a first lensing structure in the forward portion of the focusing electrode, such structure having three in-line tapered apertures of substantially truncated volumetric configuration having substantially parallel axes of symmetry, each aperture having front beam exits and smaller dimensioned rear beam entrances, the front exits and rear entrances being generally circular and separated by sloping sidewalls, a portion of the sidewall of each aperture intersecting with a portion of the sidewall of an adjacent aperture to form an inwardly sloping arcuate rounded saddle along the region of intersection, such structure resulting from the partial overlapping of geometric constructions of the volumetric configurations; and
a second lensing structure in the rear portion of the final accelerating electrode in adjacent, facing relationship with the first structure, such second structure having three in-line tapered apertures of substantially truncated volumetric configuration having substantially parallel axes of symmetry, each aperture having rear beam entrances and smaller dimensioned front beam exits, the front exits and rear entrances being generally circular and separated by sloping sidwalls, a portion of the sidewall of each aperture intersecting with a portion of the sidewall of an adjacent aperture to form an inwardly sloping arcuate rounded saddle along the region of intersection, such structure resulting from the partial overlapping of geometric constructions of the volumetric configurations,
at least one of said entrances and exits in said first and second lensing structures being elongated to provide electron beam spot-shaping, elongation in the first structure being normal to the in-line plane and elongation in the second structure being in the direction of the in-line plane.
2. The electron gun structure of claim 1 wherein the rear opening of the central aperture of the first lensing structure is elongated in a direction normal to the in-line plane. 3. The electron gun structure of claim 2 wherein the opening is elongated by an amount of from about 10 to 35 percent of the diameter of the opening in the in-line plane. 4. The electron gun structure of claim 1 wherein the front opening of the central aperture of the second lensing structure is elongated in the direction of the in-line plane. 5. The electron gun structure of claim 4 wherein the opening is elongated by an amount of from about 15 to 40 percent of the diameter of the opening normal to the in-line plane. 6. The electron gun structure of claim 1 wherein the front opening of the central aperture of the first lensing structure is elongated in a direction normal to the in-line plane. 7. The electron gun structure of claim 6 wherein the opening is elongated by an amount of from about 3 to 15 percent of the diameter of the opening in the in-line plane. 8. The electron gun structure of claim 1 wherein the rear opening of the central aperture of the second lensing structure is elongated in the direction of the in-line plane. 9. The electron gun structure of claim 8 wherein the opening is elongated by an amount of from about 5 to 20 percent of the diameter of the opening normal to the in-line plane.CROSS REFERENCE TO RELATED APPLICATIONS
U.S. patent application Ser. No. 463,791, filed Feb. 4, 1983, describes and claims color cathode ray tube electrodes having tapered apertures. Such application is a continuation-in-part of Ser. No. 450,574, filed Dec. 16, 1982, now abandoned.
U.S. patent application Ser. No. 484,780, filed Apr. 14, 1983, describes and claims color cathode ray tube electrodes having tapered apertures and beam spot shaping inserts.
The above applications are assigned to the assignee of the present invention.
BACKGROUND OF THE INVENTION
This invention relates to an in-line electron gun structure for color cathode ray tubes (CCRT), in which the apertures of the final focusing and accelerating electrodes are tapered, and more particularly relates to such structures in which one or more apertures are elongated for electron beam spot-shaping.
Reducing the diameter of the necks of CCRTs can lead to cost savings for the television set maker and user in enabling smaller beam deflection yokes and consequent smaller power requirements. However, reducing neck diameter while maintaining or even increasing beam deflection angle and display screen area severely taxes the performance limits of the electron gun.
In the conventional, in-line electron gun design, an electron optical system is formed by applying critically determined voltages to each of a series of spatially positioned apertured electrodes. Each electrode has at least one planar apertured surface oriented normal to the tube's long or Z axis, and containing three side-by-side or "in-line" circular straight-through apertures. The apertures of adjacent electrodes are aligned to allow passage of the three (red, blue, and green) electron beams through the gun.
As the gun is made smaller to fit in the so-called "mini-neck" tube, the apertures are also made smaller and the focusing or lensing aberrations of the apertures are increased, thus degrading the quality of the resultant picture on the display screen.
Various design approaches have been taken to attempt to increase the effective apertures of the gun electrodes. For example, U.S. Pat. No. 4,275,332, and U.S. patent application Ser. No. 303,751, filed Sept. 21, 1981 and assigned to the present assignee, describe overlapping lens structures. U.S. patent application Ser. No. 463,791, filed Feb. 4, 1983 and assigned to the present assignee, describes a "conical field focus" or CFF lens arrangement. Each of these designs is intended to increase effective apertures in the main lensing electrodes and thus to maintain or even improve gun performance in the new "mini-neck" tubes.
In the CFF arrangement, the electrode apertures have the shapes of truncated cones or hemispheres, and thus each aperture has a small opening and a related larger opening. In a preferred embodiment, the apertures are positioned so that the larger openings overlap. This overlapping eliminates portions of the sidewalls between adjacent apertures, leaving an arcuate "saddle" between these apertures.
Regardless of their complex shapes, CFF electrodes may be produced by deep drawing techniques, offering a marked cost advantage over other complex designs. However, in forming the CFF electrodes by drawing for mass production quantities, it has been discovered that the edge of the saddle between adjacent apertures becomes rounded, resulting in a slight decrease in the wall area between the apertures. Unfortunately, such a slight modification to the electrode is sufficient to distort the lensing field, and result in an out-of-round spot for the central electron beam on the display screen.
It is an object of the present invention to provide a modified electron gun structure with overlapping tapered apertures, which modified structure will compensate for the distortion in the lensing field caused by rounded saddles.
SUMMARY OF THE INVENTION
In accordance with the invention, a lensing arrangement, featuring partially overlapping tapered apertures with generally circular openings in the final focusing and accelerating electrodes of an in-line electron gun for a CCRT, is modified by elongating at least one of the openings to provide electron beam spot-shaping, and to compensate for the distortion in the lensing field caused by rounded saddles between adjacent apertures.
Such arrangement involves the final low voltage (focusing) and high voltage (accelerating) lensing electrodes. The forward portion of the focusing electrode and the rear portion of the accelerating electrode are in adjacent, facing relationship, and each defines three partially overlapping, tapered, in-line apertures, a central aperture and two side apertures. The apertures are of a three-dimensional surface of revolution (hereinafter called a volumetric configuration), which is substantially truncated, for example, a truncated cone or hemisphere, the axes of symmetry of which are parallel to one another and to the associated path of the electron beam. Each aperture has a large opening in an outer aperture plane of the electrode and a smaller opening in the interior of the electrode, the openings being generally circular and being separated by sloping sidewalls. A portion of the sidewall of each aperture intersects a portion of the sidewall of an adjacent aperture to form an inwardly-sloping arcuate rounded saddle along the region of the intersection. The resulting structure is derived from the partial overlapping of geometric constructions of the volumetric configurations.
In order to compensate for the lensing field distortion caused by the rounded saddles, the structure includes at least one elongated, electron beam spot-shaping opening, preferably the smaller-dimensioned opening of the central aperture of at least one of the lensing electrodes.
As used herein, the term "elongated" generally means the form resulting from expansion of a circle along a radium (oblong), but also includes forms resulting from such expansion accompanied by some distortion of the circular curvature (eg., ellipse).
In the presently most preferred embodiment, the smaller dimensioned beam-entering rear opening of the central aperture of the focusing electrode is elongated in a direction normal to the in-line plane of the electron gun.
Alternatively, the smaller-dimensioned beam-exiting front opening of the central aperture of the accelerating electrode is elongated in the direction of the in-line plane of the electron gun.
As a further alternative, the larger-dimensioned central aperture opening of either the focusing or accelerating electrode may be elongated to achieve beam spot-shaping.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a sectioned elevation view of a color cathode ray tube wherein the invention is employed;
FIG. 2 is a sectioned view of the forward portion of the in-line plural beam electron gun assembly shown in FIG. 1, such view being taken along the in-line plane thereof;
FIG. 3 is a perspective view from above of the unitized low potential lensing electrode of the gun assembly of FIG. 2, affording a partial view of the small openings of the apertures;
FIG. 4 is a top view of one embodiment of the apertures of the unitized low potential lensing electrode of the invention including an elongated rear opening of the central aperture;
FIG. 5 is a sectioned elevation view of the embodiment of the low potential electrode of FIG. 4 taken along the plane A--A in FIG. 4;
FIG. 6 is a top view of another embodiment of the apertures of the low potential electrode of the invention, including an elongated front opening of the central aperture;
FIG. 7 is a sectioned elevation view of the embodiment of FIG. 6 taken along the plane B--B of FIG. 6;
FIG. 8 is a representation of beam spot shapes related to the electron gun of FIG. 2 without spot-shaping openings;
FIG. 9 is a representation of beam spot shapes related to the electron gun of FIG. 2 with spot-shaping openings; and
FIG. 10 is a top view of an elongated front opening of the central aperture of a unitized high potential lensing electrode of the invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
With reference to FIG. 1 of the drawings, there is shown a color cathode ray tube (CCRT) 11 of the type employing a plural beam in-line electron gun assembly. The envelope enclosure is comprised of an integration of neck 13, funnel 15 and face panel 17 portions. Disposed on the interior surface of the face panel is a patterned cathodoluminescent screen 19 formed as a repetitive array of color-emitting phosphor components in keeping with the state of the art. A multi-opening structure 21, such as a shadow mask, is positioned within the face panel, spaced from the patterned screen.
Encompassed within the envelope neck portion 13 is a unitized plural beam in-line electron gun assembly 23, comprised of a unitized structure of three side-by-side guns. Emanating therefrom are three separate electron beams 25, 27, and 29 which are directed to pass through mask 21 and land upon screen 19. It is within this electron gun assembly 23 that the structure of the invention resides.
Referring now to FIG. 2, the forward portion of the electron gun 23 of FIG. 1 is shown, including a low potential electrode 31, a high potential electrode 33, and a convergence cup 35. Electrode 31 is the final focusing electrode of the gun structure, and electrode 33 is the final accelerating electrode.
In a "Uni-Bi" gun typically used in mini-neck CCRTs, the main focusing electrode potential is typically 25 to 35 percent of the final accelerating electrode potential, the inter-electrode spacing is typically about 0.040 inches (1.02 millimeters), the angle of taper of the apertures is about 30° with respect to the tube axis, and the aperture diameters (smaller and larger dimensioned openings) are 0.140 and 0.220 inches (3.56 and 5.59 millimeters) for the focusing electrode and 0.150 and 0.250 inches (3.81 and 6.35 millimeters) for the accelerating electrode. The spacing between aperture centers is 0.177 inch (4.50 millimeter) (S 1 ) for the focusing electrode and 0.182 inch (4.62 millimeter) (S 2 ) for the accelerating electrode.
Together, these two electrodes form the final lensing fields for the electron beams. This is accomplished by cooperation between their adjacent, facing apertured portions to form lensing regions which extend across the inter-electrode space. The tapered sidewalls of the apertures enable optimum utilization of the available space inside the tube neck 13.
Referring now to FIG. 3, there is shown a focusing electrode 100 of the type shown in FIG. 2, having three in-line apertures with large front beam-exiting openings 110, 120 and 130 substantially in the forward planar surface of the electrode, and smaller rear beam-entering openings 140, 150 and 160 in the interior of the electrode, such openings connected by substantially tapered sidewalls terminating with relatively short cylindrical portions 170, 180 and 190. Geometric constructions of the apertures are truncated cones (ignoring cylindrical portions 170, 180 and 190) which partially overlap one another. This overlap is indicated in phantom in the forward planar surface, and results in the partial removal of sidewall portions of adjacent aperture and the formation of inwardly sloping arcuate edges 230 and 240. In fabrication of such electrode structure by drawing, the edge tends to have a rounded contour forming what is termed herein a "saddle", resulting in reduced sidewall area between apertures and distortion of the lensing field. This field distortion results (for a typical Uni-Bi mini-neck gun as described above) in electron beam spots at the screen as shown in FIG. 8. That is, the central beam spot tends to become compressed vertically and elongated in the direction of the in-line plane of the three beams. Compensation for such distortion is provided herein by beam spot-shaping elongation of the apertures, one embodiment of which is shown in FIG. 4, which is a top view of the aperture portion of focusing electrode 100. Side aperture openings 140 and 160 are circular, having a diameter "d", while central aperture opening 150 is elongated along each radius normal to in-line plane L by an amount r e , for a total elongation of two times r e , or d e . Thus, the elongated dimension D e of central opening 150 is d plus d e . The amount of elongation will vary depending upon the degree of field distortion present and the amount of compensation desired, the amount of compensation increasing with the amount of elongation.
For the Uni-Bi gun described above, the amount of elongation may vary from about 10 to 35 percent (d e /d×100) in the focusing electrode, and from about 15 to 40 percent in the accelerating electrode. A greater degree of elongation in the accelerating electrode is generally required to achieve the desired compensation because the electrons are traveling faster through this electrode than through the focusing electrode, and are less influenced by field distortions.
Referring now to FIG. 5, which is a section view along plane A--A of FIG. 4, it is seen that front aperture 120 and rear aperture 150 are connected by tapered sidewall 500, which forms an angle θ 1 with line p, parallel to the tube axis. The elongation of opening 150 results in a slight increase in the height of the elongated cylindrical portion of the aperture, indicated at 501 and 502. The diameters of the front apertures 110, 120 and 130 all have the diameter d e .
Another embodiment of the beam spot-shaping structure for the central aperture of the focusing electrode is shown in FIG. 6. In this embodiment, the large opening 220 of the central aperture is elongated, rather than the small opening 250. Elongation is again by an amount of two times r e or d e , resulting in an elongated dimension D e . For a given amount of compensation, the amount of elongation required in the large opening is generally less than in the small opening. This is true for both the focusing and accelerating electrodes. The reason for this is that the large openings are closer to the concentration gradient of the lensing fields, and thus less control is required to achieve the desired compensation. Nevertheless, elongation of the smaller openings is generally preferred because of the greater space available in the interior of the electrode than in the forward or apertured plane of the electrode.
For the Uni-Bi gun described above, the amount of elongation may vary from about 3 to 15 percent for the focusing electrode, and from about 5 to 20 percent for the accelerating electrode. In the embodiment of FIG. 6, the rear apertures 240, 250 and 260 all have the diameter d s .
In FIG. 7, a section view along plane B--B of FIG. 6, front aperture 220 and rear aperture 250 are connected by tapered sidewall 600, which forms angle θ 2 with line p, parallel to the tube axis L.
FIG. 9 shows the beam spots after compensation by use of the elongated aperture openings as described herein.
FIG. 10 shows the smaller opening 350 of the central aperture of the accelerating electrode, which opening 350 is elongated by an amount d e to obtain dimension D e . The principles of electron optics dictate that the direction of elongation in the accelerating electrode must be the same as the direction of elongation of the distorted beam spot, whereas the direction of elongation in the focusing electrode must be normal thereto, to achieve beam spot correction.
While there have been shown and described what are at present considered to be the preferred embodiments of the invention, it will be obvious to those skilled in the art that various changes and modifications may be made therein without departing from the scope of the invention as defined by the appended claims. Just as one example, the side aperture openings can also be elongated in the same manner described for the central openings, to influence the shaping of the side aperture-related beam spots. This may be necessary, for example, in gun structures other than the particular Uni-Bi structure described herein.
TOSHIBA COLOR PICTURE TUBE FILTER-COATED PHOSPHOR
Disclosed
is a filter-coated phosphor having phosphor particles coated with
filter particles formed of pigments of the same color as that of light
emitted from the phosphor, the phosphor particles coated with the filter
particles being additionally coated with a borate compound. According
to this filter-coated phosphor, the filter particles never exfoliate
from the surfaces of the phosphor particles in a slurry, satisfactory
dispersibility is obtained in the slurry, and the slurry pH is stable. A
phosphor screen of a color picture tube obtained with use of the
filter-coated phosphor exhibits highly outstanding contrast and luminous
efficiency.
This invention relates to a filter-coated
phosphor including phosphor particles coated with filter particles, more
specifically to an improvement of a filter-coated phosphor used for
phosphor screens of color picture tubes.
Conventionally, in order
to improve the contrast property of picture images projected on a
phosphor screen of a color picture tube, filter material is caused to
absorb external light by using a filter-coated phosphor formed of
phosphor particles coated with filter particles. Filter materials to
constitute these filter particles include pigments of the same colors as
those of phosphors emitting blue, red and green colors which are used
for the phosphor screens of color picture tubes. For example, there may
be used blue pigments such as cobalt aluminate and ultramarine blue for
blue-emitting phosphors such as ZnS/Ag,Cl and ZnS/Ag,Al, red pigments
such as red iron oxide, cadmium sulfoselenide and indium sulfide, a
newly developed filter material, for red-emitting phosphors such as Y2
O2 S/Eu, Y2 O3 /Eu, and YVO4 /Eu, and green pigments such as chromium
oxide and a mixture of yellow cadmium sulfoselenide and bluish green
cobalt aluminate for green-emitting phosphors such as Zns/Cu,Al and
(ZnCd)S/Cu,Al.
As methods for coating phosphor particles with
filter particles, various measures to bond or fix the filter particles
to the surfaces of the phosphor particles by means of organic binders
have hitherto been put to practical use. For example, there are proposed
a method using gelatin (Japanese Patent Disclosure No. 56146/75), a
method using colloidal particles in acrylic resin emulsion (Japanese
Patent Disclosure No. 109488/77), a method using acidic and basic
polymers (Japanese Patent Disclosure No. 3980/78), a method using
gelatin and gum arabic (Japanese Patent Disclosure No. 5088/78), etc.
Filter-coated
phosphors prepared by those methods, however, are poor in
dispersibility in slurry because phosphor particles are liable to
cohere. Accordingly, phosphor layers formed from a slurry containing
such filter-coated phosphor are low in packing density, and hence are
susceptible to significant perforation Further, prolonged stirring of
the slurry will allow polyvinyl alcohol in the slurry to be decomposed
or deteriorated by the action of bacteria, causing pH variations of the
slurry. The phosphor layers formed by using the slurry with such
unstable pH values will suffer more significant perforation besides the
aforesaid perforation due to poor dispersibility. This phenomenon is
expressly noticeable where gelatin, which may easily be decomposed by
bacteria, is used as the organic binder or if Y2 O2 S/Eu is used as the
phosphor. Such perforation of varied degrees will reduce the luminous
efficiency of the phosphor layers. Thus, satisfactory phosphor layers
cannot be obtained with the prior art methods using organic binders.
Moreover,
if a phosphor screen is formed by coating a glass faceplate, which is
previously coated with blue and green phosphors, with a conventional
slurry prepared from a filter-coated red phosphor, especially a red
phosphor coated with indium sulfide as the filter material, then such
phosphor screen will suffer the so-called "color blend" or a phenomenon
that the red phosphor remains on blue or green phosphor layers, reducing
the luminous brightness of the blue or green phosphor layers. This may
be caused because indium sulfide as the filter material, having active
surface, is liable to be adsorbed by the blue or green phosphor layers.
Although
not in practical use yet, there is proposed a method to fix the filter
particles on the surfaces of the phosphor particles by means of
inorganic material. This method utilizes silica or water-insoluble metal
silicate for the binder (Japanese Patent Disclosure No. 28785/79). In a
filter-coated phosphor prepared by such method, however, silica or
water-insoluble metal silicate will accelerate the cohesion of the
filter particles which are fine particles with the mean diameter of 0.2
to 0.5μ, and even the cohesion of the phosphor particles, so that
resultant phosphor layers will be liable to coagulation and hence to
substantial perforation. Thus, even this method cannot provide phosphor
layers with satisfactory properties.
The object of this invention
is to provide a filter-coated phosphor affording a high-luminous
brightness phosphor layer with improved slurry dispersibility and
contrast property without involving the possibility of exfoliation of
filter particles from the surfaces of phosphor particles in a slurry.
According
to the invention, there may be provided a filter-coated phosphor having
phosphor particles coated with filter particles formed of pigments of
the same color as that of light emitted from the phosphor, the phosphor
particles coated with the filter particles being additionally coated
with a borate compound.
This invention can be more fully
understood from the following detailed description when taken in
conjunction with the accompanying drawing, in which:
The FIGURE is a graph showing pH changes of a slurry containing the filter-coated phosphor of this invention as compared with a slurry containing the prior art filter-coated phosphor.
In the filter-coated phosphor of this invention, phosphor particles coated with filter particles with or without use of an organic binder are additionally coated with a borate compound, thereby eliminating the drawbacks of the prior art filter-coated phosphor.
Water-insoluble metal borates are preferably used for the borate compound to be applied to the phosphor of this invention. These borates include borates of any other metals than alkali metals, such as zinc borate, aluminum borate, barium borate, calcium borate, strontium borate, etc. Water-soluble metal borates such as alkali metal borates are not preferred because they dissolve in slurry and cannot cover the surfaces of phosphor particles.
Now there will be described a method for preparing the filter-coated phosphor.
First, a phosphor is dispersed in deionized water, and a pigment thoroughly dispersed in deionized water is admixed with the slurry. Then, an aqueous solution of Na2 B4 O7 is added to the mixture and fully stirred. Further, metal sulfate and/or metal nitrate (e.g., zinc sulfate, aluminum sulfate, calcium nitrate, strontium nitrate, zinc nitrate, aluminum nitrate, barium nitrate, etc.) are added and thoroughly stirred. Thus, filter particles are put on the surfaces of the phosphor particles, which are additionally coated with metal borate. The metal borate may be fixed on the surfaces of the filter-coated phosphor particles by filtering the aqueous solution to separate solid matter therefrom and drying the solid matter. In order to increase the bonding strength between the metal borate and the filter-coated phosphor particles, the filter-coated phosphor particles additionally coated with the borate compound may be baked at a temperature of 300° to 400° C.
Although there has been described a method using no organic binder in fixing filter particles on the surfaces of phosphor particles, organic binders may be used in some cases. If filter particles are fixed on the surfaces of phosphor particles by means of an organic binder and a borate compound is additionally put on the surfaces, the drawback of the prior art filter-coated phosphor obtained with use of the organic binder, i.e. the poorness in water dispersibility due to the existence of the organic binder, will be eliminated by the effect of the borate compound coating. Moreover, the adhesive strength provided by the organic binder is combined with the adhesive strength of the borate compound to increase the bonding strength between the filter particles and the phosphor particles, so that the filter particles may be prevented from exfoliating from the surfaces of the phosphor particles in a slurry.
Now there will be described the quantity of borate compound for coating. In the conventional filter-coated phosphor in practical use, the weight of filter particles for coating generally is 5% or less of the weight of phosphor particles. The weight of borate compound for coating, which depends on the weight of the filter particle coating, is preferably 0.001 to 0.3% of that of the phosphor particles, more preferably 0.01 to 0.1%, where the weight of the filter particle coating is 5% or less of that of the phosphor particles. If the weight of the borate compound coating is less than 0.001% of that of the phosphor particles, the borate compound used will be of no good, allowing exfoliation of the filter particles in the slurry. If the quantity of the borate compound coating exceeds 0.3 wt. %, on the other hand, the phosphor particles will be deteriorated in dispersibility in the slurry, making it impossible to obtain satisfactory phosphor layers.
Red-emitting phosphors applicable to this invention include yttrium oxysulfide activated by europium (Y2 O2 S/Eu), gadolinium oxysulfide activated by europium (Gd2 O2 S/Eu), yttrium oxide activated by europium (Y2 O3 /Eu), yttrium vanadate activated by europium (YVO4 /Eu), zinc orthophosphate activated by manganese (Zn3 (PO4)2 /Mn), etc. For filter materials used with these red-emitting phosphors, there are red iron, chrome vermilion, antimony red, cadmium sulfoselenide, indium sulfide, etc. Indium sulfide is a newly developed red filter material. In particular, the borate compound coating will prevent the so-called "color blend" that phosphors coated with such indium sulfide have conventionally suffered. The reason is that the indiumsulfide-coated phosphors, which are naturally liable to be adsorbed by blue- or green-emitting phosphors due to the activity of their surfaces, are reduced in the surface activity by the effect of the borate compound coating, thereby decreasing their adsorbability to the blue- or green-emitting phosphors. Table 1 shows the results of visual observation of the degree of color blend depending on the amount of borate compound for coating.
TABLE 1
______________________________________
Amount of Degree of boric compound color blend
______________________________________
Red-emitting phosphor
coated with indium
O C
sulfide
Red-emitting phosphor
coated with indium
0.001 wt.% B
sulfide
Red-emitting phosphor
coated with indium
0.01 wt. % A
sulfide
Red-emitting phosphor
coated with indium
0.1 wt. % A
sulfide
______________________________________
A: No color blend. B: Some color blend but practically insignificant. C: Significant color blend. Unpractical.
According to the results of visual examination, moreover, a phosphor slurry which was prepared with use of a phosphor formed of filter-coated yttrium oxysulfide/Eu additionally coated with a borate compound displayed stable pH value after prolonged stirring, involving neither serious perforation in phosphor layers nor exfoliation of phosphor dots or stripes which would conventionally be caused by variations in pH. Accordingly, the slurry may enjoy prolonged life, and the deterioration of the luminous efficiency of the phosphor layers may be avoided. The pH value of the phosphor slurry was stabilized because the sterilizing effect of the borate compound prevented polyvinyl alcohol or organic binder in the slurry from being deteriorated or decomposed by the action of bacteria that had probably been the main cause of the pH variations.
The accompanying drawing is a graph showing pH variations of aqueous slurry containing red-iron-coated yttrium oxysulfide/Eu for the comparison between the prior art phosphor and the phosphor of the invention. In this drawing, a solid line a represents pH variations of the prior art phosphor using no borate compound, while a broken line b represents pH variations of the phosphor of the invention using a borate compound.
Blue-emitting phosphors applicable to this invention include zinc sulfide activated by silver (ZnS/Ag), zinc sulfide activated by silver and aluminum (ZnS/Ag,Al), zinc sulfide activated by silver and chlorine (ZnS/Ag,Cl), etc. For filter materials used with these phosphors, there are cobalt aluminate, ultramarine blue, cerulean blue, etc.
Green-emitting phosphors applicable to this invention include zinc sulfide activated by copper and aluminum (ZnS/Cu,Al), zinc sulfide activated by copper and chlorine (ZnS/Cu,Cl), zinc cadmium sulfide activated by copper and aluminum ((ZnCd)S/Cu,Al), zinc oxide activated by zinc (ZnO/Zn), zinc sulfide activated by gold, copper and aluminum (ZnS/Au,Cu,Al), etc. For filter materials used with these phosphors, there are chromium oxide, cobalt green, titanium yellow, zinc iron yellow, cadmium yellow, etc.
According to the phosphor of this invention formed of filter-coated phosphor particles additionally coated with a borate compound, as described above, there may be provided various advantages; good dispersibility in slurry, minimized exfoliation of filter particles in slurry, stabilized slurry pH, and prevention of color blend in phosphor screen. The phosphor screen of a color picture tube obtained with use of the filter-coated phosphor of the invention exhibits outstanding contrast and luminous efficiency.
Several examples of this invention are given below.
EXAMPLE 1
1 kg of Y2 O2 S/Eu as a phosphor is dispersed in 2 l of deionized water. Then, 42 g of indium chloride (3 wt. % of phosphor in terms of In2 S2) dissolved in deionized water is added and fully stirred. Then, H2 S gas is passed through the mixture to cause the phosphor to adsorb indium sulfide thereon. After washed once or twice in water, the solid portion is filtered out and dried, and 75 g of sulfur and 18 g of sodium carbonate are mixed and filled into a silica crucible for one hour's sintering at 800° C. The sintered product is washed twice or thrice by deionized water and dried. Thereafter, when the dried solid portion is baked at 480° C. for an hour, the phosphor is covered with red indium sulfide. The phosphor coated with red indium sulfide is dispersed in deionized water by using a ball mill to obtain 2 l of slurry. 80 cc of 11% solution of Na2 B4 O7 is added to the slurry and fully stirred. Further, 400 cc of 0.4 mol solution of ZnSO4 is added and fully stirred. Solid material obtained by filtering the resultant mixture is dried at 120° C. The dried product is sifted out by using a 300-mesh sieve, and thus an indium-sulfide-coated phosphor (Y2 O2 S/Eu) additionally coated with zinc borate is obtained.
A phosphor slurry was prepared by the conventional method with use of the phosphor obtained in the aforesaid manner, and applied to a cathode-ray tube panel in the known procedures. Then, a phosphor film thus obtained exhibited good contrast and luminous brightness (see Table 3) without mixing in color with other phosphor film layers. In the slurry, moreover, there was noticed no exfoliation of filter material.
Table 2 shows findings on the relationship between the elapse of time before use after the phosphor slurry is prepared and the degree of dot exfoliation.
TABLE 2
______________________________________
Time for use 1 day 4 days 7 days 10 days after after after after prep. prep. prep. prep.
______________________________________
State of phosphor Partial Dot
without boric
Good dot exfoli-
compound coating exfoli- ation
ation
Partial
State of phosphor
Good Good Good dot
of the invention exfoli-
ation
______________________________________
It may be seen from Table 2 that the use of the slurry containing the phosphor of the invention will reduce the dot exfoliation of phosphor by a large margin.
EXAMPLE 2
1 kg of Y2 O2 S/Eu as a phosphor is dispersed in approximately 2 l of deionized water. Then, 42 g of indium chloride dissolved in deionized water is added and fully stirred. Then, H2 S gas is passed through the mixture to cause the phosphor to adsorb indium sulfide thereon. After washed once or twice in water, the solid portion is filtered out and dried, and 18 g of sodium carbonate and 75 g of sulfur are mixed and filled into a silica crucible for one hour's sintering at 800° C. The sintered product is washed twice or thrice, and dispersed for 20 minutes by using a ball mill. Thereafter, 40 cc of 11% solution of Na2 B4 O7 is added and stirred for 20 to 30 minutes in the same manner as Example 1. Then, 200 cc of 0.4 mol solution of barium nitrate (Ba(NO3)2) is added and fully stirred. After washed several times with deionized water, solid matter obtained by filtration is dried and sifted, and thus an indium-sulfide-coated phosphor (Y2 O2 S/Eu) additionally coated with barium borate is obtained.
A phosphor slurry was prepared with use of the phosphor obtained in the aforesaid manner, and applied to a cathode-ray tube panel in the known-procedures. A phosphor film thus obtained suffered no color mixture with other phosphor film layers. Further, a phosphor film obtained by baking such film at 450° C. for about one hour exhibited good contrast and luminous brightness (see Table 3).
EXAMPLE 3
1 kg of Y2 O2 S/Eu as a phosphor is dispersed in 2 l of deionized water, and 1 g of well dispersed red iron oxide is added and fully stirred. 10 cc of 11% solution of Na2 B4 O7 is added to the resultant solution, and 50 cc of 0.4 mol solution of ZnSO4 is further added and thoroughly stirred. Then, solid matter obtained by filtering the mixture is dried and sifted by using a 300-mesh sieve, and thus a red-iron-oxide-coated phosphor (Y2 O2 S/Eu) additionally coated with zinc borate is obtained.
The solution of ZnSO4 may be replaced with Zn(NO3)2.6H2 O, A 2 (SO4)3 or Ba(NO3)2.
A phosphor slurry prepared with use of the phosphor obtained in the aforesaid manner exhibited stable pH values after prolonged stirring. When this slurry was applied to a cathode-ray tube panel in the known procedures, a resultant phosphor film exhibited good contrast and luminous brightness (see Table 3).
EXAMPLE 4
1 l of deionized water, 1 kg of ZnS/Ag as a blue-emitting phosphor, 20 g of well dispersed cobalt aluminate, and 0.05 wt. % of acrylic resin emulsion (Nippon Acryl HA-24) are dispersed and admixed by ball-milling for 10 minutes. Then, the pH value of this mixture is adjusted to 2 to 3 by using 0.1 mol sulfuric acid. Further, 40 cc of 0.1 g/cc solution of Al(NO3)3.9H2 O is added and ball-milled for 10 minutes. The mixture is removed from the ball mill, admixed with deionized water to make up the volume to 15 l, and stirred for 3 hours. Solid portion of the mixture is put in a ball mill pot for 10 minutes' ball-milling, taken out of the pot, and admixed with deionized water to make up the volume to 15 l. Then, the pH value of the mixture is adjusted to 7 to 8 by using a solution of NH4 OH, and the mixture is stirred for an hour. After washing the mixture 5 or 6 times with deionized water, 40 cc of 11% solution of Na2 B4 O7 and 200 cc of 0.4 mol solution of ZnSO4 are added in succession and stirred thoroughly. Solid matter obtained by filtering the mixture is dried and sifted out by using a 300-mesh sieve, and thus a cobalt-aluminate-coated phosphor (ZnS/Ag) additionally coated with zinc borate is obtained.
A phosphor slurry was prepared with use of the phosphor obtained in the aforesaid manner, and applied to a cathode-ray tube panel in the known procedures. Then, a phosphor film thus obtained exhibited good contrast and luminous brightness (see Table 3), and there was noticed no exfoliation of filter material in the slurry.
EXAMPLE 5
2 l of deionized water, 1 kg of Y2 O2 S/Eu as a red-emitting phosphor, 10 g of well dispersed red iron oxide, and 0.02 wt. % of acrylic resin emulsion are dispersed and admixed by ball-milling for 10 minutes. Then, the pH value of this mixture is adjusted to 2 or 3 using 0.1 mol H2 SO4, and mixture is subjected to additional 10 minutes' ball-milling. Subsequently, 40 cc of 0.1 g/cc solution of Al(NO3)3.9H2 O is added and ball-milled for further 10 minutes. Then, the mixture is removed from the ball mill, admixed with deionized water to make up the volume to 15 l, and stirred for 3 hours. Then, the pH value of the mixture is adjusted to 7 or 8 by using a solution of NH4 OH, and the mixture is stirred for an hour. After washing the mixture several times with deionized water, 40 cc of 11% solution of Na2 B4 O7 is added and stirred for 30 minutes. Further, 200 cc of 0.4 mol solution of ZnSO4 is added and fully stirred. After stirring, the mixture is washed several times with deionized water, and filtered. Solid matter obtained by such filtration is dried and sifted out by using a 300-mesh sieve, and thus a red-iron-oxide-coated phosphor (Y2 O2 S/Eu) additionally coated with zinc borate is obtained.
A phosphor slurry prepared with use of the phosphor obtained in the aforesaid manner exhibited stable pH values after prolonged stirring. When this slurry was applied to a cathode-ray tube panel in the known procedures, a resultant phosphor film exhibited good contrast and luminous brightness (see Table 3). In the slurry, moreover, there was noticed no exfoliation of filter material.
EXAMPLE 6
1 kg of ZnS/Ag as a blue-emitting phosphor is dispersed in 2 l of deionized water. Then, 10 g of well dispersed ultramarine blue as filter material is added and fully stirred, and thereafter ball-milled for 10 minutes. Then, deionized water is added to the mixture to make up the volume to 10 l. Further, 40 cc of 11% solution of Na2 B4 O7 is added and stirred for 20 to 30 minutes. Subsequently, 200 cc of 0.4 mol solution of aluminum sulfate is added and fully stirred. After washing the mixture several times with deionized water, solid material obtained by filtration is dried and sifted out, and thus an ultramarine-blue-coated phosphor (ZnS/Ag) additionally coated with aluminum borate is obtained.
A phosphor slurry was prepared with use of the phosphor obtained in the aforesaid manner, and applied to a cathode-ray tube panel in the known procedures. Then, a phosphor film thus obtained exhibited good contrast and luminous brightness (see Table 3).
EXAMPLE 7
2 l of deionized water, 1 kg of ZnS/Cu,Al as a green-emitting phosphor, 10 g of well dispersed zinc iron yellow, and 0.02 wt. % of acrylic resin emulsion (Nippon Acryl HA-24) are dispersed and admixed by ball-milling for 10 minutes. Then, the pH value of this mixture is adjusted to 3 by using 0.1 mol sulfuric acid, and the mixture is stirred for 20 to 30 minutes.
Subsequently, 40 cc of 0.1 g/cc solution of Al(NO3)3.9H2 is added and stirred for 20 minutes. Thereafter, deionized water is added to the mixture to make up to volume to 15 l, and the mixture is stirred for 3 hours. Then, solid portion of the mixture is put in a ball mill pot for 10 minutes' ball-milling, taken out of the pot, and admixed with deionized water to make up the volume to 15 l. Then, the pH value of the mixture is adjusted to 7 or 8 by using a solution of NH4 OH, and the mixture is stirred for an hour. After washing the mixture 4 or 5 times with deionized water, 40 cc of 11% solution of Na2 B4 O7 and 200 cc of 0.4 mol solution of ZnSO4 are added in succession and stirred thoroughly. After washed several times with deionized water, solid matter obtained by filtration is dried and sifted out by using a 300-mesh sieve, and thus a zinc-iron-yellow-coated phosphor (ZnS/Cu,Al) additionally coated with zinc borate is obtained.
A phosphor slurry was prepared with use of the phosphor obtained in the aforesaid manner, and applied to a cathode-ray tube panel in the known procedures. Then, a phosphor film thus obtained exhibited good contrast and luminous brightness (see Table 3), and there was noticed hardly any exfoliation of filter materaial in the slurry.
EXAMPLE 8
2 l of deionized water, 1 kg of ZnS/Au,Cu,Al as a green-emitting phosphor, and 10 g of well dispersed zinc iron yellow are admixed and ball-milled for 10 minutes. Then, deionized water is added to make up the volume to 10 l. 40 cc of 11% solution of Na2 B4 O7 is added to the mixture and stirred for 30 minutes. Further, 200 cc of 0.4 mol solution of strontium nitrate is added and stirred thoroughly. After stirring, the mixture is washed several times with deionized water, and filtered. Solid matter obtained by such filtration is dried and sifted out by using a 300-mesh sieve, and thus a zinc-iron-yellow-coated phosphor (ZnS/Au,Cu,Al) additionally coated with strontium borate is obtained.
A phosphor slurry was prepared with use of the phosphor obtained in the aforesaid manner, and applied to a cathode-ray tube panel in the known procedures. Then, a phosphor film thus obtained exhibited good contrast and luminous brightness (see Table 3).
TABLE 3
______________________________________
Phosphor-screen luminous brightness of filter-coated phosphor additionally coated with borate compound Luminous Brightness of Phosphor Screen Blue- Green- Red- Remarks filter- filter- filter- Phosphor coated coated coated & filter Example phosphor phosphor phosphor material
______________________________________
1 110% Y2 O2 S/Eu
(100) + In2 S3
2 110% Y2 O2 S/Eu
(100) + In2 S3
3 108% Y2 O2 S/Eu +
(100) red ion oxide
108% ZnS/Ag +
4 (100) cobalt
aluminate
109% (100)
Y2 O2 S/Eu + In2 S3
5 107% (100)
Y2 O2 S/Eu + red
iron oxide
107% ZnS/Ag +
6 (100) ultramarine
blue
106% ZnS/Cu,Al
7 (100) + zinc iron
yellow
105% ZnS/Au,Cu,Al
8 (100) + zinc iron
yellow
______________________________________
*Numerical value in parenthesis is luminous brightness of phosphor screen formed of same phosphor without borate compound coating.
ITT DIGIVISION 3486 OSCAR CHASSIS DIGI 3 90° ITT DIGIT2000 CATHODE RAY TUBE (Kinescope) driver with kinescope current sensing circuit: A television receiver includes a kinescope and a current sensing transistor for conveying amplified video signals to the kinescope, and for providing at a sensing output terminal an output signal related to the magnitude of kinescope current conducted during given sensing intervals. A clamping circuit clamps the sensing output terminal during normal image intervals, and unclamps the sensing output terminal during the sensing intervals. The clamping circuit facilitates interfacing the sensing transistor with utilization circuits which process the sensed output signal, and assists to maintain a proper operating condition for the sensing transistor. 1. In a video signal processing system including an image reproducing device for displaying video information in response to a video signal applied thereto, apparatus comprising:
a video output driver stage with a video signal input and a video signal output for providing an amplified video signal;
means for conveying said amplified video signal to said image reproducing display device, said conveying means having a sensing output for providing thereat a sensed signal representative of the current conducted by said image reproducing display device;
utilization means responsive to said sensed signal; and
clamping means for selectively clamping said sensing output during normal image intervals, and for unclamping said sensing output during intervals when said sensed signal representative of current conducted by said image reproducing display device is subject to processing by said utilization means; wherein
said clamping means comprises clamping transistor means with an output first electrode coupled to said sensing output, a second electrode coupled to an operating potential, and an input third electrode coupled to said sensing output, the conduction of said clamping transistor means being controlled in accordance with the magnitude of said sensed signal as received by said third electrode; and
said clamping transistor means is self-keyed to exhibit clamping and non-clamping states in response to said sensed representative signal.
2. Apparatus according to claim 1, wherein:said video output stage comprises a video amplifier with a video signal input and a video signal output for providing said amplified video signal; and
said conveying means comprises an active current conducting device with an input first terminal for receiving said amplified video signal, an output second terminal for conveying said amplified video signal to said image reproducing display device, and a third terminal for providing said sensed signal.
3. Apparatus according to claim 2, whereinsaid active current conducting device is a transistor with a base input for receiving said amplified video signal, an emitter output for providing said amplified video signal to said image reproducing display device, and a collector output for providing said sensed signal.
4. Apparatus according to claim 1, whereinsaid first and second electrodes define a main current conduction path of said clamping transistor means.
5. Apparatus according to claim 4, whereinsaid clamping means includes resistive means coupled to said sensing output for providing a voltage in accordance with the magnitude of said sensed signal; and
said third electrode of said clamping transistor means is coupled to said resistive means.
6. Apparatus according to claim 1, and further comprisingfilter means for bypassing high frequency signal components at said sensing output.
7. In a video signal processing system including an image reproducing device for displaying video information in response to a video signal applied thereto, apparatus comprising:a video output driver stage coupled to said image reproducing display device for providing an amplified video signal thereto, and having a sensing output for providing thereat a sensed signal representative of the current conducted by said image reproducing display device;
control means responsive to said sensed signal for developing a control signal;
means for coupling said control signal to said image reproducing display device to maintain a desired conduction characteristic of said image reproducing display device; and
clamping means for selectively clamping said sensing output during normal image intervals, and for unclamping said sensing output during intervals when said control means operates to monitor said sensed signal; wherein
said clamping means comprises clamping transistor means with an output first electrode coupled to said sensing output, a second electrode coupled to an operating potential, and an input third electrode coupled to said sensing output, the conduction of said clamping transistor means being controlled in accordance with the magnitude of said sensed signal as received by said third electrode; and
said clamping transistor means is self-keyed to exhibit clamping and non-clamping states in response to said sensed signal.
8. Apparatus according to claim 7, whereinsaid control means includes digital signal processing circuits; and
said control means includes an input analog-to-digital signal converter network.
9. In a video signal processing system including an image reproducing device for displaying video information in response to a video signal applied thereto, apparatus comprising:a video amplifier with a video signal input for receiving video signals, and a video signal output for providing an amplified video signal;
a signal coupling transistor with an input first electrode for receiving said amplified video signal from said video amplifier, an output second electrode for providing a further amplified video signal to said image reproducing display device, and a third electrode for providing a sensed signal representative of the magnitude of the current conducted by said image reproducing display device;
utilization means responsive to said sensed signal; and
clamping means for selectively clamping said third electrode of said coupling transistor during normal image intervals, and for unclamping said third electrode during interval when said sensed representative signal is subject to processing by said utilization means, said clamping means comprising clamping transistor means with an output first electrode coupled to said third electrode of said signal coupling transistor, a second electrode coupled to an operating potential, and an input third electrode coupled to said third electrode of said signal coupling transistor, the conduction of said clamping transistor means being controlled in accordance with the magnitude of said sensed signal as received by said input third electrode of said clamping transistor means.
10. Apparatus according to claim 9, whereinsaid coupling transistor is an emitter follower transistor with a base input electrode, an emitter output electrode, and a collector output electrode corresponding to said third electrode.
This invention concerns a video output display driver amplifier for supplying high level video output signals to an image display device such as a kinescope in a television receiver. In particular, this invention concerns a display driver stage associated with a sensing circuit for providing a signal representative of the magnitude of current conducted by the kinescope during prescribed intervals.
Video signal processing and display systems such as television receivers commonly include a video output display driver stage for supplying a high level video signal to an intensity control electrode, e.g., a cathode electrode, of an image display device such as a kinescope. Television receivers sometimes employ an automatic black current (bias) control system or an automatic white current (drive) control system for maintaining desired kinescope operating current levels. Such control systems typically operate during image blanking intervals, at which time the kinescope is caused to conduct a black image or a white image representative current. Such current is sensed by the control system, which generates a correction signal representing the difference between the magnitude of the sensed representative current and a desired current level. The correction signal is applied to video signal processing circuits for reducing the difference.
Various techniques are known for sensing the magnitude of the black or white kinescope current. One often used approach employs a PNP emitter follower current sensing transistor connected to the kinescope cathode signal coupling path. Such sensing transistor couples video signals to the kinescope via its base-to-emitter junction, and provides at a collector electrode a sensed current representative of the magnitude of the kinescope cathode current. The representative current from the collector electrode of the sensing transistor is conveyed to the control system and processed to develop a suitable correction signal.
In accordance with the principles of the present invention, there is disclosed a kinescope current sensing arrangement wherein a current sensing device is coupled to a kinescope for providing at an output terminal a signal representative of the magnitude of the kinescope current. A clamping circuit clamps the output terminal to a given voltage during normal image trace intervals. During prescribed kinescope current sensing intervals, however, the clamping circuit is inoperative and the sensed signal representative of the kinescope current is developed at the output terminal. The clamping circuit advantageously facilitates interfacing the current sensing device with control circuits for processing the sensed signal, and assists to maintain a proper operating condition for the current sensing device which, in a disclosed embodiment, also conveys video signals to the display device. In accordance with a feature of the invention, the clamping circuit is self-keyed between clamping and non-clamping states in response to the representative signal at the output terminal.
In the drawing:
FIG. 1 shows a circuit diagram of a kinescope driver stage with associated kinescope current sensing and clamping apparatus in accordance with the present invention; and
FIG. 2 depicts, in block diagram form, a portion of a color television receiver incorporating the current sensing and clamping apparatus of FIG. 1.
In FIG. 1, low level color image representative video signals r, g, b are provided by a source 10. The r, g and b color signals are coupled to similar kinescope driver stages. Only the red (r) color signal video driver stage is shown in schematic circuit diagram form.
Red kinescope driver stage 15 comprises a driver amplifier including an input common emitter amplifier transistor 20 arranged in a cascode amplifier configuration with a common base amplifier transistor 21. Red color signal r is coupled to the base input of transistor 20 via a current determining resistor 22. Base bias for transistor 20 is provided by a resistor 24 in association with a source of negative DC voltage (-V). Base bias for transistor 21 is provided from a source of positive DC voltage (+V) through a resistor 25. Resistor 25 in the base circuit of transistor 21 assists to stabilize transistor 21 against oscillation.
The output circuit of driver stage 15 includes a load resistor 27 in the collector output circuit of transistor 21 and across which a high level amplified video signal is developed, and opposite conductivity type emitter follower transistors 30 and 31 with base inputs coupled to the collector of transistor 21. A high level amplified video signal R is developed at the emitter output of follower transistor 30 and is coupled to a cathode electrode of an image reproducing kinescope via a kinescope arc current limiting resistor 33. A resistor 34 in the collector circuit of transistor 31 also serves as a kinescope arc current limiting resistor. Degenerative feedback for driver stage 15 is provided by series resistors 36 and 38, coupled from the emitter of transistor 31 to the base of transistor 20.
A diode 39 connected between the emitters of transistors 30 and 31 as shown is normally reverse biased and therefore nonconductive by the voltage difference across it equalling the sum of the two base-emitter voltage drops of transistors 30 and 31, but is forward biased and therefore rendered conductive under certain conditions in response to positive-going transients at the emitter of transistor 30, corresponding to the output terminal of driver stage 15. The arrangement of transistor 31 prevents the amplifier feedback loop including transistors 20, 21 and 31 and resistors 36 and 38 from being disrupted, thereby preventing feedback transients and signal ringing from occurring. Additional details of the arrangement including transistors 30 and 31 and diode 39 are found in my copending U.S. patent application Ser. No. 758,954 titled "FEEDBACK DISPLAY DRIVER STAGE".
The emitter voltage of transistor 30 follows the voltage developed across load resistor 27, and transistor 30 conducts the kinescope cathode current. Substantially all of the kinescope cathode current flows as collector current of transistor 30, through a kinescope arc current limiting protection resistor 37a, to a clamping network 40. Transistor 30 acts as a current sensing device in conjunction with network 40 as will be explained. Clamping network 40 in this example is self-keyed to exhibit clamping and non-clamping states in response to the magnitude of the current conducted by transistor 30.
Clamping network 40 is common to all three driver stages of the receiver, as will be seen subsequently in connection with FIG. 2, and is coupled to the green and blue signal driver stages via protection resistors 37b and 37c. Network 40 includes clamping transistors 41 and 42 arranged in a Darlington configuration, and series voltage divider resistors 43 and 44 which bias clamp transistors 41 and 42. A high frequency bypass capacitor 46 filters signals in the collector circuit of transistor 30 in a manner to be described below. The series combination of a mode control switch 49 and a scaling resistor 48 is coupled across resistors 43 and 44. A voltage related to the magnitude of kinescope current is developed at a terminal A and, as will be explained with reference to FIG. 2, the voltage at terminal A can be used in conjunction with a feedback control loop to maintain a desired kinescope operating current condition which is otherwise subject to deterioration due to kinescope aging and temperature effects, for example.
Assuming switch 49, the function of which will be explained below, is open, the kinescope cathode current flowing in the collector of transistor 30 is conducted to ground via resistors 43 and 44. When this current causes a voltage drop across resistor 44 to sufficiently forward bias the base-emitter junctions of transistors 41 and 42, transistor 42 will conduct in a linear region, and will clamp terminal A to a voltage VA according to the following expression, where V BE41 and V BE42 are the base-emitter junction voltage drops of transistors 41 and 42: VA=(V BE41 +V BE42 ) (R43+R44)/R44
During normal image intervals typically there are greater than approximately 25 microamperes of current conducted by transistor 30, which is sufficient to render transistors 41 and 42 conductive for developing clamping voltage VA at terminal A. At other times, as will be discussed, transistors 41 and 42 are rendered nonconductive whereby clamping action is inhibited and a (variable) voltage is developed at node A as a function of the magnitude of the kinescope cathode current, for processing by succeeding control circuits.
Illustratively, the arrangement of FIG. 1 can be used in connection with digital signal processing and control circuits in a color television receiver employing digital signal processing techniques, as will be seen in FIG. 2. Such control circuits include an input analog-to-digital converter (ADC) for converting analog voltages developed at terminal A to digital form for processing.
When the control circuits are to operate in an automatic kinescope black current (bias) control mode, wherein during image blanking intervals the kinescope conducts very small cathode currents on the order of a few microamperes, approximating a kinescope black image condition, clamp transistors 41 and 42 are rendered nonconductive because such small currents flowing through resistors 43 and 44 from the collector of transistor 30 are unable to produce a large enough voltage drop across resistor 44 to forward bias transistors 41 and 42. Consequently terminal A exhibits voltage variations, as developed across resistors 43 and 44, related to the magnitude of kinescope black current. The voltage variations are processed by the control circuits coupled to terminal A to develop a correction signal, if necessary, to maintain a desired level of kinescope black current conduction by feedback action. In this operating mode switch 49, e.g., a controlled electronic switch, is maintained in an open position as shown in response to a timing signal VT developed by the control circuits.
When the control circuits are to operate in an automatic kinescope white current (drive) control mode wherein during image blanking intervals the kinescope conducts much larger currents representing a white image condition, switch 49 closes in response to timing signal VT, thereby shunting resistor 48 across resistors 43 and 44. The value of resistor 48 is chosen relative to the combined values of resistors 43 and 44 so that the larger current conducted via the collector of transistor 30 divides between series resistors 43, 44 and resistor 48 such that the magnitude of current conducted by resistors 43 and 44 is insufficient to produce a large enough voltage drop across resistor 44 to render clamping transistors 43 and 44 conductive. Unclamped terminal A therefore exhibits voltage variations related to the magnitude of kinescope white current, which voltage variations are processed by the control circuits to develop a correction signal as required. As used herein, the expression "white current" refers to a high level of individual red, green or blue color image current, or to combined high level red, green and blue currents associated with a white image.
With the illustrated configuration of transistors 41 and 42 clamping voltage VA is relatively low, approximately +2.0 volts. The clamping voltage could be provided by a Zener diode rather than the disclosed arrangement of Darlington-connected transistors 41 and 42, but the disclosed clamping arrangement is preferred because Zener diodes with a voltage rating less than about 4 volts usually do not exhibit a predictable Zener threshold voltage characteristic, i.e., the "knee" transition region of the Zener voltage-vs-current characteristic is usually not very well defined. In addition, the disclosed transistor clamp operates with better linearity than a Zener diode clamp and radiates less radio frequency interference (RFI).
The relatively low clamping voltage is compatible with the analog input voltage requirements of the analog-to-digital converter (ADC) at the input of the control circuits which receive the sensed voltage at terminal A as will be explained in greater detail with respect to FIG. 2. In this example the ADC is intended to process analog voltages of from 0 volts to approximately +2.5 volts, and the clamping voltage assures that excessively high analog voltages are not presented to the ADC during normal video signal intervals.
The relatively low clamping voltage also assists to prevent transistor 30 from saturating, which is necessary since transistor 30 is intended to operate in a linear region. To achieve this result and to maximize the cathode current conduction capability of transistor 30, the clamping voltage should be as low as possible to maintain a suitably low bias voltage at the collector of transistor 30. On the other hand, the value of arc current limiting resistor 37a should be large enough to provide adequate arc protection without compromising the objective of maintaining the collector bias voltage of transistor 30 as low as possible. Operation of transistor 30 in a saturated state renders transistor 30 ineffective for its intended purpose of properly conveying video drive signals to the kinescope cathode, and for conveying accurate representations of cathode current to clamping network 40 particularly in the white current control mode when relatively high cathode current levels are sensed. In addition, undesirable radio frequency interference (RFI) can be generated by transistor 30 switching into and out of saturation. Also, when saturation occurs transistor base storage effects can result in video image streaking due to the time required for a transistor to come out of a saturated state.
Thus clamping network 40 advantageously limits the voltage at terminal A to a level tolerable by the analog-to-digital converter at the input of the control circuits coupled to terminal A, and protects the analog-to-digital converter input from damage due to signal overdrive. Network 40 also provides a collector reference bias for transistor 30 to prevent transistor 30 from saturating on large negative-going signal amplitude transitions at its emitter electrode. The clamping voltage level is readily adjusted simply by tailoring the values of resistors 43 and 44.
Capacitor 46 bypasses high frequency video signals to ground to prevent transistor 30 from saturating in response to such signals. Capacitor 46 also serves to smooth out undesirable high frequency variations at terminal A to prevent potentially troublesome signal components such as noise from interfering with the signal processing function of the input analog-to-digital converter of the control circuits, e.g., by smoothing the current sensed during the settling time of the analog-to-digital converter.
The latter noise reducing effect is particularly desirable, for example, when the input ADC of the control circuits coupled to terminal A is of the relatively inexpensive and uncomplicated "iterative approximation" type ADC, compared to a "flash" type ADC. The operation of an iterative ADC, wherein successive approximations are made from the most significant bit to the least significant bit, requires a relatively constant or slowly varying analog signal to be sampled during sampling intervals, uncontaminated by noise and similar effects.
The value of capacitor 46 should not be excessively large because a certain rate of current variation should be permitted at terminal A with respect to kinescope cathode currents being sensed. If the value of capacitor 46 is too small, excessive voltage variations, particularly high frequency video signal variations, will appear at terminal A, increasing the likelihood of transistor 30 saturating. The speed of operation of the clamp circuit itself is restricted by an RC low pass filter effect produced by the base capacitance of transistor 41 and the equivalent resistance of resistors 43 and 44.
FIG. 2 shows a portion of a color television receiver system employing digital video signal processing techniques. The FIG. 2 system utilizes kinescope driver amplifiers and a clamping network as disclosed in FIG. 1, wherein similar elements are identified by the same reference number. By way of example, the system of FIG. 2 includes a MAA 2100 VCU (Video Codec Unit) corresponding to video signal source 10 of FIG. 1, a MAA 2200 VPU (Video Processor Unit) 50, and a MAAA 2000 CCU (Central Control Unit) 60. The latter three units are associated with a digital television signal processing system offered by ITT Corporation as described in a technical bulletin titled "DIGIT 2000 VLSI DIGITAL TV SYSTEM" published by the Intermetall Semiconductors subsidiary of ITT Corporation.
In unit 10, a luminance signal and color difference signals in digital form are respectively converted to analog form by means of digital-to-analog converters (DACs) 70 and 71. The analog luminance signal (Y) and analog color difference signals r-y and b-y are combined in a matrix amplifier 73 to produce r, g and b color image representative signals which are processed by preamplifiers 75, 76 and 77, respectively, before being coupled to kinescope driver stages 15, 16 and 17 of the type shown in FIG. 1. A network 78 in unit 10 includes circuits associated with the automatic white current and black current control functions.
The high level R, G and B color signals from driver stages 15, 16 and 17 are coupled via respective current limiting resistors (i.e., resistor 33) to cathode intensity control electrodes of a color kinescope 80. Currents conducted by the red, green and blue kinescope cathodes are conveyed to network 40 via resistors 37a-37c, for producing at terminal A a voltage representative of kinescope cathode current conducted during measuring intervals, as discussed previously.
VPU unit 50 includes input terminals 15 and 16 coupled to terminal A. Through terminal 15 the VPU receives the analog signal from terminal A and, via an internal multiplex switching network 51, the analog signal is supplied to an analog-to-digital-converter (ADC) 52. Terminal 16 is connected to an internal switching device (corresponding to switch 49 in FIG. 1) which, in conjunction with scaling resistor 48, controls the impedance and therefore the sensitivity at input terminal 15. High sensitivity for black current measurement is obtained with resistor 48 ungrounded by internal switch 49, and low sensitivity for white current measurement is obtained with resistor 48 grounded by internal switch 49.
The digital signal from ADC 52 is coupled to an IM BUS INTERFACE unit 53 which coacts with CCU unit 60 and provides signals to an output data multiplex (MPX) unit 55. Multiplexed output signal data from unit 55 is conveyed to VCU unit 10, and particularly to control network 78. Control network 78 provides output signals for controlling the signal gain of preamplifiers 75, 76 and 77 to achieve a correct white current condition, and also provides output signals for controlling the DC bias of the preamplifiers to achieve a correct black current condition.
More specifically, during vertical image blanking intervals the three (red, green, blue) kinescope black currents subject to measurement and the three white currents subject to measurement are developed sequentially, sensed, and coupled to VPU 50 via terminal 15. The sensed values are sequenced, digitized and coupled to IM Bus Interface 53 which organizes the data communication with CCU 60. After being processed by CCU 60, control signals are routed back to interface 53 and from there to data multiplexer 55 which forwards the control signals to VCU 10.
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