capacitors 161, 162, 163.
The circuit arrangement shown in FIG. 2 further contains a trigger circuit 19 to which a supply voltage is fed via a supply terminal 190. Via a reset input 191 a voltage is also supplied to the trigger circuit 19 from a third terminal 133 of the reference voltage source 130. When the circuit arrangement is turned on, this voltage is designed so as to be delayed with respect to the supply voltage so that when the circuit arrangement is brought into operation the interplay of the two voltages produces a switch-on reset signal such that a low-value voltage pulse occurs at the reset input 191 during turn on, which means that the trigger circuit 19 is set in its first state. The reset input 191 can also be connected to another circuit of any configuration which generates a switch-on reset signal when the picture tube is turned on.
The trigger circuit 19 is further connected via a second connection 23 to a logic network 22 which, when the circuit arrangement is turned on, is also set into a first state via the second connection 23. In this first state the logic network 22 delivers a blocking signal at a blocking output 240 which is fed to the three switchable amplifiers 511, 512, 513. By this means the supply of the color signals to the output amplifiers 521, 522, 523 is interrupted completely so that no beam currents can be generated by these. No picture is therefore displayed.
An insertion signal EL which extends over the three line periods by which the measuring signal control pulse VH is longer than the vertical blanking pulse V, i.e. over the sampling interval, is also fed via a line 233 to the trigger circuit 19 and the logic network 22. As long as the trigger circuit 19 is in its first state, this insertion pulse EL is issued via a control output 192 from the trigger circuit 19 and fed to the pulse generator 244. During the period of the insertion pulse EL this generator produces a voltage pulse of a definite magnitude and passes this to output amplfiiers 521, 522, 523 as an auxiliary pulse via switching diodes 245, 246, 247. By this means the beam currents are switched on for a short time so as to receive a measuring signal despite the disconnected color signals as soon as at least one of the hot cathodes 801, 802, 803 delivers a beam current.
In its first state the trigger circuit 19 also delivers a signal via a control line 211, and this signal is used to switch the outputs 141, 142, 143 of the differential amplifiers 123, 124, 125 to earth potential or practically to earth potential. This suppresses effects of voltages at the inputs 111 to 116 of the differential amplifiers 123, 124, 125, especially effects of the reference voltage source 130 which may in some cases initiate incorrect charging of the control signal storage capacitors 161, 162, 163.
The measuring signal produced by means of the pulse generator 244 at the input 121 of the buffer amplifier 120 is also fed to the trigger circuit 19 via a measuring signal input 20. If it exceeds a preset threshold value, the trigger circuit 19 switched into its second state. The logic network 22 is then also switched into its second state via the second connection 23. The differential amplifiers 123, 124, 125, too, are triggered by the signal along the control line 211 into issuing a control signal defined by the difference in the voltages at its inputs 111 to 116. The pulse generator 244 is blocked by the control output 192. The blocking signal issued from the blocking output 240 of the logic network 22 now turns on the switchable amplifiers 511, 512, 513 in the time intervals defined by the storage pulses L1, L2, L3 in such a way that in these time intervals the color signals can produce beam currents to form a measuring signal by which the control loops respond. However, the display of the picture is still suppressed. The control signal storage capacitors 161, 162, 163 are charged up in this process. In the leads to the first terminals 151, 152, 153 there are change detectors 251, 252, 253 which detect the changes of the charging currents of the control signal storage capacitors 161, 162, 163 and at their outputs 261, 262, 263 in each case deliver a part change signal when the charging current of the control signal storage capacitor in question has decayed and thus the relevant control loop has responded. The part change signals are fed to three terminals 271, 272, 273 of the change signal input 27 of the logic network 22.
When part change signals are present from all change detectors 251, 252, 253, when therefore all control loops have responded, the logic network 22 switches from its second to its third state. The blocking signal from the blocking output 240 is now completely disconnected such that the switchable amplifiers 511, 512, 513 are now switched only by the blanking signals BL1, BL2, BL3. The colour signals are then switched through to the output amplifiers 521, 522, 523 and the picture is displayed in the picture tube.
FIG. 4 shows an embodiment for a trigger circuit 19 and a logic network 22 of the circuit arrangements as shown in FIGS. 1 or 2. The trigger circuit 19 contains a flip-flop circuit formed from two NAND-gates 194, 195 to which the switch-on reset signal, by which the trigger circuit 19 is returned to its first stage, is fed via the reset input 191. All the elements of the circuit arrangement in FIG. 4 are shown in positive logic. Thus, a short-time low voltage at the reset input 191 immediately after the circuit arrangement is started up is used to set the flip-flop circuit 194, 195 in such a way that a high voltage occurs at the output of the second NAND gate 194 and a low voltage at the output of the second NAND gate 195. The low voltage at the output of the second NAND gate 195 blocks differential amplifiers 123, 124, 125 via the control line 211 in the manner described.
The insertion pulse EL is fed via the line 233 to the trigger circuit 19, is combined via an AND gate 196 with the signal from the output of the first NAND gate 194 and is delivered at the control output 192 for the purpose of controlling the pulse generator 244.
The signals from the outputs of the NAND-gates 194, 195 are fed via a first line 231 and a second line 232 of the second connection 23 as a switching signal to the logic network 22. The first line 231 is connected to reset inputs R of three part change signal memories 221, 222, 223 in the form of bistable flip-flop circuits which when the circuit arrangement is started up are reset via the first line 231 in such a way that they carry a low voltage at their outputs Q. The second line 232 of the second connection 23 leads via three AND gates 224, 225, 226 to setting inputs S of the three part change signal memories 221, 222, 223. By means of the AND gates 224, 225, 226 the signal on the second line 232 of the second connection 23 is combined each time with one of the part change signals supplied via the terminals 271, 272, 273. The signals from the outputs Q of the part change signal memories 221, 222, 223 are combined by means of a collecting gate 227 in the form of an NAND gate and are held ready at its output 228.
The measuring signal is fed to the trigger circuit 19 via the measuring signal input 20 and passed to a first input 197 of a threshold detector 198 to which at a second input a threshold value, in the form of a threshold voltage for example, produced by a threshold generator 199 is also supplied. When the voltage at the first input 197 of the threshold detector 198 is smaller than the voltage delivered by the threshold generator 199, the threshold detector 198 delivers a high voltage at its output 200. When, on the other hand, the voltage at the first input 197 is greater than the voltage of the threshold generator 199, the voltage at the output 200 jumps to a low value. This voltage is supplied as the setting signal of the flip-flop circuit 194, 195, reverses the latter and thereby switches the trigger circuit 19 into its second state when the voltage at the first input 197 exceeds the voltage of the threshold generator 199.
Between the output 200 and the flip-flop circuit 194, 195 in the circuit arrangement shown in FIG. 4 there is inserted an inquiry gate 181 in the form of an OR gate to which an inquiry pulse is fed via an inquiry input 193 of the trigger circuit 19. This ensures that the flip-flop circuit 194, 195 is switched over only at a time fixed by the inquiry pulse--in the present case a negative voltage pulse--and not at any other times due to disturbances. As such an inquiry pulse it is possible to use, for example, a pulse which occurs in the second line period after the end of the vertical blanking pulse V, i.e. one which largely corresponds to the storage pulse L2.
After the switching over of the flip-flop circuit 194, 195 corresponding to the setting of the trigger circuit 19 into the second state, appropriately modified signals are supplied via the control line 211 and the output 192 for the purpose of controlling the pulse generator 244 and the differential amplifiers 123, 124, 125. Modified voltages also appear on the lines 231, 232 of the second connection 23, and these voltages release the part change signal memories 221, 222, 223 such that they can each be set when the part change signals reach the terminals 271, 272, 273.
In certain cases, a further flip-flop circuit 234 is inserted in the lines 231, 232 to delay the signals passing along these lines; this is reset via the first line 231 when the circuit arrangement is started up and thus it also resets the part change signal memories 221, 222, 223. However, after the trigger circuit 19 is switched into the second state the further flip-flop circuit 234 is not set via the second line 232 of the second connection 23 until a release pulse arrives via a release input 235 and another AND gate 236, for example a period of approximately the interval of two vertical blanking pulses V after the switching of the trigger circuit 19 into the second state. In this way it is possible to bridge a period of time in which no defined signal values are present at the terminals 271, 272, 273.
The signal at the output 228 of the collecting gate 227 changes its state when the last of the three part change signals has also arrived and has set the last of the three part change signal memories. The signal is then combined via a gate arrangement 229 of two NAND gates and one AND gate with the insertion pulse EL of line 223 and with the signal on the second line 232 of the second connection 23 or from the output Q of the further flip-flop circuit 234 to the blocking signal delivered at the blocking output 24 which is fed to the switchable amplifiers 511, 512, 513.
FIGS. 31, m, n show the combinations of the blocking signal with the blanking signals BL1, BL2, and BL3 at the blanking inputs 241, 242, 243 of the switchable amplifiers 511, 512, 513 in the form of logic AND operations. The dot-dash lines show resulting insertion signals A1, A2, A3 formed by these operations after the starting up of the circuit arrangement and before the occurrence of a beam current, i.e. in the first state of the logic network 22. Here the resulting insertion signals A1, A2, A3 are constant at low level. The dash curves show the resulting insertion signals A1, A2, A3 after the appearance of a beam current and before the steady state of the cut-off point control is reached, i.e. in the second state of the logic network 22, while the continuous curves represent the resulting insertion signals A1, A2, A3 in the steady state of the cut-off point control, i.e. in the third state of logic network 22. The dash curves have similar shapes to storage pulses L1, L2, L3, whereas the continuous curves correspond in shape to the inverses of the blanking signals BL1, BL2, BL3. In this case a high level of the resulting insertion signals A1, A2 or A3 means that the switchable amplifier 511, 512 or 513 feeds the colour signal to the relevant output amplifier 521, 522 or 523 respectively, whereas a low level in the resulting insertion signal A1, A2 or A3 means that the relevant switchable amplifier 511, 512 or 513 is blocked for the color signal.
The circuit arrangement described is designed in such a way that the trigger circuit 19 remains in its second state and logic network 22 remains in its third state even if charging currents reappear at the difference signal storage cpacitors 161, 162, 163 due to disturbances during the operation of the circuit arrangement. The cutoff point control then makes readjustments without the displayed picture being disturbed.
In the circuit arrangement shown in FIG. 2, the green color signal can also be let through during the second line period after the end of the vertical blanking pulse V and the blue color signal during the third line period after the end of the vertical blanking pulse V by the switchable amplifiers 511, 512, 513 for the purpose of controlling the beam currents. The storage pulses L2 and L3 at the control signal sampling switches 155 and 156 and the second and third blanking signals BL2 and BL3 at the blanking inputs 242 and 243 are then to be interchanged. The resulting insertion signals A2 and A3 as shown in FIGS. 3m and n are also interchanged then accordingly.
In FIG. 2 a dashed line is used to indicate which components of the circuit arrangement can be combined advantageously to form an integrated circuit. The first terminals 151, 152, 153 of the difference signal storage capacitors 161, 162, 163, one terminal 128 of leakage current storage capacitor 126, three terminals 524, 525, 526 in the leads to the output amplifiers 521, 522, 523 as well as a line connection 704 between the first terminal 701 of the measuring resistor 702 and the input 121 of the buffer amplifier 120 will then form the connecting contacts of this integrated circuit.
TDA8191 TV SOUND CHANNEL
HIGH SENSITIVITY
.
EXCELLENT AM REJECTION
.
DC VOLUME CONTROL
.
PERITELEVISION FACILITY
.
4W OUTPUT POWER
.
LOW DISTORTION
.
THERMAL PROTECTION
.
TURN-ON AND TURN-OFF MUTING
The TDA8191 is a monolithic integrated circuit that includes all the functions needed for a complete TV sound channel.The TDA8191 is assembled in a 20 pin dual in line power package.
TEA2014A VIDEO SWITCH
VIDEO OUTPUT 75Ω- 1V PP NOT
. 1 SWITCHED
SWITCHED VIDEO OUTPUT 2VPP
. VIDEO CROSSTALK : 50dB TYPICAL
. SHORT CIRCUIT PROTECTION OF INPUTS
. CLAMPED AND OUTPUTS
VIDEO INPUTS,
This integrated circuit provides all video switching allowing connections between the peri TV plug and video sections in the TV set. The TEA2014A is supplied in a DIP8.
MIVAR 28V2E TVD CHASSIS TV3536/1
SDA2516 EAROM MIVAR RM2 CONTROL UNIT.
Features- Word-organized reprogrammable nonvolatile memory
in n-channel floating-gate technology (E2PROM)
- 128 ´ 8-bit organization
- Supply voltage 5 V
- Serial 2-line bus for data input and output (I2C Bus)
- Reprogramming mode, 10 ms erase/write cycle
- Reprogramming by means of on-chip control (without
external control)
- Check for end of programming process
- Data retention > 10 years
- More than 104 reprogramming cycles per address
- Compatible with SDA 2516. Exception:
Conditions for total erase and current consumption.
I2C Bus Interface
The I2C Bus is a bidirectional 2-line bus for the transfer of data between various integrated circuits.
It consists of a serial data line SDA and a serial clock line SCL. The data line requires an external
pull-up resistor to VCC (open drain output stage).
The possible operational states of the I2C Bus are shown in figure 1. In the quiescent state, both
lines SDA and SCL are high, i.e. the output stage of the data line is disabled. As long a SCL remains
"1", information changes on the data bus indicate the start or the end of data transfer between two
components.
The transition on SDA from "1" to "0" is a start condition, the transition from "0" to "1" a stop
condition. During a data transfer the information on the data bus will only change while the clock line
SCL is "0". The information on SDA is valid as long as SCL is "1".
In conjunction with an I2C Bus system, the memory component can operate as a receiver and as a
transmitter (slave receiver or slave transmitter). Between a start and stop condition, information is
always transmitted in byte-organized form. Between the trailing edge of the eighth clock pulse and a ninth acknowledge clock pulse, the memory component sets the SDA line to low as a confirmation
of reception, if the chip select conditions have been met. During the output of data, the data output
of the memory is high in impedance during the ninth clock pulse (acknowledge master).
The signal timing required for the operation of the I2C Bus is summarized in figure 2.
Control Functions of the I2C Bus
The memory component is controlled by the controller (master) via the I2C Bus in two operating
modes: read-out cycle, and reprogramming cycle, including erase and write to a memory address.
In both operating modes, the controller, as transmitter, has to provide 3 bytes and an additional
acknowledge clock pulse to the bus after the start condition. During a memory read, at least nine
additional clock pulses are required to accept the data from the memory and the acknowledge
master, before the stop condition may follow. In the case of programming, the active programming
process is only started by the stop condition after data input (see figure 3).
The chip select word contains the 3 chip select bits CS0, CS1 and CS2, thus allowing 8 memory
chips to be connected in parallel. Chip select is achieved when the three control bits logically
correspond to the selected conditions at the select inputs.
Check for End of Programming or Abortion of Programming Process
If the chip is addressed during active reprogramming by entering CS/E, the programming process
is terminated. If, however, it is addressed by entering CS/A, the entry will be ignored. Only after
programming has been terminated will the chip respond to CS/A. This allows the user to check
whether the end of the programming process has been reached (see figure 3).
Memory Read
After the input of the first two control words CS/E and WA, the resetting of the start condition and the
input of a third control word CS/A, the memory is set ready to read. During acknowledge clock
nine, the memory information is transferred in parallel mode to the shift register. Subsequent to the
trailing edge of the acknowledge clock, the data output is low impedance and the first data bit can
be sampled, (see figure 4).
With every shift clock, an additional bit reaches the output. After reading a byte, the internal address
counter is automatically incremented when the master receiver switches the data line to “low” during
the ninth clock (acknowledge master). Any number of memory locations can thus be read one after
the other. At address 128, an overflow to address 0 is not initiated. With the stop condition, the data
output returns to high-impedance mode. The internal sequence control of the memory component
is reset from the read to the quiescent with the stop condition.
Memory Reprogramming
The reprogramming cycle of a memory word comprises an erase and a subsequent write process.
During erase, all eight bits of the selected word are set into "1" state. During write, "0" states are
generated according to the information in the internal data register, i.e. according to the third input
control word.
After the 27th and the last clock of the control word input, the active programming process is started
by the stop condition.
The active reprogramming process is executed under onchip control.
The time required for reprogramming depends on component deviation and data patterns.
Therefore, with rated supply voltage, the erase/write process extends over max. 20 ms, or more
typically, 10 ms. In the case of data word input without write request (write request is defined as data
bit in data register set to “0”), the write process is suppressed and the programming time is
shortened. During a subsequent programming of an already erased memory address, the erase
process is suppressed again, so that the reprogramming time is also shorter.
MIVAR
MIVAR 21L1E TVD SCHEMATIC / CIRCUIT DIAGRAM:
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