NL8500895A - IMAGE DISPLAY SYSTEM. - Google Patents

Description

V

* VO 7123

Subject: Image display system.

The invention generally relates to an image display device and more particularly to an imaging system for providing three or more color component images of a subject and combining the images to produce a single image in a plurality of colors of this subject display.

A cathode ray type image display tube generally comprises a tubular envelope containing an electron gun arranged to scan an electron beam across a portion of an output phosphor sharply to provide a visible light image. The phosphor screen may be provided with a suitable phosphor material for emitting light of a desired color when electrons from the scanning beam penetrate the screen. Thus, a plurality of cathode ray tubes can be provided with respective phosphor screens, which are comprised of different phosphor materials 15 to provide respective different color component images of the same subject, arranged so that the different color images are superimposed on a projection screen. As a result, a single multi-color image will be displayed on the projection screen, comprising 20 discrete areas corresponding to the relative intensities of the different colors in corresponding discrete areas of the respective component images formed by each of the cathode ray tubes.

However, it has been found to be difficult to provide a plurality of cathode ray tubes with means for forming identical images of the same subject and to keep the tubes precisely optically centered in order to color center in discrete areas of the image in a plurality of colors to gain. Therefore, different types of cathode ray tubes have been developed which are provided with phosphor screens comprising different phosphor materials to form a multi-color image. For example, a damage-mask type cathode ray tube has a phosphor screen, which has intermixed arrays of phosphor tips, the tips of each array consisting of a different phosphor material to emit respective colored light when electrons are from a corresponding beam, which 8500895 • * - 2 - centered openings in a shadow mask pass through.press the screen. A cathode ray tube of the beam index type, as another example, has a phosphor screen provided with mixed systems of phosphor strips, the strips of each system consisting of a different phosphor material for a localized emission of respective colored light when electrons from a an appropriately indexed electron beam penetrates the screen. A voltage penetration type cathode ray tube has, as a third example, a phosphor screen, which is provided with superimposed layers of different phosphor materials, the material of each layer being activated for a localized emission of respective colored light when electrons having a penetrate the corresponding energy level in a scanning electron beam through the screen.

Therefore, cathode ray tubes of the described types have phosphor heaters, which require complex deposition methods or special phosphor materials during manufacture, thereby increasing the cost of manufacturing these known tubes.

These and other drawbacks of the prior art devices are eliminated according to the invention in that it provides an image display system having means for forming a group of three or more images located in a surface and similarly over a predetermined portion of the surface are arranged. The images may be positioned to similarly extend in respective different directions from said predetermined portion of the surface and may include respective component images of an object.

Each of the images is inverted in at least one aspect from other images of the group.

This image display system also includes means coupled to the group 30 for combining the three or more images and forming a single combined image. Therefore, when the three or more images comprise respective component images of a subject, the resulting single combined image is a composite image of the subject. When the three or more component images are present in respective different colors, the resulting composite image also includes a multi-color image of the subject.

The means for forming the group of three or more images 8500895 a - 3 - may comprise a cathode ray type image display tube having a tubular envelope in which an electron gun is arranged to direct an electron beam to an output display which is image transmissive portion of the envelope is centered.

The output display screen includes quadrant portions of respective phosphor materials, which similarly extend from a central portion of the screen and are capable of emitting light of a desired color locally in response to incident electrons from the beam.

The means for forming the group of three or more images may also include beam control means coupled to the electron beam to sequentially deflect the beam across each of the quadrant portions, while varying the intensity of the beam accordingly to form the respective images therein. However, the electron beam is deflected over each of these quadrant portions, for example by sensing a conventional grating pattern, in a manner which is inverse in at least one aspect compared to the ways in which the electron beam is deflected across the other quadrant portions. Therefore, the respective constituent images formed in the quadrant portions are inverted in at least one aspect when compared with each other.

The image combination members of this image display system may include an optical combination system disposed outside the casing 25 of the tube and optically coupled to the output display of the tube through its image transmissive portion. The combination optical system may include a system of optical devices centered and supported to receive light from each of the 30's quadrant portions of the output screen and direct it along respective paths of equivalent optical length . As a result, corresponding light rays from the quadrant portions reach the observer's eye along identical light paths; the respective images formed in the quadrant portions appear to be superimposed on one another in a common virtual image plane. Furthermore, the optical devices of the image combining system are arranged such that the mutually inverted images of the quadrant portions viewed in the common virtual image plane are oriented in a similar manner. Therefore, the eye of an observer sees that located behind the output of the optical combination system and directed along its optical axis, a single combined image.

Therefore, when respective component constituent images of a subject are formed in the quadrant portions in respective different colors, the viewer's eye sees a single composite multi-color image in which not only the colors of the respective component images are present, but also mixtures thereof , which form intermediate 10 perceived colors.

The invention will be explained in more detail below with reference to the drawing. In the drawing: Fig. 1 shows an axial section and a schematic view of an image display system according to the invention; Fig. 2 is a schematic isometric view of the optical combination system at the output end of the image display tube shown in Figure 1, the optical combination system being shown exploded for clarity; FIG. 3 is a top plan view of the exit end of the image display tube shown in FIG. 1, taken along line III-III and viewed in the direction of the arrows, but rotated through 90 ° for clarity; Fig. k is a schematic isometric view of another embodiment of the optical combination system shown in Fig. 2, showing an optical path of red light emanating from one quadrant portion of the output screen; FIG. 5 is a schematic view similar to that of FIG. k, however showing an optical path of green light emanating from a second quadrant portion of the exit screen 30; FIG. 6 is a schematic view similar to that of FIG. K, however, illustrating an optical path of blue light emanating from one third quadrant portion of the output screen; Fig. T is a schematic view similar to that of Fig. K, but illustrating an optical path of blue light emanating from a fourth quadrant portion of the 8500895 output screen; FIG. 8 is a schematic view of a single combined image of the four images formed in the four quadrant portions of the exit screen shown in FIG. 3, and viewed through the viewer's eye 5, as shown in FIG. 2; FIG. 9 is an electrical schematic of the circuitry that may be contained in the composite grid generator shown in FIG. 1; Figures 10A-10H show diagrams of waveforms, which represent electrical signals generated using the circuit shown in Figures 9 to 10; and FIG. 11 is another alternative embodiment of the method shown in FIG.

2 shows the optical combination system, in which the optical path of blue light is indicated, which light originates from a third quadrant part of the output screen.

Referring to the drawing, in which like parts have been given the same references, in Fig. 1 a multi-color image display system 20 comprising a tube 22 of the cathode ray type has been healed. The tube 22 is provided with a funnel-shaped sleeve 24, which is made of a suitable dielectric material, such as, for example, glass 20, and which sleeve has an axial center line 25 extending into a neck end portion 26 of the sleeve 24. 26 terminates at one end of the sheath 24 in a circumferentially sealed stem 28 through which a circular array of spaced connecting pins 29 extends hermetically sealing. The terminal pins 29 provide means for supporting and establishing electrical connections to respective elements of an electron gun 30 disposed axially in the neck end portion 26 of the shell 24.

The electron gun 30 includes a filament 32 disposed axially at the stem 28 and in an inverted cathode cup 36, which cup has a closed end with an outer cover (not shown) of heat-sensitive electron-emitting material. The cathode cup 36 is axially spaced from and within an inverted first grating cup 38 which has a closed end provided with a central opening, which is aligned with the adjacent closed end of the cathode cup 36. The closed end of the inverted first grid cup 38 is a small distance from and centered 8500895-6-9 «

a

a closed end of a vertical second grid cup 42 arranged with a central opening. At a distance from the opposite open end of the second grating cup 42 is a central aperture, closed end <5 of an elongated focusing cup 46.

The opposite open end of the focusing cup. b6 forms the exit end portion of the electron gun 30, from which an electron beam 40 is directed axially to the opposite end portions of the envelope 2b. The respective beam-forming electrodes 38, 42 and b6 of the electron gun 30 are insulatively attached to one another by, for example, being firmly attached to a plurality of axially extending dielectric rods 34 which are angled spaced about the electron gun 30. Furthermore, the sub-assembly 15 of beam-forming electrodes 38, 42 and 46 may be held substantially on the axial centerline 25 by a plurality of axially spaced collars 44 surrounding electrodes of the electron gun 30 and against pressing the inner surface of the neck end portion 26, The neck end portion 26 is integrally connected to a larger diameter opposite end portion 50 of the casing 24 through an intermediate outwardly flared portion 52 thereof. The larger diameter end portion 50 terminates in a circumferentially sealed face plate 54 which is substantially perpendicular to the axial centerline 25 of the tube 22 and is made of a transparent material such as, for example, glass. By conventional means, an output display screen 60 is provided on the inner surface of the face plate 54, which comprises a layer of phosphor material which locally emits light when the electrons of the beam 40 penetrate through an incremental region of the material.

As indicated more clearly in Fig. 2, the phosphor layer of the display screen 60 and the supporting face plate 54 may be substantially coextensive with each other and have respective conformal rectangular configurations. Furthermore, the phosphor layer of the af-35 display 60 and the face plate 54 can be considered to be divided into four sectors by two mutually perpendicular planes 53 and 55, respectively, which are substantially perpendicular through the 8500895 * λ * - 7, respectively. - Extend thickness thicknesses of the phosphor layer and the front plate. The mutually perpendicular planes 53 and 55 intersect in a central portion 61 of the display screen 6o and define respective quadrant portions 56, 57, 58 and 59 of the phosphor layer. Therefore, the quadrant portions 56, 57, 58 and 59 comprise respective corner portions of the rectangular phosphor layer, which have substantially equal surfaces compared to each other and are grouped symmetrically about the center portion 61 of the display screen 60.

The first quadrant portion 56 may consist of a suitable phosphorus material, such as, for example, europium-activated yttrium oxide, which locally emits red light in response to electron incidence of the beam k0. Furthermore, the second quadrant portion 57 can be made of another phosphor material, such as, for example, manganese activated zinc silicate, which locally emits green light in response to incident electrons from the beam. Furthermore, the third quadrant portion 58 may be made of yet another phosphor material, such as, for example, silver-activated zinc sulfide, which emits local blue light when electrons of the beam pass through an incremental region thereof. Furthermore, the fourth kva-20 moiety portion 59 may consist of yet another phosphor material, such as, for example, terbium-activated yttrium oxysulfide, which is local blue light of a larger wavelength band than that emitted by the phosphor material of the quadrant portion 58, in response on incident electrons of the beam 40.

The fourth quadrant portion 59 may also consist of a suitable phosphor material with a persistence characteristic which differs substantially from that of the phosphor materials of the other three quadrants 56, 57 and 58, respectively. As another alternative, the fourth quadrant portion 59 of the screen 60 may be not use at all as most colors perceived by the eye can be obtained by the primary colors red, green and blue emitted by the respective phosphor materials of the quadrant portions 56, 57 and 58 , to combine.

On the inner surface of the display screen 60 is an anode coating 62 of electrically conductive material, such as, for example, aluminum, which reflects visible light. The coating 62 extends not only over the entire inner surface of the end portion 50 with 8500895 *. A * - 8 - larger diameter, but also in axial direction as well as a ring in the flared portion 52 of the casing 22. The anode coating 62 is electrically connected to an anode connection button 6b, which is hermetically sealed by the wall of the flared portion 52 extends to establish an electrical connection to the anode of the tube 22.

The anode terminal button 6b and the anode liner 62 are electrically connected by an anode liner 66 which extends from the button 6b to the neck end portion 26 of the shell 2b. Coating 66 consists of a suitable electrically conductive material, such as, for example, carbon, which extends axially and in a ring along the inclined inner surface of the flared portion 52 and into the neck end portion 26. In the neck end portion 26, the anode cladding 66 terminates at a distance from the exit end portion of the electron gun 30 from which the axially oriented electron beam "0" exits, and surrounds this end portion. Thus, the respective anode linings 66 and 62 form a generally inverted cup-shaped anode, in which there is a substantially field-free space.

During operation, as indicated schematically in Fig. 1, the cathode 36 of the electrode gun 30 can be electrically connected via a conductor 68 to a cathode voltage terminal of a polarized voltage source T0. The grid electrode 38 of the electron gun 30 may be electrically connected through a conductor 72 to a voltage terminal of the source T0, which is electrically negative with respect to the cathode voltage terminal to reduce the flow of electrons in the beam h-. 0. The second grid electrode b2 of the electron gun 30 may be electrically connected through a respective conductor 7 * + to an associated voltage terminal of the source 70, which is more positive relative to the cathode voltage terminal; and the focusing electrode b6 of the electron gun 30 may be electrically connected through a respective conductor 76 to an associated voltage terminal of the source 70, which is even more positive with respect to the cathode voltage terminal of the source 70. The anode terminal button 6b may be electrically connected via a conductor 78 to an anode voltage terminal of the source 70, which is strongly electrically positive with respect to the cathode voltage terminal of the source 70. Therefore, the respective beams forming 8500895-9 electrodes 38, h2, h of the electron gun 30 and the corona-shaped anode of the tube 22 are held at suitable electrical potentials relative to the potential of the cathode 36 to focus the electrons of the beam ho to a small spot region of the display 60 5 to provide a localized visible light emission from a permeated, incremental region of phosphor material in one of the respective quadrant portions 56, 57, 58 and * 59 of the screen 60.

A beam alignment system 80 includes beam couplers, provided with an electromagnetic yoke 82, which surrounds the outer surface of the neck-end portion 26 at the flared portion 52 of the envelope 2h such that the electron beam emerging from the electron gun 30 passes the yoke 82. The yoke 82 includes electromagnetic beam deflectors, comprising an opposing pair of interconnected vertical deflection coils (not shown), which are energized about the electron beam 40 in opposite vertical directions from the plane 53, as indicated by the respective collinear vertical vectors 63 and 65 to deflect. The vertical deflection coils of the yoke 82 are electrically connected via a conductor 82a to a conventional vertical deflection amplifier 85, which receives signals via a conductor 75 from a composite grid generator 86.

The composite frame generator 86 receives, through respective conductors 71a and 71b, drive signals from conventional synchronizing signal means 88, which comprise one component of a control signal source 86.

The yoke 82 also includes an opposing pair of interconnected horizontal deflection coils (not shown) which are energized to deflect the electron beam ko with opposite horizontal directions to the plane 55 (FIG. 2} as indicated by the respective collinear horizontal vectors 67 and 69, each of which is substantially perpendicular to the respective vertical vector lines 63 and 65. The horizontal deflection coils of the yoke 82 are electrically connected via a conductor 81b to a conventional horizontal deflection amplifier 83, which is via a conductor 77 receives signals from the composite frame generator 86. The composite frame generator 86 also receives, via an electrical conductor 69, signals from conventional video signal devices 89, which include another component of the control signal source 87. The composite frame generator 86 outputs signals through 8500895 - 10 - an electrical conductor 194 to video amplifier means 8 4, which serve to supply corresponding signals via the conductor 72 to the control grid electrode 38 of the tube 22.

As shown in Fig. 9, in the composite raster-5 generator 86, the output of the synchronizing signal members 88 is electrically connected via conductors 71a and 71b to input terminals of conventional, respective vertical and horizontal time base generators 90 and 92. Furthermore, the conductor 71a is connected to an input terminal of a two-dividing counter 94, which includes a drive output terminal connected to an input terminal of another two-dividing counter 98. In connection therewith, at the input of the generator 90, a clock-like drive signal is applied to the input of the counter 94 as well. As shown in Fig. 10A, the driving signal from the synchronizing signal members 88 may be represented by a waveform 91 of substantially non-uniform clock pulses 93 extending positively from a time-related baseline 91a and spaced at regular intervals, ie, occur in substantially equal periods. The repetition frequency of the clock pulses 93 is substantially equal to the desired vertical scan frequency for each of the respective quadrant portions 56, 57, 58 and 59 of the display 60.

Vertical time base generator 90 applies a vertical scan voltage signal to its output terminal, which, as indicated in Fig. 10B, can be represented by a positive sawtooth waveform. 95 with a period substantially equal to that of the waveform 91 shown in FIG. 10A. The output of the vertical time base generator 90 is electrically connected across two parallel, resistive elements of respective potentiometers 98 and 99 in a vertical control unit 97. The potentiometers 98 and 99 control the vertical size of areas transmitted by the electron beam 40 to the respective quadrant portions 56, 57, 58 and 59 of the display 60 are scanned. From the potentiometer 98, the grounded end of the associated resistive element is connected via a resistor 100 to an inverting (-) input terminal of an amplifier 102, 35 which is connected via a other resistor 103 is connected to the output of amplifier 102. Likewise, of the potentiometer 99, the grounded end of its resistive element is connected via a resistor 8500895 - 11 - 101 to an inverting (-) input terminal of amplifier 104, which is connected to the output of the amplifier via another resistor 105. amplifier 104 is connected.

Of the amplifier 102, the non-inverting (+) input terminal 5 is connected through a resistor 106 to the sliding contact of the vertical dimension control potentiometer 98 and through a resistor 107 to a sliding contact of a vertical jpsitic adjustment potentiometer 109. In contrast to the amplifier 102 ' however, the amplifier 104's non-inverting (+) input terminal is connected to electrical ground through a resistor 109. The inverting (-) input terminal of the amplifier 104 is connected across a resistor 110 to the sliding contact of the vertical dimension control potentiometer 99 and across a resistor 111 to the sliding contact of a vertical position control potentiometer 112. About the resistive elements of the respective vertical position control potentiometer-15 meters 108 and 112, the same value of the polarized voltage may be applied, or different values of polarized voltages may be applied across each of the resistive elements, if desired. The potentiometers 108 and 112 provide means for vertically positioning the colored images formed in the respective quadrant portions 58, 57 * 58 and 59 of the display 60 so that they can be optically superimposed to display a single multi-color image .

Therefore, the amplifier 102 is connected to generate a vertical scan voltage signal at its output terminal which has the same polarity as the combined voltage input signals received at its non-inverting (+) input terminal from the vertical size control potentiometer 98 and the vertical position control po - tentiometer 108. On the other hand, the potentiometer 10U is connected such that a vertical scanning voltage signal 30 occurs at its output terminal, the polarity of which is opposite to that of the combined input signals received at its inverting (-) terminal from the vertical input terminal. dimension control potentiometer 99 and the vertical position control potentiometer 112. The amplifiers 102 and 104 may be of the dual solid state operating type, such as, for example, OP AMP MC 17 ^ 7, marketed by Motorola Semiconduc. tor Products of Phoenix, Arizone,

The horizontal time base generator 92 supplies a horizontal scan voltage signal to its output terminal 8500895-12, which, as indicated in FIG. 10H, can be represented by respective sawtooth sequences 17¾ and 185, each having a period suitable for one. of the respective quadrant portions 56, 57, 58 and 59 of the display screen 60 once. The output of the horizontal time base generator 92 is connected to a conductor 73, which is connected to electrical ground through two parallel resistive elements of respective potentiometers 114 and 115 in a horizontal control unit 116. Potentiometers 11¾ and 115 control the horizontal dimension of regions, which are scanned by the electron beam Uo at the quadrant parts 56, 57, 58 and 59 respectively of the image sharp 60. The grounded end of the resistive element of the potentiometer 11¾ is connected via a resistor 118 to an inverting (-) input terminal of the amplifier 120, which is connected to the output of the amplifier 120 via another resistor 123. Similarly, of the potentiometer 115, the grounded end of its resistive element is connected through a resistor 121 to an inverting (-) input terminal of an amplifier 122, which is connected to the output of amplifier 122 through another resistor 125.

Of the amplifier 120, the non-inverting (+) input terminal is connected via a resistor 126 to the sliding contact of the horizontal dimension control potentiometer 11¾ and via a resistor 127 to a sliding contact of a horizontal position control potentiometer 128. However, unlike the amplifier 120, amplifier 122 connects the non-inverting (+) input terminal to electrical ground through a resistor 129. The inverting (-) input terminal of the amplifier 122 is connected across a resistor 130 to the sliding contact of the horizontal dimension control potentiometer 115 and through a resistor 131 to the sliding contact of a horizontal position control potentiometer 132. 30 About the resistive elements of the horizontal position control potentiometers 128 132, respectively, the same value of the polarized voltage may be applied, but different values of polarized voltages may be applied across each of the resistive elements, if desired. The potentiometers 128 and 132 provide means for horizontally positioning images formed in the respective quadrant portions 56, 57, 58 and 59 of the display 60 so that they can be optically superimposed for 8500895-13. displaying a single multi-color image.

Therefore, the amplifier 120 is connected such that a horizontal scan voltage signal having its same polarity as the combined voltage input signals received at its non-inverting (+) input terminal from its horizontal size control potentiometer 114 and its output voltage is applied to its output terminal. horizontal position control potentiometer 128. On the other hand, the amplifier 122 is connected so that a horizontal scan voltage signal occurs at its output terminal, the polarity of which is opposite to that of the combined input signals received at its inverting (-) input terminal from the horizontal dimension control potentiometer 115 and horizontal position control potentiometer 132. Amplifiers 120 and 122 may also be of the dual solid state operation type, such as, for example, OP AMP MC 1747, marketed by Motorola Zemiconductor Products of Phoenix, Arizona.

The output terminals of the non-inverting amplifier 102 and the inverting amplifier 104 in the vertical control unit 97 are connected via respective conductors 143 and 135 to movable arm contact elements of respective vertical sensing switching devices 142 and 143 in a switching unit 140. Furthermore, the inverting amplifier 120 and inverting amplifier 122 in the horizontal control unit 116, the output terminals connected to movable lean ignition element and respective horizontal sensing switches 144 and 145 in the switching unit 140 via respective conductors 136 and 137.

Of the vertical sensing switching devices 142 and 143, the switching operating elements are connected via respective conductors 146 and 147 to respective output terminals of the two dividing counter 94, which is driven by the clock-like signal from the synchronizing signal members 88. In addition, from the horizontal Sensing switching devices 144 and 145, the switching operating elements are connected via respective conductors 148 and 149 to respective output terminals of the other by two dividing counter 96, which is driven by output signals from the counter 94. Of the switching devices 142 and 143, the stationary contact elements are jointly connected with a vertical scanning output conductor 151 · Furthermore, of the switching devices 144 and 145, the stationary contact elements are jointly connected to a horizontal scanning output conductor 152.

__Λ 8500895 - 14 -

Therefore, the counter 94 supplies the output conductors 146 and 1 UT with respective voltage signals, which, as indicated in FIG. 10C, can be represented by respective rectangular waveforms 153 and 154. Each of the waveforms 153 and 154 includes regularly occurring positive waveforms. voltage pulses, 155 and 15Tj, respectively, which are separated from each other by intervals having a voltage of zero, 156 and 158, respectively. Furthermore, each of the waveforms 153 and 154 has a respective period which is substantially equal to the period of the periods shown in FIG. 10A clock signal waveform 91. Unlike the clock pulses 93 of waveform 91, each of the positive voltage pulses 155 and 157, as well as each of the intermediate zero voltage intervals, 156 and 158, respectively, has a length or duration substantially equal to an entire period . Therefore, when a clock pulse 93 occurs in the waveform 91 and a corresponding positive voltage pulse 157 occurs in the waveform 154, a zero voltage interval 156 of one period occurs in the waveform 153. On the other hand, when a subsequent clock pulse 93 occurs in the waveform 91 and a corresponding positive voltage pulse 155 occurs in the waveform 153, a zero voltage interval 158 of one period duration occurs in the waveform 154.

Therefore, when the counter 9 ** receives a clock voltage pulse from the synchronizing signal members 88, the counter 94 outputs a corresponding excitation voltage signal from one of the output conductors, such as he example 146, and applies it to the other output conductor 147. On at the end of a period, the counter 94 receives a subsequent clock voltage pulse from the synchronizing signal members 88 and transmits the corresponding excitation voltage signal from the output conductor 147 back to the output conductor 146. By receiving a continuous series of clock voltage pulses from the synchronizing signal members 88 spaced one period apart, counter 94 alternately supplies the corresponding energizing voltage signal in respective one period pulses to each of their respective output conductors 146 and 147 sequentially and repetitively.

Therefore, when the counter 94 supplies an energizing voltage pulse to, for example, the conductor 147, the connected actuating element of the switching device 143 is energized about its movable arm contact element outside of electrical cooperation with the stationary contact element of the switching device 1 ^ 3. to keep. As a result, the connection between the output of the vertical inverting amplifier 10k and the vertical scanning output conductor 151 is broken. At the same time, the counter 9 ^ removes the excitation voltage pulse from the output conductor 1U6, thereby switching off the connected operating element of the switching device 1h2. Therefore, the movable arm contact element of the switching device 1k2 can move in electrical cooperation with its stationary contact element 10 and connect the output of the vertical non-inverting amplifier 102 to the vertical scan output conductor 151. Therefore, the amplified vertical scan voltage generated by the non-inverting amplifier 102 is applied to conductor 151 during one period.

At the end of the period, when the counter 9 ^ removes the energizing voltage signal from the output conductor 1 ^ 7 and applies it to the output conductor 1½, the operating element of the switching device 1 ^ 2 is energized about its movable arm contact element outside of electrical cooperation with the stationary contact element of the device. As a result, the connection between the output of the vertical non-inverting amplifier 102 and the vertical scanning output conductor 151 is broken. At the same time, the operating element of the switching device 11 * 3 is deactivated and the movable lean ignition element of the switching device Ik3 can move in electrical cooperation with its stationary contact element. Therefore, the output of the vertical inverting amplifier 10Oh is connected to the vertical scanning output conductor 151. Therefore, the inverted vertical scan voltage generated by the amplifier 10U is passed over the vertical scan output conductor 151.

Therefore, the counter 91 is driven by the clock voltage signal received from the synchronization signals 88 to supply the corresponding excitation voltage signal alternately to the respective output conductors and 11 * 7. As a result, the vertical switching devices 11 * 2 and 1U3 are turned off every other period to alternately connect the outputs of the respective amplifiers 102 and 1QU to the vertical sensing output conductor 151.

. 8500895 - 16 -

Thus, a conductor vertical scanning voltage signal is applied across conductor 151, which, as shown in FIG. 10F, can be represented by a waveform 166 with a time-related baseline 167 from which alternating non-inverted and inverted vertical scanning voltage pulses 168 and 169, respectively. stretch out.

The non-inverted vertical scan voltage pulses 168 gradually increase from the baseline 16j to a positive peak value and then decrease sharply to the baseline 167. On the other hand, the inverted vertical scan voltage pulses 169 progressively decrease from the base line 167 to a negative peak value and decrease. then sharply up to baseline 1Ö7.

The counter 96, which is driven by output pulses from the counter 9 ^, applies to the output conductors 1U8 and 1 ^ 9 thereof respective voltage signals, which, as indicated in Fig. 10D, can be represented by respective waveforms 159 and 160 with regular positive voltage pulses 161 and 163, respectively, which are separated from each other by zero voltage intervals 162 and 161, respectively. Each of the waveforms 159 and 160 has a respective period, which is substantially equal to double the respective periods of the waveform 91 shown in FIG. 10A, and of the waveforms 153 and 15 ^ 5. shown in Fig. IOC. Thus, each of the pulses 162 and 16k has a length or duration substantially equal to an entire period of the associated waveforms 159 and 160, respectively. In addition, when a positive voltage pulse 163 occurs in the waveform 160, a zero voltage interval 162 with a duration of one period in the waveform 159 at; and when a next positive voltage pulse 161 occurs in the waveform 159, a subsequent zero voltage interval 16k with a duration of one period in the waveform 162 occurs.

Therefore, when the counter 96 receives two consecutive pulses from the counter 9 ^, the counter extracts an excitation voltage signal from one of its output conductors, such as, for example, 1U8, and supplies the excitation voltage signal to the other output conductor, 1-9. Therefore, the operating element of the horizontal switching device 1 is actuated to keep its movable arm contact element out of electrical cooperation with the stationary contact element of the device. Therefore, the connection between the output of the inverting amplifier 122 in the horizontal 8500895 - 17 control unit 116 and the horizontal scanning output conductor 152 is broken. At the same time, the operating element of the horizontal switching device 1kh is switched off, whereby the movable arm contact element can move in electrical cooperation with the stationary contact element of the device. Therefore, the output of the inverting amplifier 120 in the horizontal control unit 116 is connected to the horizontal scan output conductor 152 for a period of double length.

After counter 96 receives two more consecutive pulses from counter 10½, counter 96 takes the excitation voltage signal from output conductor 1U9 and transfers it to output conductor 143. Consequently, the control element of horizontal switching device 1UU is energized to move the movable keep its poor contact element out of electrical cooperation with the stationary contact element of the device. Therefore, the connection between the non-inverting amplifier 120 in the horizontal control unit 116 and the horizontal scan output conductor 152 is broken. At the same time, the operating element of the horizontal switching device-145 is disabled, allowing the movable arm contact element 20 to move in electrical cooperation with the stationary contact element of the device. Therefore, the output of the inverting amplifier 122 in the horizontal control unit 116 is connected to the horizontal scanning output conductor 152 for a period of double length.

Thus, the counter 96 is driven by a series of pulses from the counter 91 to supply a corresponding energizing voltage signal alternately to its output conductors 1U8 and 1U9 for respective double length periods. Consequently, the horizontal switching devices iMt and IU5 are alternately operated to sequentially connect the non-inverting amplifier 120 and the inverting amplifier 122 to the output conductor 152 for repetitive periods of double length. Thus, a horizontal scan signal is applied to the output conductor 152, which, as shown in FIG. 10G, can be represented by a composite horizontal scan waveform 1T0 with a time-related base line 171 from which alternate positive and negative envelopes 172 and 173 extend, respectively. A comparison 8S00895-18 of the composite horizontal scanning waveform ITO of FIG. 10G with the composite vertical scanning waveform 166 of FIG. 10F shows that the positive envelope 172 of the waveform 170 is coextensive with the successive inverted and inverted pulses. 168 and 169 of the waveform 166, respectively. Furthermore, the following negative envelope 173 of the waveform 170 is coextensive with successive non-inverted and inverted pulses 168 and 169, respectively, of the waveform 166. FIG. 1QH shows by an expansion of time related baseline 171 of the waveform 170, shown in FIG. 10G, that each of the positive envelopes 172 comprises a series of positive sawtooth pulses 17 ^ with a period suitable to one of the respective quadrants 56, 57, 58 and 59 of scan the image sharply 60 once. Furthermore, each of the negative envelopes 173 includes a series of negative sawtooth pulses 175 having a polarity opposite to that of the positive sawtooth pulses 17, and a period suitable for one of the respective quadrants 56, 57, 58 and 59 of the scan screen 60 once.

As shown again in FIG. 9, the scan signal conductors 151 and 152 are connected to respective input terminals of a geometry correction module 150. Since the output screen 60 is located on the substantially planar inner surface of the output face plate 52 - and being scanned by the electron beam Uo, which is deflected by electromagnetic means, it may be necessary to include respective corrections in the scanning signals passed through the conductors 152 and 153 for non-linear scanning and distortion in grating patterns, that are scanned on the respective quadrant portions 56, 57, 58 and 59.

The geometry correction module 150 may be of the type, such as, for example, IITROIICS ClOU, which is marketed by Intertronics of Newton, Massachusetts, which is used for the smooth synthetic construction of a correction function, which closely matches an accurate mathematical correction function. approaches. Thus, the geometry correction module 150 includes linearity compensation means for eliminating any cushion distortion or the like, which may occur in a non-uniform image-to-image fashion in the images sequentially in the respective quadrant portions of the image. the display 60 are formed. The geometry correction module 150 has respective output terminals which are connected across respective conductors 75 and 77 to respective vertical and horizontal deflection amplifiers 85 and 83. The vertical deflection amplifier 85 is via a conductor 81a to the vertical deflection coils of the yoke. 82, and the horizontal deflection amplifier 83 is connected across a conductor 81b to the horizontal deflection coils of the yoke 82.

Therefore, the vertical and horizontal scan signals applied to the respective vertical and horizontal deflection coils of the yoke 82 cause the electron beam kQ to be deflected electromagnetically to, for example, line-by-line 10 predetermined regions of the respective quadrant portions 56 , 57, 58 and 59 scan sequentially. Therefore, as shown in Fig. 3, in the quadrant portions 56, 57, 58 and 59 of the display 60, respective exposed grating regions 176, 177, 178 and 179 can be obtained, each of which is determined by the distinctive colored light, which is locally is emitted from increments of the associated phosphor material through which electrons penetrate. Therefore, red light is emitted from the grating region 176. Green light is emitted from the grating region 177, and blue light with relatively smaller and larger wavelength bands, respectively, is emitted from the grating regions 178 and 179. The persistence of the light emitted from the respective phosphor materials and the refresh rate of the diffracted electron beam Uo relative to the facial persistency help to ensure that the lattice regions 176-179 are simultaneously visible in the respective quadrant portions. 25 to 5.6 - 59 of the screen 60.

In addition, in order to provide symmetrical component images of the same subject at the respective quadrant portions 56 - 59, the vertical and horizontal scan signals cause the electron beam to be deflected in a predetermined manner in each of the grating regions 176 - 179 in a different different way. way. As shown in Fig. 10F, the composite vertical scanning waveform 160 includes a first full sawtooth pulse 168 extending positively from the baseline 167 of the waveform 160, the electron beam Uo being considered to be in plane 53, shown in Fig. 3. Therefore, the grating region 176 of the quadrant portion 56 is scanned in the vertical direction by the electron beam U0, which is scanned from the plane 53 in the direction of the 6500895-20 vertical vector 63. Furthermore, as shown in Fig. 10G, the composite horizontal scan waveform 170 and others include first full envelope 172 extending positively from the baseline 171 of the waveform 170 and having an initial half length simultaneously with the first full sawtooth pulse. 168 of the waveform 166 occurs. The envelope 172, as shown in Figure 10H, includes a repeating array of uniform sawtooth pulses 17 ^ with respective inclined trailing edges extending from a uniform positive maximum value and terminating at the base line 171 of the waveform 170, 10 which can be considered to correspond to the electron beam, which is located in the plane 55 shown in Fig. 3. Therefore, while scanning in the vertical direction in the direction of the vertical vector 63, the grating region 176 is scanned a number of times in the horizontal direction corresponding to the horizontal vector 67. Therefore, since the scanning of the raster region 176 takes place in the conventional manner of reading a sheet of a book, it can suitably serve as a standard by which the scanning of the other raster regions 177-179, respectively, can be illustration can be compared.

As shown in Fig. 10F, after the first full sawtooth pulse 168 has reached a maximum positive value, this pulse decreases rapidly to the baseline 167 of the waveform 166, which corresponds to the return of the electron beam Uo to plane 53 . Another sawtooth pulse 169 extends in a negative direction from the baseline 167 of the waveform 166 and occurs simultaneously with the remaining half-length of the first full envelope 172 in the waveform 170.

Therefore, by referring again to the positive sawtooth pulses 17 ^ shown in FIG. 10H, and to FIG. 3, it is seen that the grating region 177 of the quadrant portion 57 is scanned by the electron beam IJ-O which is in the vertical direction. is bent from the plane 53 in the direction of the vertical vector 65, while the beam is bent a number of times in the horizontal direction corresponding to the horizontal vector 67. Therefore, the grating region 177 is scanned horizontally in the same direction as for the horizontal scanning of the grating region 176, but scanned vertically in a direction opposite to that of the vertical scanning of the grating region 176.

Referring again to FIG. 10F, after the negative tooth pulse 8500895-21 tooth pulse 169 has reached a minimum or nadir value, the pulse rapidly increases back to baseline 167 of waveform 160, corresponding to the signal shown in FIG. 3. depicted face 53 returning from the scanning electron beam 40. Subsequently, in the waveform 160, a second sawtooth pulse 168 occurs, which extends from the base line 167 of the waveform 166 in a positive direction. As a result, the grating region 178 in the quadrant portion 58 is scanned in the vertical direction in that the electron beam UO is deflected from the plane 53 towards the vertical vector 63. Furthermore, as indicated in Fig. 10G, the composite horizontal scanning waveform 170 includes a first full envelope 173 extending from the base line 171 of the waveform 170 in a negative direction and having an initial half length simultaneously with the second sawtooth pulse 168 of the waveform 166 occurs. The envelope 173 includes, as shown in FIG.

10H, a repeating array of uniform sawtooth pulses 175 with respective sloping trailing edges, which extend from uniform negative peak values and terminate at the baseline 171 of the waveform 170, where the electron beam 1 + 0 can be considered to be in the plane 55, shown in FIG. 3. Therefore, while scanning in the vertical direction in the direction of the vertical vector line 63, the grating region 178 is scanned a number of times in the horizontal direction by the electron beam 1 + 0 a number of times to the plane 55 is deflected in the direction of the horizontal vector 69. Therefore, the grating region 178 is scanned vertically in the same direction as in the vertical scanning of the grating region 176, but scanned horizontally in a direction opposite to that of the horizontal scanning of the grating region 176,

As shown in Fig. 10F, after the second sawtooth pulse 168 reaches a positive peak value, the pulse rapidly decreases to the baseline 167 of the waveform 166, which corresponds to the return of the electron beam to the plane 53 shown in Fig. 3. kO. Thereafter, a next sawtooth pulse 169 occurs in the waveform 166, which extends in a negative direction from the baseline 107 of the waveform 166 and occurs simultaneously with the remaining half-length of the first 35 full negative envelope 173 in the waveform 166. Therefore, by referring again to the negative sawtooth pulses 175 shown in Fig. 10H, and to Fig. 3, it appears that the grating region 169 8500895-22 of the quadrant portion 59 is scanned by the electron beam Uo, which is vertical from the plane 53 in the direction of the vertical vector 65, while the beam is deflected a number of times in the horizontal direction of the horizontal vector 69. Therefore, the grating region 169 is scanned vertically and horizontally in directions which are respectively reversed from those of the vertical and horizontal scanning of the grating region 176,

Thus, by referring to the respective vertical vectors 63 and 65, it appears that all raster regions 176 - 179 and 10, respectively, are vertically from plane 53 and outwardly from the display 60 to one end or the other end of the opposite ends thereof. scanned. Referring further to the respective horizontal vectors 67 and 69, it appears that all raster regions 176-179 become horizontal respectively from one or the other opposite sides of the display 60 and inwardly thereto the plane 55. scanned. Therefore, all grating regions 176-179 are grouped symmetrically about the neutral portion Ö1 of the display 60, respectively, where the respective surfaces 53 and 55 intersect. In addition, the respective grating regions 177 and 179 are scanned inverse in the vertical direction from the plane 53 compared to the vertical scanning of the grating regions 176 and 178, respectively. Furthermore, the respective grating regions 178 and 179 are scanned inverse in the horizontal direction to the plane 55 compared to the horizontal scanning of the grating regions 176 and 177, respectively. Therefore, each of the respective grating areas 176-179 is scanned in at least one direction, which is inverse compared to the directions in which the other three grating areas are scanned.

As shown in FIG. 9, the output conductors 1B and 1U7 of the counter 9 ^, in addition to being connected to the operating elements of the respective vertical switching devices 1 ^ 2 and 1 ^ 3, are also connected to respective input terminals of a conventional decoder 180. In addition, the output conductors 1h8 - 1 ^ 9 of counter 96, in addition to being connected to the operating elements of respective horizontal switching devices 1hh and 1 ^ 5, are also connected to respective input terminals of the decoder 180. The decoder 180 has four output terminals electrically connected to control elements of brightness control switches 186, 187, 188 and 189, respectively, via respective conductors 182, 183, 184 and 185. The brightness control switching devices 186, 186, 188 and 189 have respective stationary contact elements which are jointly connected via the conductor 194 to the video amplifier members 84, the output of which is connected via the conductor 72 to the control grid 38 of the tube 22. The movable arm contact elements of the switching devices 186, 187, 188 and 189 are electrically connected via respective conductors to sliding contacts of brightness control legs 10, diameters 190, 191, 192 and 193, respectively. Of resistive elements of the brightness control potentiometers 190 - 193, respective corresponding end portions are common via the conductor 79 is connected to the output of the video signal members 89 in the control signal source 87. Furthermore, of the resistive elements of the brightness control potentiometers 190 to 193, the respective opposite end portions are jointly connected to electrical ground via a conductor 195.

Therefore, the decoder 180 serves to determine at its input terminals when excitation voltage signals are taken from combinations of the respective conductors 146-149 to close an associated combination of the vertical and horizontal sensing switches 142-143 and 144-145, respectively. . Consequently, the decoder 180 is operated to simultaneously remove an excitation voltage signal from a respective conductor of its output conductors 182 - 185 to close an associated device of the brightness control switches 186 - 189, respectively. Therefore, when a suitable combination of vertical and horizontal scanning signals is passed over the respective output conductors 151 and 152 to scan a certain area of the raster regions 176 - 179, respectively, a corresponding brightness control signal is sent to the video amplifier signals 84 via the output conductor 194. supplied.

Therefore, the decoder 18Ο applies to its output conductors 182 - 185 respective voltage signals, which, as indicated in FIG. 10E, can be represented by waveforms 196 - 199, respectively. By waveforms in FIG. 10C, 10D and 10E. It can be compared that a voltage voltage interval 200 with a 8500895 - 2k duration of one period in the waveform 196 simultaneously with the first full zero voltage interval 156 in the waveform 153 and with an initial half length of the first full zero voltage interval 100 in the waveform 159 occurs. Furthermore, a sequential zero voltage interval 201 of a period of time in the waveform 197 coincides with a first full zero voltage interval 158 in the waveform 15 and with the remaining half-length of the auxiliary voltage interval 153 in the waveform 159. In addition, a further sequential zero voltage interval 202 of one period duration in waveform 198 coincides with a second zero voltage interval 156 in waveform 153 and an initial half of a first full zero voltage interval 16U in waveform 160. Then, yet another sequential zero voltage interval 203 of a period in the waveform 199 coincides with a second zero voltage interval 158 in the waveform 15 ^ sn the remaining 15 half length of the zero voltage interval 16 ^ in the waveform 160.

At the end of the zero voltage interval 203 of the waveform 199, again a zero voltage interval 200 of one period duration in the waveform 199 coincides with a third zero voltage interval 156 in the waveform 153 and an initial half length of the second zero voltage interval 162, which is the waveform 159 occurs, op. Therefore, the sequential occurrence of zero voltage intervals 200, 201, 202 and 203 in the respective waveforms 196, 197, 198 and 199 is repeated continuously during the scanning of the respective grating regions 176-179.

Furthermore, by comparing the waveforms of FIGS. 10E, 10F and 10G with each other, it appears that the zero voltage interval 200 in the waveform 196 occurs simultaneously with the first full sawtooth pulse 168 in the composite vertical scan waveform 166 and the initial half-length of the first full envelope 172 in the composite horizontal scan waveform 170. In addition, the zero voltage interval 201 in the waveform 197 occurs simultaneously with the first full saw tooth pulse 169 in the composite vertical scan waveform 166 and the remaining half-length of the first full envelope 172 in the composite horizontal scanning waveform 1T0. Furthermore, the zero voltage interval 202 in the waveform 198 coincides with the second full sawtooth pulse 168 in the composite vertical scan waveform 166 and the initial half length of the first full envelope 173 in the composite horizontal scan waveform 170. In addition, the zero 8500895-25 voltage interval 203 in the waveform 199 simultaneously with the second full sawtooth pulse 169 in the composite vertical scan waveform 166 and the remaining half-length of the first full envelope 173 in the composite norizontal scan waveform 170.

Therefore, with reference to FIG. 9, when the respective vertical and horizontal scan switches 142 and 1 44 are closed during scanning of the raster region 176, the brightness control switch 186 is closed simultaneously, so that the setting of the potentiometer 190 is the mean brightness level of 10 controls the red light emitted from the grating region 176. When the respective vertical and horizontal scan switches 143 and 144 are closed for scanning the raster region 177, the brightness control switch 187 is also closed simultaneously, so that the adjustment of the potentiometer 191 controls the average brightness level 15 of the green light emitted from the raster region 177.

Furthermore, when the respective vertical and horizontal scanning switches 142 and 14? for scanning the raster region 178, the brightness control switch 188 is closed simultaneously, so that the adjustment of the potentiometer 192 controls the average brightness level of the blue light emitted from the raster region 178. Furthermore, when the respective vertical and horizontal scan switches 143 and 145 are closed to scan the raster region 179, the brightness control switch 189 is closed simultaneously, so that the adjustment of the potentiometer 193 emits the average brightness level of the raster region 179. blue light.

Referring to FIG. 9, it is noted that an input video signal from the video signal members 89 in the control signal source 87 can be applied through the conductor 79 to the resistive elements of the respective brightness control potentiometers 190-193. Therefore, instantaneous variations in the input video signal at the sliding contacts of the brightness control potentiometers 190 - 193 are respectively determined and cause corresponding instantaneous variations in the signal applied across the closed arrangement of the respective switching devices 186 - 189 to the common output conductor 194, which is connected to the input of the video amplifier means 84. Therefore, the output signal is amplified with the corresponding 8500895 - 26 - instantaneous variations and supplied through conductor J2 to the control grid 38 of the electron gun 30. The resulting instantaneous variations in the electrical potential of the control grid 38 cause corresponding instantaneous variations in the intensity of the electron beam b0 originating from the electron gun 30. Therefore, when the electron beam 1 + 0 scans a certain region of the respective grating regions 176 - 179, the average intensity of the beam 1 + 0 is controlled by the adjustment of the corresponding potentiometer of the brightness control potentiometers 190 - 193, respectively, while the instantaneous Intensity of the beam 1 + 0 is controlled by instantaneous variations in the corresponding parts of the input video signal carrying information.

Therefore, as indicated in Fig. 3, when the electron beam 1 + 0 scans the grating region 176, the instantaneous intensity of the beam 1 + 0 can be varied to provide respective alphanumeric symbols 20 +, 205, 206 and 207 in the grating region 178. . The 20l + symbol represents an all-red R portion of a subject to be displayed; and the symbol 205 represents a red component of a yellow Y portion of the subject. Similarly, the symbol 206 20 represents a red component of a white W portion of the subject; and the symbol 207 represents a red component of a purple P portion of it. subject for. In addition, when the electron beam 1 + O scans the grating region 177, the instantaneous intensity of the beam 1 + 0 can be varied to provide respective alphanumeric symbols 208, 209 and 210 in the grating region 177. The symbol 208 represents an entirely green G-section of the subject; and the symbol 109 represents a green component of the yellow Y portion of the subject; and the symbol 210 represents a green component of the white W portion of the subject. However, since the grating region 177 is scanned in a vertical direction opposite to that of the vertical scanning of the grating region 176, the respective symbols 208-210 are inverted vertically compared to the respective symbols 20 + + 207. Also vertically, the respective symbols 209 and 210 in the grating region 177 include vertically inverted duplicates 35 of the respective symbols 205 and 207 in the grating region 176.

Furthermore, when the electron beam 1 + 0 scans the grating region 178, the instantaneous intensity of the beam bO can be varied from 8500895-27 to provide respective alphanumeric symbols 212, 213 and 214 in the grating region 178. The symbol 212 represents an entire blauv B portion of the subject; the symbol 213 represents a blue component of the purple P portion of the subject; and the symbol 21U 5 represents a blue component of the white W portion of the subject. Since the grating area 178 is scanned horizontally opposite to the horizontal scanning of the grating area 176, the respective symbols 212 - 21 ^ in the grating area 178 are inverted horizontally compared to the respective symbols 10h - 207 in the grating area 176. Also in the horizontal direction, the respective symbols 213 and 214 in the grid region 178 include mirror images of the respective symbols 297 and 206 in the grid region 178.

Similarly, as the electron beam ^ scans the grating region 179, the instantaneous intensity of the beam 40 can be varied to provide respective alphanumeric symbols 21, 217 and 218 in the grating region 179. The symbol 216 represents the all blue B portion of the subject; the symbol 217 represents the blue component of the purple P portion of the subject; and the symbol 218 represents the blue component of the white W portion 20 of the subject. However, because the grating region 179 is scanned vertically and horizontally in directions opposite to those in the vertical and horizontal scanning of the grating region 176, respectively, the respective symbols 216 - 218 in the grating region 179 are inverted both vertically and horizontally compared to the respective symbols 20U - 207 in the grid region 176. Furthermore, the respective symbols 216 - 218 in the grid region 179 are vertically inverted duplicates of the respective equivalent symbols 212 -2 \ k in the grid region 178. In addition, the symbol 218 is a mirror image of the equivalent symbol 210 in the grid area 177.

Therefore, except that each of the grating regions 176-179 is scanned inversely in at least one direction with the coordinate directions when scanning the other three grating regions, the respective symbols appearing in each of the grating regions 176-179, oriented correspondingly to the respective symbols present in the other three grid regions. Furthermore, each of the grating regions 176-179 is scanned by the electron beam hO in a respective manner relative to the central portion 61 of the display 6θ, resulting in corresponding increments of the grating regions 176-179 in the same sequential sequence and in substantially equal intervals of the scan time are addressed. Therefore, respective symbols common to more than one of the grid regions 176-179 are positioned symmetrically relative to the central portion 61 of the display 60, respectively. Furthermore, symbols unique to one of the respective grid regions 176-179 relative to the central portion 61 of the display 60 are positioned so that corresponding portions of the other three grid regions remain blank. As a result, the display 60 can be optically folded along the lines defined by intersecting the respective faces 53 and 55 to ensure that component duplicate symbols obtained in more than one grating region are congruently superimposed and symbols, which are unique to one grid area, are not located on a symbol of another grid area.

Thus, as shown in FIGS. 1 and 2, the image display system 20 includes a combination optical system 220 disposed outside the tube 22 and optically coupled to the display 60 through the face plate 5. The optical combination system 220 may include a mirror 22b centered with the quadrant portion 56 and having a reflective surface disposed at an acute angle, for example, from 5 ° to the face plate 5, which angle is measured in a left direction from the front plate 5b to the reflecting surface of the mirror 22 ^. The mirror 22b is predominantly reflective to red light as it is emitted by the phosphor material of, for example, the quadrant portion 56. The optical combination system 220 may also include a mirror 225 centered with the quadrant portion 58 and having a reflecting surface , which is arranged relative to the front plate 5b at an acute angle of, for example, U50, which is measured in a left direction from the front plate 5b to the reflecting surface of the mirror 225. Mirror 225 is predominantly reflective of blue light, such as this due to the phosphor material of, for example.

35 quadrant portion 58 is emitted.

The use of the separate mirrors 22b and 225 in the optical combination system 220 may be advantageous when an independent 8500895 r-29 angle adjustment of the mirrors relative to the front plate 54 is required. However, when the optical combination system 220 is designed such that the two mirrors 224 and 225 are positioned at the same acute angle to the front plate 54, the separated mirrors 224 and 225 may be as shown in an alternative embodiment 220a in Figure 4. -6, are replaced by a single mirror 222, which is arranged at the determined acute angle with respect to the front plate 54. The mirror 222 has respective half-sections 224a and 225a, which are centered with the quadrant parts 56 and 58, respectively, and which function in the same manner as the respective separated mirrors 224 and 225. Therefore, the half-section 224a of the mirror 222 is predominant reflective for red light, which is emitted from the grating region 176, and the half portion 225a of the mirror 222 is predominantly reflective for blue light, which is emitted from the grating region 1J8.

The optical combination system 222 may include a dichroic filter 228 disposed substantially coplanar with the portion of the plane 53 between the respective quadrant portions 56 and 57 and oriented substantially perpendicular to the face plate 54. The dichroic filter 228 is predominantly transmissive to red light and predominantly reflective to green light. The combination optical system 220 also includes a filter 229 disposed coplanar with the portion of the plane 53 between the respective quadrant portions 58 and 59 and oriented substantially perpendicular to the face plate 54. The dichroic filter 229 is predominantly transmissive to small wavelength blue light and predominantly reflective to long wavelength blue light.

It is also possible, as indicated with the optical combination system 220a in Figs. 4-6, to replace the separate dichroic filters 30 228 and 229, respectively, with a single filter 226. The filter 226 is arranged substantially coplanar with the plane 53 and in oriented substantially perpendicular to the face plate 54. The filter 226 includes respective half portions 228a and 229a, which operate in the same manner as the respective separated filters 228 and 229. Therefore, the half filter portion 228a is predominantly transmissive to red light and predominantly reflective to green light. Furthermore, the half filter portion 229a is predominantly transmissive for small wavelength blue light - 8500895-30 length and predominantly reflective for long wavelength blue light.

The combination optical system 220 may also include a beam splitter 232 centered with the quadrant portion 57 of the display 60 and disposed relative to the grating region 5 177 at an appropriate acute angle, for example, k5 °, which is opposite to the angle arrangement of the mirror 22k and clockwise from the front plate 5 ^ · is measured. The beam splitter 232, which is predominantly transmissive to red light, is approximately 50% transmissive and 50% reflective to green light, as it is emitted from the phosphor material of, for example, the quadrant portion 57o. The optical combination system 220 may also include a beam splitter 233, which is centered with the quadrant portion 59 of the display 60 and is arranged at a suitable angle of, for example, 5 5 °, which is opposite to the angle arrangement of the mirror 225 and measured in the right direction from the front plate 5½ . The beam splitter 233 is approximately 50% transmissive and 50% reflective for long wavelength blue light as it is emitted from the phosphor material of, for example, the quadrant portion 59, and preferably more transmissive for small wavelength blue light 20 as it is emitted from the phosphor material of, for example, the quadrant portion 58.

As indicated by the optical combination system 220a in Figs. U-6, the separated beam splitters 232 and 233 can also be replaced by a single beam splitter-230, centered with the respective quadrant portions 57 and 59 and below, respectively. the determined suitable angle of, for example, U50 is arranged, which is opposite to the angular arrangement of the single mirror 222 and measured in the right direction from the front plate 5 ^.

The beam splitter 230 includes respective half sections 232a 30 and 233a, which are centered with the respective quadrant sections 57 and 59 and operate in a similar manner to the respective mirrors 232 and 233. Thus, the half beam splitter section 232a is predominantly red light transmissive and approximately 50% transmissive and 50% reflective for green light. In addition, half beam splitting device portion 233a is predominantly transmissive for small wavelength blue light and about 50% transmissive and 50% reflective for long wavelength blue light.

8500895 9 - 31 -

The optical combination system 220 may also include a recovery mirror 2338, which is centered with the beam splitter 232 and disposed at its furthest side in substantially parallel relationship to the face plate. The recovery mirror 238 is predominantly reflective to green light, as emitted, for example, from the phosphor material of the quadrant portion 57 and transmitted through the beam splitter 232. In addition, the optical combination system 220 includes a recovery mirror 239 which is centered with the beam splitter 233 and disposed on its furthest side substantially parallel to the face plate. The recovery mirror 239 is predominantly reflective of blue light, as it is emitted, for example, by the phosphor material of the quadrant portion 59 and transmitted through the beam splitter 233.

It is also possible, as indicated with the optical combination system 220a in Figs. B - 6, to replace the recovery mirrors 238 and 239 with a single recovery mirror 236, which is centered with the respective half sections 332a and 233a of the single beam splitter. 230 and on its furthest sides thereof is arranged substantially parallel to the front plate 51. The beam splitter 236 includes respective half portions 238a and 239a centered with the half portions 232a and 233a, respectively, and operate in a similar manner to the separate respective recovery mirrors 238 and 239. Therefore, the half portion 238a of the recovery mirror is substantially reflective to green light and the half portion 239 of the recovery mirror is substantially reflective to blue light.

Thus, in the optical combination system 220, the optical elements system, including the mirror 22U, the filter 228, and the beam splitter 232, forms a tent-shaped sub-assembly mounted on the face plate 5 such that the filter 228 is an extension of the portion of the the plane 53 between the respective quadrant portions 56 and 57 forms. Furthermore, the mirror 22b and the beam splitting device 232, which are centered with the respective quadrant parts 56 and 57, are oriented such that with the filter 228 they form respective opposite angles of view, which are complements of the angles seen by the mirror. 22b and the beam splitter 232 are formed with the front plate 51, respectively. Furthermore, the system of 8500895 m 5 - 32 optical elements, including the mirror 225, the filter 229 and the beam splitter 233, forms a tent-shaped sub-assembly mounted on the front plate 54 such that the filter 229 is an extension of the portion of the plane 53 between the respective quadrant portions 58 and 5 59. In addition, mirror 225 and beam splitter 233, centered with respective quadrant portions 58 and 59, are oriented to form respective opposite acute angles with filter 229, which are complements of the angles formed by mirror 225, respectively. and the beam splitter 333 10 is formed with the front plate 5¾.

From a rim of the front plate 54 extends a similar tent-shaped sub-frame comprising a mirror 210, a filter 241 and a second mirror 242. The mirror 240 is centered with the ten-shaped sub-frame provided with the mirror 224, the film 15b 228 and the beam splitter 232 and is oriented at an acute angle to the filter 241, which is an extension of the plane 55. Likewise, the second mirror 2k2 is centered with respect to the tent-like sub-assembly, which includes the mirror 225, the filter 229, and the beam splitter 233, and is at an opposite acute angle to the mirror 2k0 relative to the filter 241 oriented. The respective opposite sharp angles formed by the mirrors 240 and 242 with the filter 241 may be complements of the angles formed by the mirrors 2k0 and 2h2 with the adjacent edge of the front plate 54, respectively. The mirror 240 is predominant reflective for red light, green light and light with an intermediate color of the visible light spectrum. The filter 241, which is predominantly transmissive to red light, green light, and the intermediate color light, is predominantly reflective to blue light. The mirror 242, which is predominantly transmissive for red light, green light and the intermediate colored light, is approximately 50 $ transmissive and 50 $ reflective for blue light.

As indicated with the optical combination system 220a in FIG.

4-6, the single mirror 222, the single filter 226, and the single beam splitter 230 also form a tent-shaped subassembly mounted on the front plate 54; that the filter 226 forms an extension of the plane 53. The half mirror portion 224a and the half 8500895 -33 beam splitting portion 232a, centered with the quadrant portions 56 and 57, respectively, are oriented to form respective opposite sharp angles with the half filter portion 228a, which are complements of the angles formed by the half mirror portion 224a and half beam splitting device portion 332a with the front plate 54, respectively. Furthermore, the half mirror portion 225a and the half beam splitting device portion 233a with the half filter portion 229a form respective opposite sharp angles, which are complements of the angles formed by the respective half mirror portion 225a and the half beam splitting device portion 233a with the front plate 54 formed.

From one edge of the front plate 54 extends, as described above, the tent-shaped sub-assembly comprising the first mirror 240, the filter 241 and the beam splitter 2k2. The mirror 240 is centered with the tent-shaped array of optical elements, which includes the half mirror portion 224a, the half filter portion 228a and the half beam splitter portion 232a. Likewise, the beam splitter 242 is centered with the tent-like array of optical elements, which includes the half mirror section 225a, the half filter section 229a, and the half beam splitter section 233a. Furthermore, mirror 240 and beam splitter 242 with filter 241 form respective opposite sharp angles, which may be complements of the angles formed by respective mirror 240 and beam splitter 242 with the adjacent edge of front plate 54. Thus, in the alternative embodiment shown in Figures 4-6, the mirror 240 and the beam splitter 242, as well as the filter 241, operate in a manner corresponding to their respective operation in the embodiment shown in Figure 2.

During operation, red light emitted from the grating region 1j6 of the quadrant portion 56, as indicated, for example, by the red light beam 250 shown in Fig. 4, is reflected by the half mirror portion 224a toward the half filter portion 228a, therefore the red light beam 250 is passed through the half filter 35 portion 228a and the half beam splitter portion 232a to strike the mirror 240. As a result, the red light beam 250 is reflected by the mirror 240 in the direction of the optical axis 245 8500895-3k. propagates through the filter 2 ^ 1 and the beam splitter 2k2 and. Thus, the red light beam 250 passes an exit plane, indicated by 2k6, from the optical combination system 220a to the eye 2bj of an observer located on whether it is the optical axis 52-5.

Therefore, the red light from the grating region 176, as indicated by the ray 250, traverses in the optical combination system 220 from the grating region 176 to the exit plane 2k6 a total optical path, which is equivalent to four times a unit path length 10 "dn, which can be defined as the cent-to-cent distance from adjacent respective quadrant portions 56 - 59. Thus, the observer's eye 2 ^ -7 sees a virtual image of the red rasteroded 176 in a plane, indicated by 2 ^ 8, which is an equivalent optical distance of four times "d" from the exit plane 2b6 of the frame 220. It is further noted that due to the reflections of the red light from the grating region 176 at the half mirror portion 22Ua and the mirror 2b0, the eye 2bj of the observer sees the image of the raster region 176 in the plane 2 ^ 8 as an upright standing image, which has the conventional left-right orientation as it is arranged This is considered for reading, for example, a page of a book.

The green light, which is emitted from the grating region 177 of the quadrant portion 57, as indicated, for example, by the green light beam 252 in FIG. 5, is reflected by the half beam splitter portion 232a about 30% and transmitted by 30%. Therefore, the reflected portion of the green light beam 252 is reflected by the half filter portion 228a to the half beam splitter portion 232a, where about 30% is reflected back to the grating area 177 and 30% via. the half beam splitting device portion 232a in the direction of the mirror 20 is passed. Furthermore, the portion of green light initially transmitted by the half beam splitting device portion 232a is reflected by the half recovery mirror portion 238a to the half beam splitting device portion 232a, where about 30% is directed through this portion toward the grating region 177. transferred and reflected 30% towards the mirror 2 ^ 0. Therefore, the green light striking the mirror 21 + 0, as indicated by the green 8500895 - 35 light beam 252, is reflected by the mirror 240 toward the optical axis 245 to reflect the filter 241 and the beam splitting device 242. run through. As a result, the green light transmitted through the beam splitter 242 passes the exit plane 246 to the eye 247 of the observer.

Therefore, the green light reaching the observer's eye 2kj travels in the optical combination system 220a from the grating region 177 to the exit plane 2k6 a total optical path equivalent to four times the unit path length "d". Thus, the viewer 247 sees a virtual image of the green grating region 177 in the plane 248, which is an equivalent optical distance of four times "d" from the exit plane 246. It is further noted that due to the reflection of the green light at the half beam splitter portion 232a and at the mirror 240, the observer's eye 247 sees the image of the raster region 177 in the plane 248 as an upright and left-to-right image, corresponding to the image of the grating region 176 in the plane 248. Therefore, the images of the grating regions 176 and 177 in the plane 248 appear to be superimposed on the eye 247 of the observer.

Furthermore, the blue light emitted by the grating region 178 of the quadrant portion 58, as shown in FIG.

6 is indicated by the blue light beam 253, reflected by the half mirror portion 225a toward the half filter portion 229a. Therefore, the blue light beam 253 is transmitted through the half filter section 229a and the half beam splitter device section 233a to hit the beam splitter 242. As a result, about 50% of the blue light beam 253 is transferred through the beam splitter 242 and expires from the system. About 50% of the blue light beam 253 is reflected by the beam splitter 242 toward the optical axis 245 and back to the filter 241. Therefore, the portion of the blue light beam 253s becomes that. hits the filter 241, reflected back to the beam splitter 242, where about 50 # is reflected toward the half beam splitter portion 233a and about 50 $ is transferred through the beam splitter 242 and the exit plane 246 to the viewer's eye 247.

Therefore, the portion of the blue light beam 353 8500895 - 36 - from the grating region 177, which reaches the eye 2kj of the observer, traverses in the optical combination system 220a from the grating region 177 to the exit plane 2 * f6 a total optical path length, which is equivalent on four times the unit length "d". Therefore, the eye 2 ** 7 of the 5 observer sees a virtual image of the blue grating region 17Ö in the plane 2 * + 8, located at an equivalent optical distance four times "d" from the exit plane 2 * + 6. Furthermore, it appears that due to the reflections at the mirrors 225a and 2 * + 2, the eye 2 * + 7 of the observer, the image of the grating region 178 ia the plane 2U8 in upright position 10 and oriented in a similar manner to the images of the raster regions 176 and 177, respectively. As a result, the image of the grating region 178 in the plane 2hQ to the viewer's eye 2kj seems to be superimposed on the similarly oriented images of the respective grating regions 176 and 177.

In addition, the blue light emitted from the grating region 179 of the quadrant portion 59, as shown, for example, in Fig. 7 by the blue light beam 25 * +, is reflected for about $ 50 and transmitted for about $ 50 by the half beam splitting device section 233a. Therefore, the reflected portion of the blue light beam 25 * 4- is reflected by the half filter section 229a to the half beam splitter section 233a, where about 50 $ is reflected back to the raster region 179 and 50 $ through the half beam splitter section 233a toward the beam splitter. 2 * + 2 is passed. Furthermore, the transmitted portion of the blue light beam 25 * + is reflected by the half reclaim mirror portion 239a to the half beam splitting device portion 233a, where about $ 50 is transferred via the half beam splitting device portion 232a to the grating region 179 and $ 50 by the half beam splitter portion 233a is reflected in the direction of the beam splitter 2 * + 2. Therefore, with respect to the portions of the blue light beam 25 * + which hit the beam splitter 2b2, about $ 50 is transmitted through the beam splitter 2k2 and is lost to the system, while $ 50 in the direction of the optical axis 2k6 to the filter.2 * + 1 is reflected, The portions of the blue light beam 2 ^ * + that hit the filter 2 * + 1 are reflected back to the beam splitter 3 * + 2, where about 50 $ in the direction of half 8500895 Beam splitter portion 233a is reflected and about 50 # is passed through the beam splitter 242.

Therefore, the portion of the blue light beam 254, which is transmitted through the beam splitting device 2h2 and the exit plane 2h6 to the observer's eye, traverses in the optical combination system 220 from the field region 179 to the exit plane 240 a total optical path, which is equivalent to four times the unit web length "d". Thus, the eye 247 of the observer sees the image of the raster region 179 in the plane 248, which is an equivalent optical distance of four times? Rd, r from the exit plane 246. Further, in connection with the reflections at the half beam splitter, see portion 233a and the beam splitting device 242, the viewer's eye 247 shows the image of the raster region 179 in the plane 248 in an upright position and with the same left-right orientation as in the images 15 of the respective raster regions 176, 177 and 178.

Thus, the eye 247 of the observer, as shown in Fig. 8, sees a single multi-color image 260 comprising an assembly of the superimposed images of the raster regions 176, 177, 178 and 179, respectively. The single image 260 comprises an all-red portion consisting of a red R symbol 262, which corresponds to the all-red R symbol 204 in the grating region 176 shown in FIG. 3. Furthermore, the single image 260 includes an all-green portion, which includes a green G symbol 264, corresponding to the all-green G symbol 208 in the grating region 177 shown in FIG. 3. In addition, the single image 260 includes an all-blue portion, provided with a blue B symbol 266, corresponding to the combination of the blue wavelength and long wavelength B symbols 212 and 216 in the respective grating regions 178 and 179 shown in FIG. 3. Furthermore, the single image 260 includes a yellow Y symbol 268, a purple P symbol 270 and a white 30 W symbol 272, The yellow Y symbol 268 in the image 260 corresponds to the combination and mixing of the red component symbol 205 in the grid area 276 and the green component symbol 209 in the grid region 177 is shown in Fig. 3. Furthermore, the purple P symbol 270 in the image 260 corresponds to the combination and mixing of the red component symbol 35 207 in the grating area 176, the blue component symbol 213 in the grating area 178 and the blue component symbol 217 in the grating area. 179, shown in FIG. 3, Similarly, the white W-8 5 0 ö 8 9 5-38 - symbol 272 in the image 260 corresponds to the combination of the white component symbols 206, 210, 21U and 218 in the respective grating regions 176, 1779, 178 and 179 shown in FIG. 3.

As shown in FIG. 2, mirror 22b, filter 228 and beam splitter 232 operate in a similar manner to half mirror portion 22ba, half filter portion 228a and half beam splitter portion 232a, respectively. Therefore, the red light beam 250 emitted from the grating region 176 is reflected by the mirror 22b to traverse the filter 228 and the beam splitter 232, thereby striking the mirror 20. Torch, the green light beam 252, which is emitted from the grating region 177, is partially reflected by the beam splitter 232 toward the filter 228 and partially transmitted through the beam splitter 232 toward the recovery mirror 238. The portion of the green light beam 252, which hits the filter 228, is reflected back to the beam splitter 232, where the beam is partially reflected toward the grating region 177 and partially transmitted through the beam splitter 232 toward the mirror 200. The portion of the green light beam 252 hitting the recovery mirror 238 is reflected back to the beam splitter 232, where the beam is partially transmitted toward the grating region 177 and partially reflected toward the mirror 2bQ.

As a result, the portions of the red light beam 250 and the green light beam 252, which hit the mirror 2 ^ 0, are reflected in the direction of the optical axis 2 ^ 5 to pass the filter 2 ^ 1 and the beam splitter 2 ^ 2. Therefore, the portions of the red light beam 250 and the green light beam 252, which are transmitted through the beam splitter 2 ^ 2, traverse the exit plane 2b6 to the eye 2bj of the observer located on or near the optical axis 2U5. Therefore, these portions of the red light beam 250 and the green light beam 252 in the optical combination system 220 from the respective grating regions 276 and 177 to the exit plane 2b6 traverse a total optical path equivalent to four times the unit path length "d", therefore the eye 2 ^ 7 of the observer sees respective virtual images of the red grating region 176 and 8500895 - 39 - the green grating region 177 in the plane 248, which is at an equivalent optical distance of four times "d" along the optical axis 245 from the tread 246 is located. Furthermore, due to the described red and green light reflections, the observer's eye 247 sees the 5 virtual images of the red grating region 176 and the green grating region 177 as upright and with the conventional left-right orientation so that they appear to be on top of each other are superimposed and include a single combined image.

Furthermore, as shown in Fig. 2, the mirror 225, the filter 229 and the beam splitter 233 operate in a similar manner to the half mirror portion 225a, the half filter portion 229a and the half beam splitter portion 233a, respectively. Therefore, the blue light beam 253 emitted from the blue grating region 178 is reflected by the mirror 225 to pass the filter 229 and 15 the beam splitter 233 to hit the beam splitter 2h2. Furthermore, the blue light beam 254 emitted from the blue grating region 179 is partially reflected by the beam splitter 233 toward the filter 229 and partially transmitted through the beam splitter 233 toward the recovery mirror 239. The portion of the blue light beam 254 hitting the filter 229 is reflected back to the beam splitter 233, where it is partially reflected toward the grating region 179 and partially transmitted toward the beam splitter 242. The portion of the blue light beam 254 that strikes the fin-back mirror 239 is reflected back to the beam splitter 233, where it is partially transmitted toward the raster region 179 and partially reflected toward the beam splitter 242.

As a result, some portions of the blue light rays 253 and 254, which hit the beam splitter 242, are transmitted through this device and are lost to the system. Other portions of the blue light rays 253 and 25h, respectively, are reflected by the beam splitter 242 to the filter 241, where they are reflected to the beam splitter 242. Some portions of these blue rays reflected back to the beam splitter 242 are reflected toward the 8500895-U0 beam splitter 233, and other portions of these blue rays of light reflected from the filter 2H1 pass through the beam splitter 2 ^ 2. Thus, the portions of the blue rays 253 and 25 ^ passing through the beam splitter 2k2 move through the exit plane 2k6 to the eye 2kj of the observer. Therefore, these portions of the blue light rays 253 and 25 ^ in the optical combination system 220 from the respective grating regions 178 and 179 to the exit plane 2h6 traverse a total optical path equivalent to four times the unit path length 10 "d". Therefore, the eye 2kf of the observer respective virtual images of the blue grating regions 178 and 179 in the plane 2 ^ -8, which is located at an equivalent optical distance of four times, "d" along the optical axis' 2k $ from the exit plane 2U6. of the described reflections of the blue light, the eye of the observer shows the respective virtual images of the blue grid regions 178 and 179 as upright and with the conventional left-right orientation, corresponding to that of the virtual images of the respective grid regions 178 and 179 ·

Therefore, in the optical combination system 220 shown in FIG. 2, the eye 2U7 of the observer sits the four virtual images of the lattice regions 176 r 179 in plane 2bQ as oriented and superimposed in a similar manner. As a result, the eye 2 ^ 7 of the observer sees in the plane 2 ^ 8 a single multi-color image, such as, for example, the image 200 shown in Figure 8. Thus, the single combined image 200 formed by the optical combination system 220 shown in FIG. 2 also has an all-red R portion 2β2, an all-green G portion 26k, and an all-blue B portion 266. The red R portion 262 of the image 260 corresponds to the all-red R portion 20U of the raster region 176 and the green G portion 26b 30 of the image 260 corresponds to the all-green G portion of the raster region. the blue B portion 266 of the image 260 corresponds to the all blue B portions 212 and 216 of the respective grating regions 178 and 179 »

Furthermore, the single combined image 260 formed by the optical combination frame 220 shown in FIG. 2 also has a yellow portion 268, a purple P portion 270 and a white W portion 272. The yellow Y portion. portion 268 of the image 260 corresponds to the combination 8500895 - 1 + 1 - nation and mixing of the red component portion 205 of the grating area 176 and the green component portion 209 of the grating area 177 · The purple P portion 270 of the image 260 corresponds to the combination and mixing of the red component portion 207 of the grating region 176 and the blue component parts 213 and 217 of the respective grating regions 178 and 179. Furthermore, the white W portion 272 of the image 260 corresponds to the combination and mixing the red component portion 206 of the grating area 176, the green component portion 210 of the grating area 177, and the blue component portions 214 and 218 of the respective grating areas 178 and 179

In Fig. 11, another alternative embodiment 220b is shown, which is structurally similar to the alternative embodiment 220a shown in Figs. 4-6 and additionally includes a blauv light recovery mirror 274. The mirror 274 is behind the beam splitter 242. and arranged substantially parallel to the optical axis 21 + 5 to receive the portions of the respective blue light rays 253 and 251+, which are transmitted through the beam splitter 21 + 2, as shown in FIGS. 6 and 7. These portions of the blue light rays 253 and 25 + passing through the beam splitter 202 and alleged to be lost to the optical sync system 220a system, substantially all of them are passed through the recovery mirror 27I + to the beam splitter 21 +2 bounced. Thus, in the beam splitter 21 + 2, the blue light reflected from the recovery mirror 27 * + is partially transmitted through the beam splitter 242 to the half beam splitter portion 233a and partially reflected by the beam splitter 242 toward the optical axis 245. As a result, this portion of the blue light reflected in the direction of the optical axis 245 traverses the exit plane 246 toward the viewer's eye 247.

Therefore, the blue light reflected from the mirror 2Jk and the beam splitter 2h2 to the eye 2bJ travels from the respective grating regions 178 and 179 to the exit plane 35 246 through a total optical path equivalent to four times the unit path length T ' dft. Thus, the eye 247 of the observer virtually sees the images of the blue grating regions 178 and 179 formed by this blue 8500895 -In-plane illumination 2k8-which plane is at an equivalent optical distance of four times. is located along the optical axis 25 from the exit plane 2k6. Furthermore, due to the reflections of blue light through the mirror and the beam splitter 2k2, as described, the associated virtual images of the raster regions 178 and 179, viewed in the plane 2 ^ 8, are oriented in the same manner as the virtual images thereof, which are formed by the blue light reflected from the beam splitter 2h2 and the filter 21l. As a result, the virtual images of the raster regions 178 and 179 obtained by blue light reflected from the mirror 27 ^ and the beam splitter 2 ^ 2 appear superimposed and amplify the virtual images, which are formed by the blue light, which the beam splitter 2k2 and the filter 2ki are reflected. Therefore, using the optical combination system 220b shown in Fig. 11, the viewer's eye 2kj can see a single multi-color image, such as, for example, the image 200 shown in Fig. 8.

Above is described an image display system comprising means for forming a group of three or more component images of a subject, each of which extends symmetrically from a central portion of the group and in at least one aspect relative to the other gang component images are inverted. The described image display system also includes means coupled to the group to combine the three or more component images and provide a single combined image of the subject. Therefore, if the three or more component images are present in respective colors, the resulting single combined image includes a multi-color image of the subject.

Although the cathode ray type image display tube 2 described herein is provided with a rectangular exit face plate, it may as well be provided with an exit face plate of a circular configuration or other suitable or desired configuration. Furthermore, although the face plate 5 is shown as a flat face plate, it may as well have a curvature symmetrical to the four quadrants, in which case the composite virtual image has an identical curvature. Furthermore, although the beam scanning system 80 shown here is of the raster scan type, this system may also be of the beat recording type, provided with members around the contours of desired alphanumeric symbols, vectors and other patterns somewhere in each of the respective quadrants. 56 - 59 without scanning the entire quadrant. Furthermore, although the respective switching devices 142-145 and 186-189 of the composite grid generator circuit shown in FIG. 9 have been described as mechanically operated devices such as, for example, relay switches, they may be of the same type. electronically operated type, such as, for example, DG201 solid state switchgear, which are marketed by Analog Devices of Norwood, Massachusetts.

Although the mirrors and beam splitters in the respective combination optical systems 220, 220a and 220b have been described as plate-type elements, each of the mirrors and beam splitters may also include a suitably coated surface of a right-angle prism. Furthermore, the optical devices in the respective optical combination systems 220, 220a and 220b can be held in place relative to each other and relative to the exit faceplate 54 by filling the intermediate space with an optically clear refractive index matched cement, such as an epoxy resin material, such as is used, for example, for connecting implosion panels to output front plates of image display tubes, to form a rigid system. Furthermore, each of the beam splitters in the respective optical combination systems 220, 220a and 220b may be of the improved plate type, as described in United States Patent Application Serial No. 513,939.

Furthermore, the respective quadrant portions 56, .57, 58 and 59 need not be made from the respective indicated phosphor materials to provide the associated colored light, but may consist of other respective phosphor materials which are the same or different Generate desired colored light. In addition, the system 20 described herein may operate essentially as described, but somewhat less effectively, if the phosphor screen 60 consists of a uniform intimate mixture of phosphor materials which emit light of the four colors described, and if each of the mirrors and beam splitting devices in a more suitable manner have been designed to reflect and / or transmit the particular desired colored light.

In addition, the respective optical combination systems 220, 8500895 - hh - 220a and 220¾ will operate as described if the single display tube 22 is replaced by four image display tubes, the output screens of which are suitable for emitting of associated distinctive colored light and which screens are arranged approximately next to each other coplanar. In four separate tubes, each provided with associated deflectors, their phosphor screens can be simultaneously addressed by respective electron beams, such as in the known manner of the multi-color "flying spot" scan used in television broadcasts, for example. Furthermore, the disclosed display system will operate satisfactorily if other image forming means, such as, for example, matrix-addressed light-emitting diode arrays, replace the image display tube 22 shown in Figure 1.

8500895

Claims (14)

A system characterized by means for forming a group of at least three heights, each inverted in at least one aspect with respect to each other, and means for combining these images. System according to claim 1, characterized in that the images lie in a common plane and are grouped around a part of the plane. System according to claim 2, characterized in that the plane is built up of quadrant parts, of which respective angles adjoin each other at the said part of the surface, and wherein the images are located in respective quadrant parts of the plane. System according to claim 3, characterized in that one of the images has first and second adjacent sides connecting to respective other images of the group. System according to claim 1, characterized in that the images comprise respective component images of a subject. System according to claim 5, characterized in that the component images are present in respective colors. 7. Image display system characterized by means for forming a group of at least three component images of a subject, each of the images being inverted in at least one aspect with respect to another image, and means coupled to the image forming members combine images and form a composite image of the subject. Image display system according to claim 7, characterized in that the image forming means are provided with means for providing each of the images in a respective color. Image display system according to claim 7, characterized in that the image forming members are provided with means for providing the component images in a common surface, the images being located in respective quadrant portions of the surface. 10. Image display system according to claim 9, characterized in that a first of the images is oriented in a first of the quadrant portions in conventional left-to-right and top-down aspects, a second of the images in a second of the quadrant portions 850 08 9 5 9 - k6 - 'is inverse oriented to the left-to-right aspect of the first of the images, and one-third of the images in one-third of the quadrant portions inverse to the above down-aspect of the first of the images is oriented. Image display system according to claim 10, characterized in that the first of the images and the second of the images have corresponding parts of the subject, which are located as mirror images relative to each other. 12. Image display system according to claim 10, characterized in that the first image and the third image have similar parts of the subject, which are spaced apart as vertically inverted duplicates. Image display system according to claim 10, characterized in that a fourth of said images is oriented inverse to the left-to-right aspect and to the top-down axis of the first image in a quarter of the quadrant portions 15. . 1k. Image display system according to claim 13, characterized in that the second image and the fourth image have similar parts of the subject which are spaced apart as vertically inverted duplicates. Image display system according to claim 13, characterized in that the third image and the fourth image have similar parts of the subject, which are located as mirror images relative to each other. An image display system characterized by display members having a phosphor layer having quadrant portions, at least three of which comprise respective phosphor materials for emitting light of respective different colors, imaging members coupled to the display members for the emission of the respective light To excite different colors from the three quadrant portions and to form respective color component images of a subject in the three quadrant portions, each of the component images being inverted in at least one aspect with respect to the other images, and image combination means associated with the display members are coupled to combine the color component images and form a single multi-color image. * Image display system according to claim 16, characterized in that 8500895 - ι * Τ - of the display elements the phosphor layer comprises a fourth quadrant portion, consisting of a phosphor material, which corresponds to the phosphor material of one of the other three quadrant portions for emitting light with a reinforcing color. Image spring display system according to claim 16, characterized in that the image elements are provided with quadrant portion addressing means to address each of the three quadrant portions in a manner inverse in at least one aspect with respect to each of the other quadrant parts is addressed. Image display system according to claim 16, characterized in that the image combination means comprises optical means for directing the light of different colors emitted by the three quadrant sections along equivalent optical paths to an output of the image combination means . 20. Image display system according to claim 19, characterized in that the optical members are provided with light directing means for conveying light rays emitted from the three quadrant parts to the output of the image combining members as originating from a single virtual image in a surface that an optical distance from this output is substantially equal to the equivalent optical paths. 8500895