The PHILIPS CHASSIS KM2 is an awesome and amazing example of PHILIPS ENGINEERING.
THE PHILIPS CHASSIS KM2 It's the first PHILIPS CHASSIS FOR MULTISTANDARD FEATURING PAL 625 LINE AND SECAM 819 LINES completely based on semiconductors and further advanced with ASIC'S around almost all signal processing boards even if the chassis is mainly based around discretes semiconductors both silicium and germanium diodes and transistor.
It's developed in 2 main sections boards panels:
- DEFLECTIONS LEFT SIDE (POWER SIGNALS PANEL)
- SIGNAL RIGHT SIDE (SMALL SIGNALS PANEL)
- MIDDLE BOTTOM POWER SUPPLY UNIT.
- ABOVE ADDITIONAL FRAME DEFLECTION UNIT.
The chassis CTV KM2 is higly sophisticated and complex but it has an unique fashinating structure and design which expands his technology in a way of simplicity which is today, long time, lost and forgotten (forever).
CIRCUIT ARRANGEMENT FOR GENERATING IN A PICTURE DISPLAY DEVICE A SAWTOOTH CURRENT OF LINE FREQUENCY HAVING AN AMPLITUDE VARYING AT FIELD FREQUENCY IN PHILIPS CHASSIS CTV KM2.A circuit arrangement for generating by means of a modulator in a colour picture display device a sawtooth correction current of line frequency flowing through the line deflection coils and having an amplitude varying at field frequency for the purpose of obtaining a better colour superposition in the corners of the screen of the display tube, comprising means to add an additional correction current which flows in the same direction as the first mentioned current and which is proportional to the third power of both the line and the field deflection currents. Said means may be a saturable coil or a resonant circuit which is tuned to a frequency which lies between the like frequency and twice the value thereof. In the latter case the voltage present across the circuit may be used for correcting the North-South pincushion distortion. Also, the modulator is controlled by an amplifier comprising a linear and a voltage-dependent resistor which ensure that a
third-power component is added also to said field deflection current.
1. A distortion correction circuit for line and field deflection coils of a display tube, said circuit comprising line and field deflection generator means coupled to said coils respestively for producing line and field deflection signals respectively; a modulator means for providing a line frequency first correction current having a field frequency varying amplitude to at least one of said coils; and means for supplying an additional correction current distinct from said deflection signals that is a thrid power function of at least one of said deflection signals and for applying it to said one deflection coil in the same direction as said first correction current.
2. A circuit as claimed in claim 1 wherein said supplying means comprises a non-linear inductor series coupled to said modulator and having an inductance that decreases with increasing current.
3. A circuit as claimed in claim 1 wherein said supplying means comprises a tuned circuit including an inductor and a capacitor parallel coupled thereto, said circuit being tuned to a frequency between the line frequency and twice the line frequency and being series coupled to said modulator.
4. A circuit as claimed in claim 3 wherein said inductor comprises a transformer primary, said transformer including a secondary; and further comprising means coupled to said secondary for correcting North-South pincushion distortion in said display tube.
5. A circuit as claimed in claim 1 wherein said modulator comprises diode switch means operating at the line frequency for coupling during the line scan time the field generator to a resonant circuit having a period twice the line flyback period, said resonant circuit including a capacitor and said line deflection coil; and further comprising a coil coupled in series between said line generator and said line coil.
6. A circuit as claimed in claim 5 further comprising a resistor series coupled to said capacitor.
7. A circuit as claimed in claim 5 further comprising a series circuit including in order a first capacitor, a pair of diodes that are non-conducting during the line flyback time, and a second capacitor, said series circuit being parallel coupled to said coil; and an inductance capacitance parallel resonant circuit coupled to the junction of the diodes, said circuit being resonant at a frequency between the line frequency and twice the line frequency.
8. A circuit as claimed in claim 1 further comprising amplifier means for applying said field signal to said modulator, said amplifier including a complementary pair of transistors adapted to receive a negative feedback network having an input coupled to the output electrodes of said transistors for receiving a zero average signal, said network comprising fixed and voltage dependent resistors coupled thereto.
9. A circuit as claimed in claim 1 further comprising a circuit coupled between said modulator and said field generator, said circuit comprising a fixed and a voltage dependent resistor parallel coupled thereto.
10. A circuit as claimed in claim 1 further comprising North-South pincushion correction means for adding a sinusoidal current of line frequency to said correction current.
11. A circuit as claimed 1 wherein said additional correction current is a third power function of both of said deflection signals.
U.S. Pat. No. 3,440,483 described a display device for colour television wherein for the purpose of correction on the screen of a display tube in the device use is made of a sawtooth correction current of line frequency having an amplitude varying at field frequency. From the beginning up to the end of the scan of a field period this correction current of line frequency is to decrease down to zero from a given value in a substantially linear manner, whereafter a substantially equal increase in the reverse current direction follows. This correction current is superimposed on the deflection current flowing in the line and/or field deflection coil, the peak-to-peak amplitude of the deflection current being substantially constant. Since the deflection coil is divided into two coil halves provided substantially symmetrically on either side of the neck of the display tube, it is possible to add the correction current in one coil half to the deflection current and to subtract it from the deflection current in the other coil half. The magnetic deflection field of one coil half will therefore be enlarged and that of the other coil half will be reduced to a substantially equal extent.
As has been described in the said U.S. patent the so-called anisotropic astigmatism of a deflection coil causes a distortion which gives an electron beam having a circular or ellipse cross-section a tilted ellipse shape, which distortion is dependent on the extent of the deflection. In other words, this distortion occurs most seriously in the corners of the displayed picture and it results in colour superposition errors. The said patent application shows that it is possible to eliminate this distortion with the aid of an oppositely directed distortion caused by the above-mentioned correction current.
The said amplitude variation of field frequency of the sawtooth current of line frequency is established by means of a modulator controlled by the field deflection current generator. The said patent application describes inter alia an arrangement wherein this modulator is formed as a multiplier to which information regarding the line and field deflection currents is supplied. If the centre horizontal line on the screen of the display tube is referred to as x'Ox and the central vertical line is referred to as y'Oy, wherein O is the centre of the screen while, as is common practice in mathematics, x'Ox extends from left to right y'Oy extends from bottom to top, it can be assumed that the compensating deviation Δ x which is established by means of the modulator is in the first instance proportional to x and to y. In this case x and y are the coordinates of one point on the screen relative to the previously defined system of coordinates. In this manner the compensating deviation Δ x is indeed increased in the corners of the screen and is zero on the axes x'Ox and y'Oy.
However, the invention is based on the recognition of the fact that the previously described correction is not sufficient to completely eliminate the colour superposition errors in the corners of the screen of the display tube. In order to be able to eliminate this the circuit arrangement according to the invention is characterized in that it includes means to add an additional correction current to the sawtooth current in the vicinity of the beginning and the end of each scan period, which additional current flows in the same direction as the said correction current and which is proportional to the third power of the line deflection current and to the third power of the field deflection current.
The correction currents may be produced in different manners. To this end the circuit arrangement according to the invention is further characterized in that the means for producing the additional correction current during the line scan period are obtained by means of a coil which is series-arranged with the modulator and whose inductance decreases when the current flowing therethrough increases and that the means for producing the additional correction current during the line scan period are obtained by means of a parallel circuit which is series-arranged with the modulator and whose resonant frequency lies between the line frequency and twice the value thereof.
Furthermore the invention is based on the recognition of the fact that the voltage which is present under these circumstances across the said parallel circuit may alternatively be used for other purposes. To this end, the circuit arrangement according to the invention is characterized in that the coil in the parallel circuit constitutes the primary winding of a transformer and that the voltage produced across the secondary winding of the transformer controls a circuit for the correction of the North-South pincushion distortion on the screen of a picture display tube present in the picture display device.
FRAME DEFLECTION CIRCUIT CHASSIS K9
A field deflection circuit in which the deflection coil is connected to a direct voltage source during the flyback period so as to reverse the polarity of the deflection current. For this purpose the deflection coil is connected through a switch controllable connected to the direct voltage source, which switch is controlled by the difference between a voltage proportional to the steep-edged sawtooth input signal and a voltage proportional to the deflection current. This difference is considerable during the flyback period and is utilized for switching on the controllable switch; it becomes zero as soon as the deflection current has reached its required value at which the switch is switched off again. It is thus achieved that the polarity reversal is always terminated when the required value is reached, even when the direct voltage fluctuates and also when the inductive load is changed.
1. A circuit for generating an output deflection current for a deflection coil from an input sawtooth deflection voltage signal having a polarity changes at the start of the flyback period which are short with respect to said flyback period; said circuit comprising an amplifier having an input adapted to receive said input signal, and an output means adapted to be coupled to said coil for providing said output current; means coupled to said amplifier for generating a control voltage that is the difference between a voltage that is proportional to said input signal and a voltage that is proportional to said output current; a direct voltage source; and means for rendering said output current independent of voltage and load variations comprising means for reversing the polarity of said deflection current at the start of said flyback period including a switch means coupled to said amplifier and said source and having a control input coupled to said means for generating for coupling said coil to said source at the start of said flyback period and separating said coil from said source upon said deflection current reaching a selected value required for the start of the scan period.
2. A circuit as claimed in claim 1, wherein said amplifier comprises a junction having a potential that differs from a threshold value during said flyback period, said switch being coupled to said junction and switching at about said threshold value; and further comprising feedback means for applying said voltage proportional to said deflection current to said amplifier input.
3. A circuit as claimed in claim 2 wherein said junction potential goes below said threshold value during said flyback period, said switch switching above said threshold value.
4. A circuit as claimed in claim 2 wherein said junction potential exceeds said threshold value during said flyback period, said switch switching below said threshold value.
5. A circuit as claimed in claim 2 wherein said amplifier comprises first and second final stage class B push pull transistors, each of said transistors having emitter and collector conduction electrodes, a conduction electrode of one of said transistors being coupled to a like conduction electrode of said other transistor, said first transistor being conductive during said start of said scan period; a pass direction coupled diode having a first end coupled to first transistor conduction electrode, and a second end adapted to receive a first terminal of a power supply; a capacitor having a first end coupled to said diode first end, and a second end coupled to said switch; and a resistor having a first end coupled to said capacitor second end, and a second end adapted to receive a second terminal of said power supply.
6. A circuit as claimed in claim 5 wherein said like conduction electrodes comprise said collector electrodes and said diode first end is coupled to said first transistor emitter.
7. A circuit as claimed in claim 5 wherein said like conduction electrodes comprise said emitter electrodes and said diode first end is coupled to said first transistor collector.
8. A circuit as claimed in claim 5 further comprising a second cut off direction coupled diode having a first end coupled to a conduction electrode of said first transistor, and a second end coupled to the remaining conduction electrode of said first transistor.
As compared with a vertical deflection circuit in which the deflection coil with an additionally arranged capacitor is constituted as a part of a resonance circuit, which circuit performs an unattenuated half oscillation during the flyback period whereby considerable voltage amplitudes at the output of the amplifier circuit occur, the advantage of such a deflection circuit is that the direct voltage to which the deflection coil must be connected is not so high, so that transistors having a slight collector breakdown voltage can be used. In a circuit arrangement of the kind described in the preamble and in U.S. Pat. No. 3,070,727 the flyback voltage depends on the height of the direct voltage, the inductance of the deflection coil and the maximum deflection current in accordance with the relation T = LI/U, in which T denotes the duration of the polarity reversal, I denotes the height of the deflection current (measured from peak to peak), L denotes the inductance of the deflection coil and U denotes the height of the direct voltage.
In a known circuit arrangement of this kind the input of the controllable (transistor) switch is connected to the output of the amplifier through the series arrangement of a capacitor and a resistor. At the commencement of the flyback period the sawtooth voltage changes from its positive to its negative maximum value while a negative pulse becomes available through the RC member at the input of the transistor switch, which pulse causes this transistor to conduct and which connects the deflection coil to a negative direct voltage so that the current flowing through the coil is reversed in polarity. The duration of this polarity reversal depends on the time constant of the RC member before the input of the transistor switch. In case of fluctuations of the direct voltage to which the deflection coil is connected during the flyback period, the amplitude of the current reached by the deflection current during this polarity reversal of course also changes so that the scan period commences either at a too low or at a too high value of the vertical deflection current. Since in addition, as stated, the period of time during which the deflection coil must be connected to the direct voltage depends on the inductance of the deflection coil, the time constant of the RC member must be adapted to the inductance of the deflection coils.
An object of the present invention is to obviate these drawbacks and to provide a circuit arrangement in which the deflection coil is connected to the direct voltage as long as is necessary for reaching the amplitude of the deflection current required for the commencement of the scan period and in which an adaptation is not necessary when the inductance of the deflection circuit changes, for example, by including a transformer for the North-South raster correction.
Starting from a vertical deflection circuit of the kind described in the preamble this object is achieved according to the invention in that the controllable switch is controlled by the difference between a voltage which is proportional to the sawtooth signal and a voltage which is proportional to the deflection current, said two voltages and/or the switch being dimensioned in such a manner that the deflection coil is separated from the direct voltage by means of the switch as soon as the current flowing through the deflection coil has reached the value required for the commencement of the scan period.
The invention is based on the regulation of the fact that the sawtooth signal at the input of the amplifier and the current flowing through the vertical deflection coil have substantially the same variation throughout the scan period; during the flyback period the sawtooth signal is, however, reversed in polarity within a few microseconds, while the polarity reversal for the deflection current is considerably slower due to the limited direct voltage present at the deflection coil. These differences in the variation with time between the input signal and the deflection current may be utilized for the purpose of rendering the switch operative, which switch becomes inoperative again as soon as the deflection current has reached its value required for the commencement of the scan period, because then no difference exists any longer between the sawtooth input signal and the deflection current.
According to a further embodiment of the invention the voltage proportional to the deflection current is applied as a feedback voltage to the input of the amplifier and the controllable switch is connected to a point of the amplifier whose potential exceeds a threshold value only during the flyback period, which threshold value renders the controllable switch operative.
In order that the invention may be readily carried into effect, an embodiment thereof will now be described in detail by way of example with reference to the accompanying diagrammatic drawing. In this embodiment a class B push-pull amplifier is used which, as is known, has a lower dissipation then a class A amplifier for a determined deflection output. The amplifier is substantially symmetrical so that two corresponding parts are denoted by two corresponding reference numerals (for example, 12, 12').
The input signal 1 is applied through a capacitor 2 of 10 μF to the interconnected bases of the input transistors 3 and 3'. The collector of npn-transistor 3 is connected through a resistor 4 of 1.5 kOhms to the positive supply voltage terminal, while its emitter is connected through a resistor 5 of 6.8 kOhms to the negative supply voltage. Transistor 3' is of the pnp type and accordingly it has a polarity which is opposite to that of transistor 3; however, the resistors 4' in the collector lead and 5' in the emitter lead have the same values as resistors 4 and 5. The collector of the transistor 3(3') is connected to the base of a pnp- (npn-) transistor 6 (6') whose emitter is connected through a resistor 7 (7') of 470 Ohms to the positive (negative) supply voltage. The collectors of transistors 6 and 6' are connected together through a diode arranged in the pass direction. The collector voltages of transistors 6 and 6' are applied to the bases of transistors 8 and 8' which are of a conductivity type opposite to that of the transistors driving them. The collectors of transistors 8 and 8' are connected through resistors 9 and 9' to the bases of final transistors 10 and 10' which are again of a conductivity type which is opposite to that of the transistors driving them. The collectors of transistors 10 and 10' are connected together and the junction is connected to ground through the deflection coil 11 and a low-value resistor 12 of 2.2 Ohms. The final transistors are protected by diodes 15 and 15' from the voltage peaks occurring at the deflection coil when the current is reversed in polarity and when flashovers occur in the picture display tube, said diodes being connected in the blocking direction in parallel with the collector-emitter path of the final transistors. In case of a short circuit at the end of the final stage the driver current is limited by the resistors 9, 9'.
In case of a class B push-pull stage the output potential is normally highly dependent on the adjusted quiescent current which in turn is determined by the ambient temperature. In the present circuit arrangement this would give rise to the fact that the vertical position of the picture highly depends on the temperature. To avoid this, the bases of the final transistors 10 and 10' are connected through the series arrangement of diodes 13 and 13' arranged in the pass direction and resistors 14 and 14' to supply voltage terminal for their emitters. A resistor 16 of 47 kOhms arranged between the cathode of the diode 13 connected to the positive potential and the anode of the diode 13' connected to the negative potential ensures that the diodes 13 and 13' are always slightly biassed. As a result the base potential and the quiescent current of the final transistors 10 and 10' is determined by the bias voltage of these diodes when the input signal fails, hence when transistors 8 and 8' are cut off. Since this bias voltage is already very low and is even more reduced by the voltage drops at resistors 14 and 14', quiescent currents of a few μA can be adjusted. The distortions of the output signal to be expected at such a low quiescent current adjustment are eliminated in known manner (Austrian Pat. specification 245038) in that the bases of the final transistors are not connected to the emitters of the driver stages 8 and 8' but to their collectors so that the output resistance of the driver stages 8, 8' driving the final transistors 10, 10' is considerably larger than the input resistance of the final stages. The non-linearity of the input resistance therefore does not exert any influence on the course of the signal.
A voltage is derived from resistor 12 which is applied through resistors 17 and 17' to the emitters of input transistors 3 and 3'. The voltage 18 proportional to the deflection current derived from resistor 12 has the same phase and substantially also the same shape as the input signal 1 and therefore acts as a direct current feedback. The mean value of the deflection current and hence the position of the picture is determined in this circuit arrangement by the potential at the bases of transistors 3 and 3'. To adjust this potential a potentiometer connected to the supply voltage would be sufficient, while its wiper would be connected to the bases of the input transistors, but in this case the position of the picture would be greatly dependent on fluctuations in the supply voltage. Adjustment of the picture position substantially independent of supply voltage fluctuations is obtained when, as shown in the drawing, the base is connected to the wiper on a potentiometer 18' of 5 kOhms whose ends are connected to ground through resistors 19 and 19' of 22 kOhms and further resistors 20 and 20' of 330 Ohms, the junction of resistors 19, 20 and 19', 20' being connected through resistors 21 and 21', respectively, to the positive and negative potential, respectively. The amplifier and particularly the driver stages 8, 8' and the final stages 10, 10' are substantially insensitive to hum voltages so that the positive voltage of 24 volts and the negative voltage of -20 Volts need not be especially smooth. For the preliminary stages this smoothing may be effected in known manner by resistors 22 and 22' of 680 Ohms arranged in the supply lead which resistors together with capacitors 23 and 23' of 500 μF constitute a smoothing member.
It is achieved by the direct current feedback that the deflection current is adjusted such that the voltage fed back on the emitters of the input transistors 3 and 3' corresponds but for a small difference to the voltage at the bases of transistor 3 and 3' (for this reason the deflection current can be varied by varying the value of resistor 12 in case of a given amplitude of the input signal). As a result the deflection current has the same variation with time as the input signal 1 at least during the scan period. At the beginning of the flyback period the input voltage changes within a few microseconds from its positive to its negative maximum value; the deflection current can, however, not be reversed in polarity at the same rate. As a result the base-emitter voltage of the input transistors 3 varies substantially stepwise after the beginning of the flyback period when the input signal has already reached its negative peak value while the deflection current has only very slightly varied. The bases of the input transistors 3, 3' become thus considerably more negative so that the lower transistor 3' and at the same time the transistors 6', 8', 10' conduct heavily while transistors, 3, 6, 8 and 10 are cut off. This voltage variation produces a negative voltage step, for example, at the interconnected emitters of driver transistor 8, 8' which emitters are connected to ground through a resistor 24 of 100 Ohms, said voltage step being applied to the input of a controllable switch 27 through a potential divider consisting of resistors 25 of 1 kOhm and 26 of 22 kOhms and having one end connected to the said emitters and the other end connected to the positive supply voltage, so that said switch then onducts. In the conducting state the switch 27 must conduct current in both directions; when using a transistors switch the collector-emitter path of the switching transistor may be connected for this purpose in parallel with a diode having an opposite pass direction and having such a polarity that it does not conduct during the scan period.
The current flowing through the deflection coil might alternatively be reversed in polarity when the deflection coil would be directly connected via the switch to the negative supply voltage. In case of a negative supply voltage of - 20 Volts, a deflection inductance of 30 mH and a deflection current of 1,2 A (peak-to-peak) a time of 1.8 ms would, however, be required for reversing the polarity of the deflection current; a flyback period of less than one ms is, however, desirable. This shorter flyback period could be obtained by increasing the negative and the positive supply voltage. Then, however, the dissipation of the final stage transistors 10, 10' would also be increased.
In the circuit arrangement shown in the drawing the duration of the flyback period is reduced by means of a clamping circuit without increase of dissipation of the final stage transistors. For this purpose the emitter of transistor 10', unlike the emitter of transistor 10 is not directly connected to the associated voltage supply terminal but through a diode 28 conducting in the pass direction. In addition the emitter of transistor 10' is connected through a large capacitor 29 of 250 μF to the end of the transistor switch not connected to the negative supply voltage, which end is simultaneously connected through a resistor 30 of 220 Ohms to the positive supply voltage terminal. The clamping circuit operates as follows:
During the scan period capacitor 29 is charged through resistor 30 and the diode 28, a voltage of + 24 Volts occurring at the end of capacitor 29 connected to the switch and a voltage of approximately - 20 Volts occurring at the other end, so that a voltage of approximately 44 Volts is present at the capacitor. As soon as the transistor switch 27 conducts as a result of the steep-edged voltage step of the input voltage 1 the electrode of capacitor 29 which was positive (+ 24 Volts) up till that instant is connected to the negative supply voltage; this potential step is transferred to the other electrode of the capacitor which was previously at - 20 Volts and subsequently at approximately - 60 Volts. Diode 28 is blocked at this voltage.
At the beginning of the flyback period a negative voltage peak is produced at the end of the deflection coil 11 connected to the amplifier output, and this as a result of the sudden cut-off of the final stage transistor 10 which was still conducting relatively strongly at the end of the scan period. The negative voltage peak is limited by diode 15' to a voltage which is slightly more negative than - 60 Volts, for example, -60.6 Volts. The deflection current flows via diode 15' in the same direction as it did previously through transistor 10, but due to the negative voltage at the end of the deflection coil connected to the amplifier output it decreases to the value of zero. Subsequently, the current is reversed in polarity and flows through the collector-emitter path of the npn transistor 10' whose base also carries a positive voltage during the first part of the flyback period. The voltage at the deflection coil is then only slightly less negative than the voltage on the left-hand electrode of capacitor 29 due to the small voltage drop on the collector-emitter path of transistor 10', so that the deflection current furthermore decreases at approximately the same rate as during the first half of the flyback period, because substantially the same voltage is present at the deflection coil. Simultaneously also the voltage at resistor 12 decreases and hence the difference between the base-emitter voltages of the input transistors 3 and 3'. Consequently the lower half of the class B push-pull amplifier becomes less conducting so that the emitter potential of transistors 8 and 8' becomes again less negative. In case of suitable dimensioning of the potential divider 25, 26 and of the threshold at which the transistor switch 27 is opened again it can be achieved that opening is effected just at the instant when the deflection current has reached its required value. The capacitor 29 is still further charged during the first part of the flyback period and the more the lower its capacitance is, and during the second part of the flyback period it is discharged to the voltage present at the commencement of the flyback period. The mean value of the potential on the left-hand electrode of this capacitor is thus still more negative than - 60 Volts during the flyback period and the more as the capacitance of the capacitor is lower so that the deflection current is reversed in polarity at an even faster rate. However, restrictions are imposed in this case due to the dielectric strength of the final stage transistors; consequently, when the dielectric strength of transistors 10, 10' is only slightly more than 60 Volts, a capacitor having a high capacitance (250 μF) is to be used, as in the embodiment.
This circuit arrangement is insensitive to fluctuations during operation. When, for example, the negative and/or the positive supply voltage increases, the flyback duration decreases; accordingly the emitter potential of the driver transistors 8 and 8' reaches the positive threshold value more quickly so that the switch is opened again and the polarity reversal is interrupted as soon as the deflection current has reached its required value.
MEDIATOR (PHILIPS) 66K365/16Z (PHILIPS KM2) CHASSIS KM2 NORD SOUTH (NORD/SUD) CORRECTION CIRCUIT ARRANGEMENT FOR CORRECTING THE DEFLECTION OF AT LEAST ONE ELECTRON BEAM IN A TELEVISION PICTURE TUBE BY MEANS OF A TRANSDUCTOR :
A circuit arrangement for raster correction in a television picture tube by means of a transductor whose power winding is connected in parallel with at least a portion of the line deflection coils, the line deflection generator having a low internal impedance. In order to increase this impedance a mainly inductive impedance is connected in series with the generator. In a picture tube employing at least two electron beams the series impedance may include the convergence circuit. As a result the convergence in the corners of the picture screen is also improved. The linearity control circuit may likewise form part of the series impedance.
1. A deflection circuit for a cathode ray tube comprising a transistor horizontal deflection generator; a horizontal deflection coil parallel coupled to said generator; means for pincushion correction of said tube comprising a saturable reactor having a control winding adapted to receive a vertical deflection signal and a power winding parallel coupled to at least a portion of said deflection coil; and means for increasing the effectiveness of said correction means comprising an impedance element external to said generator having a substantially inductive reactance series coupled between said generator and said coil. 2. A circuit as claimed in claim 1 wherein said generator comprises a transformer having a tap and said power winding has a first end coupled to said coil and a second end coupled to said tap. 3. A circuit as claimed in claim 1 wherein said impedance element comprises means for controlling the linearity of the beam deflection. 4. A deflection circuit for a cathode ray tube having at least two electron beams comprising a transistor horizontal deflection generator; a horizontal deflection coil parallel coupled to said generator; means for pincushion correction of said tube comprising a saturable reactor having a control winding adapted to receive a vertical deflection signal and a power winding parallel coupled to at least a portion of said deflection coil; means for increasing the effectiveness of said correction means comprising an Impedance element external to said generator having a substantially inductive reactance series coupled between said generator and said coil; and means for dynamically converging said beams comprising a convergence circuit coupled to said horizontal generator and to said transductor. 5. A circuit as claimed in claim 4 wherein said generator comprises a transformer having a tap and said power winding has a first end coupled to said coil and a second end coupled to said tap. 6. A circuit as claimed in claim 4 wherein said impedance element comprises means for controlling the linearity of the beam deflection.
A circuit arrangement for raster correction with the aid of a transductor is described, for example, in U.S. Pat. No. 3,444,422. In this patent the power winding of a transductor is connected in parallel with the horizontal deflection coils while the control winding receives a signal of field frequency so that the current of line frequency which flows through the deflection coils is modulated at the field
Due to the step according to the invention the internal impedance of the deflection generator is increased and the different components of the circuit remain mainly inductive so that the deflection current is more or less linear when the voltage provided by the deflection generator during the line scan period is substantially constant. The series impedance may be, for example, a fixed coil. However, the invention is furthermore based on the recognition of the fact that the increase in the internal resistance of the horizontal deflection generator may not only be obtained by a constant impedance, but other arrangements envisaging other improvements of the deflection may be used for this purpose. In that case even special improvements may be obtained as will be apparent hereinafter and possible small non-linearities of the additionally used arrangements have no detrimental results.
It is true that in known convergence circuits in picture tubes employing a plurality of electron beams a satisfactory improvement is obtained for the central horizontal and vertical lines of a picture tube of the shadow mask type. However, it is found that convergence errors may subsist in the corners of the picture. Known circuit arrangements which correct these second-order errors are often complicated and expensive. In the circuit arrangement according to the invention a satisfactory compensation of such convergence errors is possible in a simple manner if the series impedance which is arranged between the horizontal deflection generator and the deflection coils includes the convergence circuit. In this manner the sum of the deflection current and of the current derived for the field correction and modulated by the transductor flows through the convergence circuit so that the desired additional convergence correction in the corners of the written raster is obtained.
In order that the invention may be readily carried into effect a few embodiments thereof will now be described in detail by way of example with reference to the accompanying diagrammatic drawings in which:
FIG. 1 shows a circuit arrangement in which the transductor is connected in parallel with the deflection coils, while in
FIG. 2 the transductor is only fed by part of the voltage applied to the deflection coils.
FIG. 1 shows two line-output transistors 1 and 2 which are arranged in series. The emitter of transistor 2 is connected to ground through a winding 3 while the collector of transistor 1 is connected through a winding 4 and a small series impedance 5, preferably a resistor, to the positive terminal of a supply source V b whose negative terminal is connected to ground.
Windings 3 and 4 are wound together with an EHT-winding 6 on the same transformer core 7. The ends of windings 3 and 4 remote from each other are connected through the capacitor 10 for the S-correction to the deflection-unit consisting of two windings 8 and 9 arranged, for example, in parallel. The base of transistors 1 and 2 receive pulses of line frequency in a manner not shown in FIG. 1 so that these transistors are cut off during the flyback period. During the scan period, a substantially constant voltage is applied to the deflection unit. Consequently a more or less sawtooth-shaped current flows through windings 8 and 9. The bipartite power winding 11 of a transductor ensuring the raster correction is connected in parallel with this deflection unit 8, 9. The control winding 12 of said transductor, and a converting capacitor 13 in parallel therewith form part of the circuit for the vertical deflection through terminals 14 and 15. An adjustable coil 16 with which the raster correction can be adjusted exactly is connected in series with winding 12.
Windings 3 and 4 have the same number of turns so that pulses of the same amplitude and reversed polarity are produced at the emitter of transistor 2 and at the collector of transistor 1. As a result a disturbing radiation of these pulses is reduced. Furthermore, transistor types are chosen in this Example for transistors 1 and 2 whose collector-base diodes may function as efficiency diodes. All this has been described in U.S. Pat. No. 3,504,224.
According to the invention the convergence circuit 17 is arranged through a separation transformer 20 between the end of winding 3 remote from winding 4 and the horizontal deflection coils 8, 9. Furthermore, this current branch includes the linearity control circuit 21 which comprises the parallel arrangement of a resistor and a coil whose inductance is adjustable, for example, by means of premagnetization of the core of the coil. A current, which is the sum of the current for the deflection coils 8, 9 and of the current for the power winding 11 of the transductor, flows through the primary winding of transformer 20. This primary current is transformed to the secondary circuit of transformer 20 so that a current flows through convergence circuit 17.
In known arrangements the convergence current is only influenced by the deflection current itself. It has been found that in this case the convergence correction is not sufficient in the corners of the picture. At these areas, where the deflection in both directions is at a maximum, a greater intensity of the convergence current is required. This is especially the case in picture tubes having a great deflection angle and according to the invention this is achieved in that the current which is derived from the power winding 11 of the transductor for the raster correction is also applied to the convergence circuit. This current flows from the horizontal deflection generator constituted by windings 3 and 4 through the primary winding of transformer 20 to power winding 11 of the transductor. The transductor current is in fact at a minimum in the center of the picture and increases towards the edges and particularly towards the corners. Thus the convergence current varies in the desired manner. According to the invention the desired improvements of the convergence correction and simultaneously the likewise desired increase in the internal resistance of the horizontal deflection generator is consequently obtained without a considerable increase in the number of required circuit elements and without disturbing the normal operation of the circuit arrangement. Due to transformer 20 a terminal of convergence circuit 17 may be connected to ground so that the convergence can be adjusted safely. If necessary, a suitable impedance transformation may also be obtained with the aid of transformer 20.
The linearity control circuit 21 may alternatively be connected in series with the said branch which includes transformer 20. As a result the internal resistance of the horizontal deflection generator for the line frequency is further increased without the field correction and the convergence correction being disturbingly influenced.
FIG. 2 shows a modification of the circuit arrangement according to the invention in which the deflection current is not changed relative to that of FIG. 1. The end of power winding 11 of the transductor shown on the upper side of FIG. 1 is connected to ground in FIG. 2. In addition convergence circuit 17 is included between winding 3 and ground so that separation transformer 20 may be omitted. If as a first approximation the impedances 5 and 17 are assumed to be negligibly small relative to the other impedance of the circuit arrangement, power winding 11 may be considered to be connected to a tap on the deflection generator 3, 4. Consequently, only approximately half the voltage of the deflection generator is applied to transductor winding 11 which winding must therefore be proportioned in such a manner that it can convey a current which is approximately twice as large as that of FIG. 1. This larger current also flows through convergence circuit 17 which, with the omission of separation transformer 20, is favorable for the convergence in the corners of the picture screen.
In FIG. 2 the emitter of transistor 2 is connected to ground i.e., the said tap on the deflection generator. During the scan period the series arrangement of supply source V b and windings 3 and 4 FIG. 1 is substantially short-circuited by transistors 1 and 2. In order that these transistors in the circuit arrangement according to FIG. 2 operate under the same circumstances as those in FIG. 1, an additional winding 24 must be wound on core 7 between windings 4 and 6, winding 24 having the same number of turns as winding 3, and the collector of transistor 1 must be connected to the junction of windings 6 and 24.
The end of power winding 11 connected to ground in FIG. 2 may alternatively be connected for the desired adjustment of the corner convergence to a different tap on the transformer, that is to say, on winding 3 or 4.
Resistor 5 serves in known manner mainly as a safety resistor so that in case of an inadmissible load of the EHT, for example, as a result of flash-over in the picture tube, the supply voltage for transistors 1 and 2 is reduced so that overload of these transistors is avoided.
MEDIATOR (PHILIPS) 66K365/16Z (PHILIPS KM2) CHASSIS KM2 E/W CORRECTION Circuit arrangement in an image display apparatus for (horizontal) line deflection
Line deflection circuit in which the deflection coil is east-west modulated. In order to cancel an east-west dependent horizontal linearity defect the inductance value of the linearity correction coil is made independent of the field frequency, for example by means of a compensating current. In an embodiment this current is supplied by the shunt coil of the east-west modulator.
1. Circuit arrang
ement for use with a line deflection coil, said circuit comprising a generator means adapted to be coupled to said coil for producing a sawtooth line-deflection current through said line deflection coil, said deflection current having a field-frequency component current, a horizontal linearity correction coil adapted to be coupled in series with said deflection coil and including an inductor having a bias-magnetized core, and means for making the inductance value of the linearity correction coil substantially independent of the field frequency component current. 2. Circuit arrangement as claimed in claim 1, wherein said making means includes a current supply source means for producing a compensating line-frequency sawtooth current through a winding of the linearity correction coil, the amplitude of the compensating current having a field-frequency variation. 3. Circuit arrangement as claimed in claim 2, wherein the direction of curvature of the field-frequency envelope of the compensating current is opposite to the direction of curvature of the field-frequency component current of the line deflection current, whereby the magnetic fields produced in the core of the correction coil by the two currents have the same direction. 4. Circuit arrangement as claimed in claim 2, wherein the direction of curvature of the field-frequency envelope of the compensating current is the same as the direction of curvature of the field-frequency component current of the line deflection current, whereby the magnetic fields produced in the core of the correction coil by the two currents have opposite directions. 5. Circuit arrangement as claimed in claim 2, wherein said correction coil further comprises an additional winding disposed on the core, said additional winding being coupled to said supply source means to receive the compensating current. 6. Circuit arrangement as claimed in claim 5, further comprising modulator means for modulating the line deflection current with said field frequency component, said modulator including a compensation coil coupled in series with said additional winding. 7. Horizontal linearity correction coil comprising a core made of a magnetic material and bias-magnetized by at least one permanent magnet, and an additional winding disposed on the core. 8. Image display apparatus including a circuit arrangement as claimed in claim 1.
By means of the linearity correction coil the linearity error due to the ohmic resistance of the deflection circuit is corrected. The sign of the bias magnetisation is chosen so that it is cancelled by the deflection current at the beginning of the deflection interval, so that the inductance of the correction coil is a maximum, whereas the voltage drop across the deflection coil then is a minimum. This voltage drop is adjustable by adjustment of the starting inductance of the correction coil. During the deflection interval the core gradually becomes saturated so that the inductance of, and the voltage drop across, the correction coil decrease. Thus the linearity error can be cancelled exactly at the beginning of the interval, that is to say on the left on the screen of the image display tube, and with a certain approximation at other locations.
In image display tubes using a large deflection angle, raster distortion, which generally is pincushion-shaped, of the image displayed occurs. This distortion can be removed in the horizontal direction, the so-called east-west direction, by means of field-frequency modulation of the line deflection current, the envelope in the case of pincushion-shaped distortion being substantially parabolic so that the amplitude of the line deflection current is a maximum at the middle of the field deflection interval.
It was found in practice that the said two corrections are not independent of one another, that is to say the adjustment of the east-west modulation affects horizontal linearity. As long as the modulation depth is not excessive, a satisfactory compromise can be found. However, in display tubes having a deflection angle of 110° and particularly in colour display tubes in which the deflection coils have a converging effect also, it is difficult to find such a compromise. A tube of this type is described in "Philips Research Reports," volume Feb. 14, 1959, pages 65 to 97; the distribution of the deflection field is such that throughout the display screen the landing points of the electron beams coincide without the need for a converging device. Owing to this field distribution, however, the pin-cushion-shaped distortion in the image displayed in the east-west direction is greater than in comparable display tubes of another type. Hence there must be east-west modulation of the line deflection current to a greater depth. It is true that under these conditions horizontal linearity can correctly be adjusted over a given horizontal strip after the east-west modulation has been adjusted correctly, i.e., for a rectangular image, but it is found that in other parts of the display screen a serious linearity error remains. When vertical straight lines are displayed as straight lines in the right-hand part of the screen, they are displayed as curved lines in the left-hand part.
It is an object of the present invention to remove the said defect so that horizontal linearity can satisfactorily be adjusted throughout the screen, and for this purpose the circuit arrangement according to the invention is characterized in that it includes means by which the inductance of the linearity correction coil is made substantially independent of the field frequency.
The invention is based on the recognition that the defect to be removed is due to a field-frequency variation of the said inductance because the latter is current-dependent. According to a further recognition of the invention the circuit arrangement is characterized in that it includes a current supply source for producing a compensating line-frequency sawtooth current through a winding of the linearity correction coil, the amplitude of the current being field-frequency modulated. The circuit arrangement according to the invention may further be characterized in that an additional winding is provided on the core of the linearity correction coil and is traversed by the compensating current. A circuit arrangement in which the modulator for modulating the line deflection current includes a compensation or bridge coil may according to the invention be characterized in that the additional winding is connected in series with the said coil.
The invention also relates to a linearity correction coil for use in a line deflection circuit having a core which is made of a magnetic material and is bias magnetized by at least one permanent magnet, which coil is characterized in that an additional winding is provided on the core.
Embodiments of the invention will now be described by way of example, with reference to the accompanying diagrammatic drawings, in which
FIG. 1 is the circuit diagram of a known circuit arrangement for line deflection in which the line deflection current is east-west modulated,
FIG. 2 shows the distorted image which is displayed on the screen when the circuit arrangement of FIG. 1,
FIG. 3 is a graph explaining the observed defect, and
FIGS. 4 and 7 show embodiments of the circuit arrangement according to the invention by which this defect can be cancelled.
FIG. 1 is a greatl simplified circuit diagram of a line deflection circuit of an image display apparatus, not shown further. The circuit includes the series combination of a line deflection coil L y , a linearity correction coil L and a trace capacitor C t , which series combination is traversed by the line deflection current i y . The collector of an npn switching transistor T r and one end of a choke coil L 1 are connected to a junction point A of a diode D, a capacitor C r and the said series combination. The other end of the choke coil is connected to the positive terminal of a supply voltage source which supplies a substantially constant direct voltage V b and to the negative terminal of which the emitter of transistor Tr is connected. This negative terminal may be connected to earth. The other junction point B of elements D and C r and of the series combination of elements C t , L y and L is connected to one terminal of a modulation source M for east-west correction which has its other terminal connected to earth. Diode D has the pass direction shown in the FIG.
To the base of transistor Tr line-frequency switching pulses are supplied. In known manner the said series combination is connected to the supply voltage source during the deflection interval (the trace time), diode D and transistor Tr conducting alternately. During the retrace time these elements are both cut off. Under these conditions the current i y is a sawtooth current. The coil L, which has a saturable ferrite core which is bias-magnetized by means of at least one permanent magnet, serves to correct the linearity of the current i y during the trace time, whilst the capacitance of the capacitor C t is chosen so that the currenct i y is subjected to what is generally referred to as S correction. During the retrace time, at point A pulses are produced the amplitude of which is much higher than that of the voltage V b and would be constant in the absence of modulation source M. Information from the field deflection circuit, not shown, of the image display apparatus and line retrace pulses, the latter for example by means of a transformer, are supplied in known manner to modulation source M. Amplitude-modulated line retrace pulses having a field-frequency parabolic envelope, as indicated in the FIG., are produced at point B. During the line trace time the voltage at point B is zero. Thus the current i y is given the desired field-frequency modulated form which is also shown in FIG. 1.
The amplitude of the envelope in point B at the beginning and at the end of the field trace time and the amplitude of this envelope at the middle of the said time can both be adjusted so that the image displayed on the display screen of the display tube (not shown) has the correct substantially rectangular form. If, however, the required modulation depth is comparatively large, a linearity error of the line deflection is produced which cannot be removed by means of the correction coil L.
FIG. 2 shows the image of a pattern of vertical straight lines as it is displayed on the screen with the correction coil L adjusted so that horizontal linearity is satisfactory along and near the central horizontal line. In FIG. 2 the defect is exaggerated. It is found that horizontal linearity is defective in other areas of the screen so that the vertical lines are displayed correctly in the right-hand half of the screen but as curves in the left-hand path, the defect increasing as the line is farther to the left.
This phenomenon can be explained with reference to FIG. 3. In this FIG. the inductance L of the linearity correction coil is plotted as a function of the magnetic field strength H. In the absence of current, H has a value H 0 owing to the bias magnetization. If an approximately linear sawtooth current i (t) as shown in the bottom left-hand part of FIG. 3 flows through the coil, the field strength H varies proportionally about the value H 0 , for the mean value of the current is zero. Because the curve of L is not linear, the variation L(t) of L, which is shown in the top right-hand part, is not a linear function of time. The resulting curve may be regarded as composed of a linear component and a substantially parabolic component which is to be taken into account when choosing the capacitance of capacitor C t .
Because owing to the east-west modulation the amplitude of current i(t) varies, the amplitude of L(t) also varies. This implies a field-frequency variation of L which is non-linear. This variation is undesirable. In the case of a small variation of the amplitude of current i(t) the variation of L(t) can be more or less neglected, but this is no longer possible when the amplitude of current i(t) varies greatly owing to the east-west modulation. L(t) varies according to different curves. FIG. 3 shows two of such curves and also illustrates the fact that the undesirable variation of L(t) is greatest at the beginning of the trace time and smallest at the end thereof.
FIG. 4 shows a circuit arrangement in which the defect described can be corrected. On the core of the correction coil L of the circuit of FIG. 1 an additional winding L 2 is provided. Winding L 2 is connected to a current source which produces a compensating current i 2 which has a line-frequency sawtooth variation and a field-frequency amplitude modulation. The envelope here also is parabolic, however, with a shape opposite to that of deflection current i y , that is to say having a minimum at the middle of the field trace time. The direction of current i 2 and the winding sense of winding L 2 relative to that of coil L are chosen so that the magnetic field produced in the core by winding L 2 has the same direction as the field produced by coil L. Hence the two field strengths are added. The amplitude of current i 2 and the turns number of winding L 2 can be chosen so that current i y flows through inductances the total value of which is not dependent upon the field frequency. The curve L(t) of FIG. 3 remains substantially unchanged. Consequently the undesirable field-frequency modulation is removed without variation of the bias magnetization, which would have been varied if current i 2 were a field-frequency current. Obviously the same result can be achieved by a choice such of the direction of current i 2 and of the winding sense of winding L 2 that the two field strengths are subtracted one from the other, whilst the curvature of the envelope of current i 2 has the same direction as that of the envelope of current i y .
The current source of FIG. 4 may be formed in known manner by means of a modulator in which a line-frequency sawtooth signal is field-frequency modulated, the envelope being parabolic. FIG. 5 shows a circuit arrangement in which current i 2 is produced by the modulation source which provides the east-west correction. In FIG. 5, the source M of FIG. 1 comprises a diode D', a coil L' and two capacitors C' r and C' t , which elements constitute a network of the same structure as the network formed by elements D, L y , C r and C t . The capacitor C' t is shunted by a modulation source V m which supplies a field-frequency parabolic voltage having a minimum at the middle of the field trace time.
With the exception of the linearity correction means to be described hereinafter, the circuit arrangement of FIG. 5 was described in more detail in U.S. Pat. No. 3,906,305. Hence it will be sufficient to mention that the capacitances of capacitors C r and C' r and of a capacitor C 1 connected between junction point A and earth and the inductance of coil L' are chosen so that the three sawtooth currents flowing through L y , L' and L 1 have the same retrace time. The capacitances of capacitors C t and C' t , which are large, are ignored. When voltage V b is constant, current i y is subjected to the desired east-west modulation having the form shown in FIG. 1.
Coil L y is connected in series with correction coil L, and winding L 2 is connected in series with coil L'. FIG. 5 shows that the current flowing through winding L 2 has the same waveform as the current i 2 of FIG. 4, for its envelope has the same shape as the voltage supplied by source V m . By a suitable choice of the number of turns of winding L 2 it can be ensured that the linearity correction remains the same for every line during the field trace time.
Modified embodiments of the circuit arrangement of FIG. 5 can also be used. FIG. 6 shows such a modified embodiment in which the capacitive voltage divider C r , C' r of FIG. 5 is replaced by an inductive voltage divider by means of a tapping on coil L 1 . A capacitor C 2 is included between the tapping and the junction point of diodes D and D', whilst capacitor C' t here forms part of two networks C t , L y and C' t , L' traversed by a sawtooth current. In FIG. 6 modulation source V m is connected via a choke coil L 3 to the junction point of D, D', C 2 and C' t . One end of winding L 2 is connected to the junction point of capacitor C' t and the coil L, whilst the other end is connected to earth via coil L'. The capacitances of capacitors C 1 and C 2 and the location of the tapping on coil L 1 are chosen so that the sawtooth currents flowing through L y , and L' and L 1 have the same retrace time, whilst the field-frequency linearity defect of FIg. 2 is cancelled by correctly proportioning winding L 2 .
Other east-west modulators are known in which the step of FIGS. 5 and 6 can be used. An example is the modulator described in the publication by Philips, Electronic Components and Materials: "110° Colour television receiver with A66-140X standard-neck picture tube and DT 1062 multisection saddle yoke," May 1971, pages 19 and 20, which modulator also comprises two diodes and a compensation coil L', which are arranged in a slightly different manner. In another example the east-west modulator and the line deflection generator are included in a bridge circuit whilst they are decoupled from one another by means of a bridge coil which has the same function as coil L' in FIGS. 5 and 6. In these circuit arrangements coil L and winding L 2 may be arranged in the same manner as in FIG. 6. The same applies to an east-west modulator using a transductor the operating winding of which is in series with the deflection coil.
In the abovedescribed embodiments of the circuit arrangement according to the invention the compensating current i 1 is provided by transformer action. In the embodiment of FIG. 7 the current source which supplies the current i 2 is connected in parallel with correction coil L, i.e., without an auxiliary winding. In this embodiment the east-west modulation is achieved not by means of a modulator, but by means of the fact that the supply voltage V b is the super-position of a field-frequency parabolic voltage on the direct voltage. In this known manner the supply source also is the modulator.
It will be seen that in the embodiments of FIGS. 4, 5 and 6 current i 2 counteracts the east-west modulation of deflection current i y . It was found in practice, however, that this counteraction is slight.
MEDIATOR (PHILIPS) 66K365/16Z MULTISTANDARD CHASSIS PHILIPS KM2 DUAL SYNCH FREQUENCY. 625 LINES / 819 LINE PAL/SECAM:
1. A power supply and deflection circuit for use in a video display system comprising:
means for selecting one of a plurality of horizontal deflection rates;
horizontal deflection means coupled to said selecting means for operating at said selected horizontal deflection rate, incorporating means for producing horizontal retrace pulses having amplitudes dependent upon said selected horizontal deflection rate;
a voltage source providing a plurality of predetermined different voltage levels;
means for selecting one of said voltage levels in response to said selected horizontal deflection rate;
transformer means comprising:
a transformer winding comprising a plurality of winding turns having a first terminal coupled to said means for producing horizontal retrace pulses, and having a plurality of taps, each of said taps forming, with said first terminal, a transformer primary winding having a different number of winding turns dependent on the tap selected; and
a transformer secondary winding magnetically coupled to said primary winding for producing a secondary winding voltage in response to said retrace pulses on said primary winding; and
means for applying said selected voltage level to one of said taps in response to said selected horizontal deflection rate, said tap selected such that said secondary winding voltage remains substantially constant during retrace in response to retrace pulses of different amplitudes.
2. The arrangement defined in claim 1, wherein the number of winding turns of said primary winding is increased as said horizontal deflection rate is decreased. 3. The arrangement defined in claim 1, wherein said secondary winding produces a high voltage level in response to said retrace pulses on said primary winding.
One problem which arises as a result of an attempt to use common circuit components is associated with the horizontal deflection circuit. If the same flyback transformer, yoke inductance, and horizontal retrace capacitor are utilized, the horizontal retrace or flyback pulse will be substantially the same in width for each scanning rate. A constant width retrace pulse will, however, cause the trace/retrace ratio to change for different horizontal scanning frequencies or rates, with the ratio increasing for decreasing scan rates. The trace/retrace ratio will increase, however, by a factor greater than the ratio of the scanning rates, so that the retrace pulse amplitude tends to be greater at the lower scanning frequency. Since the retrace pulse amplitude determines the high voltage level via the high voltage transformer, the high voltage level will increase as the horizontal scanning frequency or rate decreases.
In accordance with an aspect of the present invention, a power supply and deflection circuit for use in a video display system comprises horizontal deflection means adapted for operating at a plurality of selectable horizontal deflection or scanning rates. The deflection means incorporates circuitry which produces horizontal retrace pulses that have amplitudes that depend on the selected horizontal scanning rate. A voltage source produces different voltage levels and means select one of those voltage levels in response to the selected scanning rate. A transformer has a primary winding with a number of winding turns and a first terminal that is connected to the retrace pulse producing circuit. The transformer winding also has a number of taps which each form a primary winding with the first terminal and have different numbers of winding turns. A transformer secondary winding is magnetically coupled to the primary winding and produces a high voltage level in response to the amplitude of the horizontal retrace pulses on the primary winding. Means couple the voltage source to one of the taps in response to the selected scanning rate so that the high voltage level remains substantially constant independent of changes in retrace pulse amplitude.
MEDIATOR (PHILIPS) 66K365/16Z MULTISTANDARD CHASSIS PHILIPS KM2 BISTABLE LATCHING RELAY FOR CHANNEL SELECTION SYSTEM:
A bistable latching relay comprising a pair of reversible permanent magnet cores extending through and attached to a soft magnetic baseplate by means of glass-to-metal seals. A soft magnetic reed contact is attached to one end of each core so that the reed contacts overlap and provide an electrical contact gap for the relay. The relay is hermetically sealed within a cover to provide a dust-free enclosure for the contacts. The magnetism of each core is transmitted to the soft magnetic reed contacts attached to the ends of the cores to provide magnetic latching. Electromagnetic coils surrounding each core determine the magnetic sense of the core when energized and, depending upon the direction of the current through the coil, cause the reed contacts to open or to close. The current pulse in one direction, for example, momentarily causes the contacts to close, wherein the bistable latching property is accomplished by the transmission of the remanent magnetism of the coil to the reed contacts.
BACKGROUND OF THE INVENTION
The present invention relates to a bistable magnetic latching relay with hermetically sealed or protected reed contacts and permanent magnets capable of being subjected to polarity reversals by at least one coil respectively, operating on the series-ferreed principle.
The ferreed principle is described in German Pat. No. 1,154,870 and in two articles published in "The Bell System Technical Journal," of Jan. 1960 and Jan. 1964, respectively. The name "ferreed" is composed of the abbreviations for the words ferrite and reed contact, which basically consists of a suitable combination of reversible permanent magnets with reed contacts. Conventional types of ferreeds are all provided with reeds hermetically sealed into small glass tubes (envelopes).
Moreover, self-latching reed contacts contain reeds which are made from a reversible hard-magnetic material. In one conventional type of magnetic latching relay the had-magnetic reeds are given the necessary spring properties by way of flat stamping. Magnetically hard materials, however, are mostly also mechanically hard; and flat stamping of this material is very difficult because of the high tool requirements. In another conventional hard-magnetic reed, each of the contacts contain short flat springs which are secured to a rod-shaped part sealed into the (protective) contact tube by way of spot welding. This type of construction, however, is complicated and expensive, because four welding points have to be arranged inside the protective contact tube which are not very structurally reliable.
SUMMARY OF THE INVENTION
This invention, therefore, comprises reversible remanent-magnetic cores secured in pairs by means of glass-to-metal sealing in a baseplate. The cores transmit their magnetic flux through the baseplate, to soft-magnetic armature contacts cooperating in pairs. Electromagnetic coils supply magnetic energy to these cores to open and close the soft armature contacts. The relays are bistable since the permanent magnetic flux through the cores transmits to the contacts and allows them to remain magnetically coupled when the energizing magnetic field is turned off. Reversing the polarity of the energizing fields causes the contacts to open.
German Printed Application (DAS) 1,194,980 discloses an electromagnetic relay for polarized operation in which a permanent magnet is secured in a baseplate by means of glass-to-metal sealing. This permanent magnet, however, is not reversible and the aforementioned relay therefore does not operate on the ferreed principle.
With the bistable latching relay of the instant invention it is possible to avoid the disadvantages of latching crosspoint elements employing self-latching reed contacts. Production thereof becomes simple because the relatively hard reversible permanent magnetic parts of the magnet circuit do not need to be stamped. The use of glass-to-metal sealing makes it possible to attach electromagnetic coils with a small number of turns.
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