DE2855731A1 - DEVICE FOR COLOR REPRODUCTION USING AN AUXILIARY MEMORY FOR COLOR INFORMATION - Google Patents

Description

RCA 71,611 / Sch / Vu

RCA Corporation, New York, N.Y. (V.St.A.)

Device for color reproduction using an auxiliary memory for color information

The invention relates to the communication of information in color, in particular on a scanning raster display device, like a television receiver.

The grid of a television receiver is an inexpensive display option for microcomputers, minicomputers, and other similar cheap small control devices when it comes to display is used by point elements stored in a data memory. The luminance signal (which is a The switch-on or switch-off state) is stored in a data memory as a binary variable (bit) which is used for each Point element of the display device has a value 1 or 0. A binary value of the stored information means a point of light or an ON point, and the other binary value a dark or OFF point. If color information is to be displayed, The number of bits to be stored in the memory triples because three information bits are required, namely for each Point element to be displayed for controlling the red, blue or green ray system of the color rendering device. A An example of such an arrangement can be found in US Pat. No. 4,016,544.

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An alternative to storing three bits of information per dot for a color display device is in U.S. Patent 3,624,634 (the applicant also this application) shown. In this circuit the information for the first dot element of each line of the display device and the same color is used for the remainder of the line. For the representation of an alphanumeric Text, where different colors are used for highlighting each line of text, this system gives a satisfactory one Color control without the need for three bits for each dot element of the display device. For other purposes, for example for video games and the like, however, this method is not entirely satisfactory because it does not allow a color change within a line.

A system to which the invention can be applied is used an auxiliary memory that stores fewer bits than the data memory, which stores the luminance information for each point element to be displayed. The color information can be in the course of a Line can be changed so that the impression of complete color control is created. A high resolution is obtained here Luminance signal with a lower resolution color signal. Experience has shown that the eye can experience small color changes Color television display devices cannot resolve, so a lower color resolution is not necessarily a disadvantage is, however, allows considerable cost savings because special devices are not required, which would otherwise be necessary for a high color resolution would be necessary.

Another advantage of the color display system of the invention is that it can be used with only minor modifications in systems designed for black and white display are determined. Only a small amount of additional equipment and storage of the color information is necessary. Another The advantage is that the color information can be changed between the frames of the display to match the active one To correspond to information on the playback device, the bandwidth of the signal being less than that for a

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high color resolution is necessary.

In a method according to the invention, the are on a scanning raster medium Luminance data to be displayed are arranged as a series of dot elements in a plurality of lines. the Color data are provided corresponding to the color of a plurality of adjacent dot elements, the sub-units of shorter length as a complete line.

The invention is explained in more detail below with reference to the accompanying drawings, FIGS. 1 and 2 of which are logic circuits of arrangements represent that are used to implement the invention.

According to FIG. 1, a control device 1 is provided with a data memory 2 and an auxiliary memory 3 via an address line 4 and a data line 5 coupled. The control device 1 can be designed as a microprocessor, minicomputer or sequencer. Its main purpose consists in storing the luminance information for a color television display device in the data memory 2, wherein each bit corresponds to a point element on the display device which has a point pattern arranged in lines of the grid contains. In the auxiliary memory 3, there are information designation blocks entered for the color to be used in the display.

The control unit also supplies a sequence of addresses to the address line 4, which means that both the display data that lead to a Television interface circuit 5 are to be transmitted from the data memory 2, as well as the color information from the auxiliary memory 3 to the three latch circuits 9 to 11 are to be transmitted during playback. Alternatively could a more complex TV interface circuit 5 can also be provided for supplying the address sequence. Will the control circuit together with COSMAC microprocessors (CDP18O2 from RCA Corporation) is used, then the control circuit (COSMAC) supplies the addresses. A fourth latch circuit 12 can be used for optical

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Functions, e.g. for a light rifle in some screen games, to be used.

The TV interface circuit 5 receives a byte (8 bits) of the luminance information from the data memory 2 and shifts the information bit by bit to get a luminance signal in correct time Relation to the usual television sync signals, which are also provided. An example of a suitable TV interface circuit 5 is the CDP1861 video display controller from RCA Corporation. More detailed information on the operation of this Circuitry with COSMAC microprocessors are available from the manufacturer available data sheets, but for the purpose of explaining the invention described here it is only necessary to to know that the luminance information is shifted out of the circuit 5 serially at the correct times, to coincide with their desired position on the television grid. If you use a black and white device, the luminance information is coupled to the video circuit of the viewing device, for example a television receiver or monitor.

If you use a color display device such as a color television receiver, then the luminance information is not coupled to the display device (television receiver), but to a Set of gates, as will be explained in more detail below. The output signals these gate circuits are color signals for the red, Blue and green ray system of the television receiver. These signals can be fed directly to the color amplifiers for each beam system or they can be for each color signals that in turn have the correct phase relationship to the color oscillator's Have receiver, key to a mixer circuit, which generates the composite image signal. If you modulate a carrier, then you can the composite image signal are fed to the antenna connection of the television receiver used as a display device.

Each set of gate circuits that deliver the individual color signals, has two AND gates per color. The AND gates 7 and 8 supply the red signals, the AND gates 17 and 18 the blue signals

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and AND gates 27 and 28 the green signals.

The AND gates 7, 17 and 27 are indicated by the luminance (dot) information controlled by the TV interface circuit 5. The other input signal for AND gates 7, 17 and 27 is the output signal of in each case one of the flip-flops 9 to 11. These flip-flops store the information relating to the color of the display point elements determine if the points are present (i.e. if the luminance information is a binary one (high level) in this example corresponds to. The background color information is provided, for example, by switches in the background color selection circuit 16 set. If the luminance information is a binary zero (low level) in this example, then an inverter 6 generates a high signal, which prepares the AND gates 8, 18 and 28, which then produce a corresponding color signal can deliver when the associated switch of the background selector 16 establishes a connection to a binary one (+ V), whereas the AND gates are blocked when the switch connects to binary zero (ground).

The arrangement shown can display points and background in any of eight colors, i.e. eight possible combinations of three colours. The red, blue and green ray systems of the display device are switched on or off. If you use more bits for each color, then the saturation value can also be set for each color. For example, two bits per color gives four values for the saturation of each color. You would then get 64 possible color combinations. The relevant circuit would then be more complex and required two AND gates per color for the representation of a point and two for the background colors with digital / analog converters (which could be realized through a resistor network) for each set and goals. A multi-valued color saturation is to be regarded as an embodiment of the invention described here, which uses the same working principle makes and is therefore not shown separately.

The output signals of the AND gates for each color are shown in the

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position shown as an OR link. In practice you can Isolation impedances, such as resistors, may be provided. This is also to be regarded as a modification within the inventive concept.

Before describing the operation of the circuit in detail the operation and structure of the memory is explained. The data memory 2 is a common digital memory with a single data input / output connection, which is connected to the data line 15 and with one coupled to the address line 4 Addressing circuit. The address line 4 contains the control lines, which are required for the correct memory operation, such as timing signals and signals from which it can be seen whether the memory is to be read into or out of it.

The auxiliary memory 3 has two address input connections 24 and 25 two data inputs are shown. The data input is coupled to the data line 15 and the data output to a line 14. While the data connections of the data memory 2 can be operated in both directions and in the usual way to the data line are connected, the data connections of the auxiliary memory work 3 in one direction only. Such unidirectional connections are known in the prior art, for example with the 256 χ 4 RAM memory CDP1822 from RCA Corporation. The advantage of using separate data output ports will become clear from the following description of the company. In the auxiliary memory 3 of this example only 3 bits are required per address (or 4 if the lighting system or another function is required).

Two address connections 24 and 25 allow the writing of data in the auxiliary memory 3 at memory locations that are through a Address, and the reading out of the data from the same memory locations, but with an address other than be designated for registered mail. The use of a two-address connection is not necessary for an understanding of the invention required, but it is appropriate for the following reasons.

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As will be explained, the data memory 2 and the. Auxiliary storage 3 during the presentation time by the same set of Address bits addressed. However, the data in the relevant memory locations in the two memories are not the same because the data memory 2 contains luminance information for each point, while the auxiliary memory 3 contains fewer memory locations for the Contains storage of the color block information. Because different information has to be written into the corresponding memory is, the control unit 1 must be able to select that memory 2 or 3 in which the Data on line 15 (at the locations determined by the address on address line 4) are to be stored. One way to do this is to transfer the auxiliary memory to a to address a different address than that of the data memory when data are to be written (an alternative would exist in the supply of control signals which only make the memory addressable in which the data is written should be). Essentially, the address terminal 25 is internally connected to an encoder which is activated by a signal which indicates that writing is to be carried out, and the address terminal 24 is connected to a decoder which is connected by a signal is put into operation, which indicates that a memory readout is to be carried out. The read and write signals are as mentioned, transmitted by means of the address line. The auxiliary storage 3 is shown for storing 4 bits in each memory location, but only three are used for color information required, while the fourth bit for the lighting system has the status of a special request. The storage process for the data memory 2 and the auxiliary memory 3 do not need to be explained in more detail for an understanding of the invention. It should only be noted that the output line 14 of the auxiliary memory 3 is independent of the data line 15.

For the purpose of explanation it is assumed that the The data stored in the data memory 2 consists of eight bits (one byte), so that each memory location of the auxiliary memory 3 has four bits

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and that the active display area on the television grid is a dot pattern with 64 rows of 128 dots each. So must the data memory 2 thus contain 1024 bytes of data (8192 bits). It is also assumed that the color information is given for blocks of eight points wide and four points high. Of the Auxiliary memory 3 therefore only requires 256 storage spaces. For addressing of the 1024 bytes in data memory 2, ten binary address bits are required, but for the 256 color memory locations only eight bits are required to designate an address in auxiliary memory 3. However, the eight-bit address of the color information must specify the storage location of the color data which corresponds to the correct byte addressed in the data memory by ten address bits. This can be done by selecting the appropriate eight out of ten address bits and no address conversion is necessary. With a designation of the ten address bits for the data memory with 2 - 2, the auxiliary memory 3 with the 2 - 2 and the 2-2 bits of the data memory address are addressed, i.e. with the four most significant and the four least significant bits of the Data storage address. So it is clear that the auxiliary memory address a suitable subgroup, that is to say a smaller part, which is the memory address for the data memory 2. Since the the memory address supplied to the data memory 2 runs through from all zeros to all ones, the color addresses change as follows, that every eight-to-four subgroup of the display pattern is the same Coloring information addressed. The auxiliary memory only needs 3/32 (1/8 to count the fourth light system bit) of the volume of the data memory 2.

Arrangements of the subgroups other than color blocks can also be provided. For example, a 16 χ 8 color block would be (i.e. 16 points wide and 8 points high) reduce the color resolution, but still reduce the size of the auxiliary memory required further decrease. In auxiliary memory 3 there would only be 64 storage locations required, which can be addressed by six bits, in the present case these would be the three most significant and the three least significant bit of the data memory address.

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It has been shown how an auxiliary memory is much smaller Size can be used as the data memory for storing the color information with a satisfactory color resolution and can be controlled for the interaction with the brightness data on a color display device. The data store 2 and the TV interface circuit 5 (in addition to the control unit 1) are used to reproduce information by means of black and white television screens used. All that is needed to display color information is the auxiliary memory 3, the interlocking circuits 9 to 11, the background selector switches 16 and the AND gates 7, 8, 17, 18, 27 and 28 can be added without removing the existing ones Device elements and data would have to be changed.

Because the addresses on address line 4 during presentation time occur in sequence, the luminance information from the data memory 2 to the TV interface circuit 5 via the Data line 15, in the present example as an eight-parallel bit, transfer. The luminance information is input in parallel and output bit by bit serially from the interface circuit 5. At the same time, the color information is read out on the line 14 and in the flip-flops 9 to 11 according to the Interface circuit 5 or the control unit 1 coming control signal locked. In the case of a COSMAC control unit, the locking signal according to data sheet CDP1861 (from RCA Corporation) can be the Signal be TPB.

The luminance information output serially from the output of the interface circuit 5 is fed to the AND gates 7, 22 and 17. The luminance information is reversed by means of the inverter 6 and fed to the gate circuits 8, 18 and 28.

The flip-flops 9 to 11 supply color signals for activation the AND gates if a point is to be displayed according to the luminance signal. If no luminance point is to be displayed, then the color is determined by the background selection circuit 16.

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The circuit shown in FIG. 2 is essentially similar in terms of purpose and structure to that of FIG. 1. Accordingly If possible, the labels are chosen to match. It is therefore only a description of the deviations compared to FIG. 1 required for understanding the arrangement according to FIG.

In the circuit according to FIG. 2, the sets include the color information supplying gate circuits three AND gates per color beam system. The AND gates 7, 8 and 22 supply the red signals, the AND gates 17, 18 and 23 the blue signals and the AND gates 26, 27 and 28 the green signals.

The AND gates 7, 17 and 27 are indicated by the luminance (dot) information controlled by the TV interface circuit 5 and the set output signals from a flip-flop 31, which during the active display time is set. The other input signals of the AND gates 7, 17 and 27 are the output signals of the corresponding Flip-flops 8 to 11. These flip-flops store the information which determine the color of the display point elements when the Points are present, i.e. when the luminance information in the present example is a binary one (high level). Corresponding the colors of the dots, if they are not present, are stored in the flip-flops 19 to 21. The background color information is preset in three flip-flops, which belong to the background color selector 16 (background as inactive Depiction).

The arrangement of FIG. 2 can display and blocked points and background (inactive areas) in any of reproduce eight colors, i.e. the eight possible combinations of three colors. The red, blue and green ray systems of the display device are on or off. By adding bits for each color, the saturation level for each can be increased Adjust color. As already mentioned in connection with FIG. 1, four level values for the saturation can be achieved with two bits per color provide any color.

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In Fig. 2, the auxiliary memory 3 is for storing six Bit per memory location, but it can also be replaced by two auxiliary memories, each of which stores the color information for would store the dot rendering and dot lock color using three corresponding bits. The color selection circuit 16 can also be designed as a third auxiliary memory in the can be saved separately, but since the background color does not have to be changed as often, it is directly from the data line 15 is locked. The control device 1 effects the setting of the flip-flop 16 by addressing a fictitious one Storage space, i.e. an address not available in the data memory or in the auxiliary memory. This address is given by means of a Decoder such as an AND gate 29 during a memory write command decoded. During this time, the control unit supplies the background color information selected in the color selection circuit 16 on the data line 15, for example in the last three data lines. As in the case of FIG. 1, the storage process takes place for the data memory 2 and the auxiliary memory 3 for understanding of the invention not to be explained in more detail. It is only important that the data output is independent of the auxiliary memory 3 of the information on the data line 15 is.

For purposes of explanation, it is assumed that the corresponding Storage space of the data memory 2 consists of eight bits (1 byte) of the data stored on each corresponding Storage space of the auxiliary memory 3 stored data six Bits and that the active display area of the television grid is a dot pattern in 64 rows of 128 dots each. Then he has to Data memory contains 2 1024 data bytes (8192 bits). It is assumed that the color information is blocks of eight points wide and four points of height determined. Therefore, the auxiliary storage requires 3 only 256 memory locations. To address the 1024 bytes, ten binary address bits are required for data memory 2 256 color storage locations of the auxiliary memory 3, however, only eight bits to designate a storage location. The eight-bit address of the color information in the auxiliary memory 3 must, however, with the correct,

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in the data memory 2 by ten address bits addressed bytes coincide. If the ten address bits for the data

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memory with 2 - 2, then the auxiliary memory 3 is connected to the output address connection addressed by 2 to 2 and 2 - 2 bits, i.e. with the four most significant and the four least significant bits the data storage address. As in the case of Figure 1, the auxiliary memory address is a suitable subgroup, i.e. a smaller part, of the memory address for data memory 2. Because the Memory address for the data memory 2 runs through the sequence of all zeros to all ones, the color address changes, see above that the address in data memory 2 of each 8x4 subgroup of the Main display pattern, the corresponding color information in the auxiliary memory 3 is addressed. In the case of FIG. 2, the volume is of the auxiliary memory only 3/16 of the volume of the data memory. Other subsets of color blocks can also be specified; for example, a 16 χ 8 color block would be 16 points wide and 8 points high, lower the color resolution, but also reduce the required size of the auxiliary memory. It only 64 memory locations would be necessary in the auxiliary memory, their each is addressed by six bits, which in this case are the three most significant and three least significant bits of the data storage address

If, in the operation of the circuit according to FIG. 2, the addresses on the address line 4 are consecutive during the display time appear, then the luminance information from the data memory 2 in this example in the form of eight parallel bits via the Data line 15 is transmitted to the TV interface circuit 5. the Luminance information enters the interface circuit 5 in parallel and leaves it serially. At the same time the color information read out on line 14 and in flip-flops 9 to 11 and 19 to 21 under the control of one of the interface circuit 5 delivered control signal locked or saved.

The luminance information supplied serially from the output of the interface circuit 5 is the AND gates 7, 22, 17, 23, 27 and

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ur.d 26 supplied. The luminance information is in the inverter
6 reversed and fed to the AND gates 22, 23 and 26. The AND gates 7, 22, 17, 23, 27 and 26 are supplied with the set output signal of a position flip-flop 31 and the AND gates 8, 18 and 28 are supplied with the reset output signal of the flip-flop. The display flip-flop 31 is set for the active display area of the grid.

In the case of a COSMAC control device 21, the clock signal fed to the flip-flop 31 can be a signal TPB, namely a time pulse that occurs at the end of each cycle. An AND gate 30 decodes the status code signals to provide a D input to flip-flop 31 while a DMA cycle is in progress. The DMA cycle is used to generate the display addresses for the data memory 2 and the auxiliary memory 3. Relevant details can be found in the data sheets for the CDP1861 of
RCA Corporation. The flip-flops 9 to 11 and 19 to 21 deliver
the color information during the active display time, whereby the
Flip-flops 9 to 11 provide the color for a point to be reproduced and flip-flops 19 to 21 for a missing point.

In the background part, i.e. for the color outside the active one
Display area (when the flip-flop 31 is reset)
the color is determined by the state of the background selection circuit 16.

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Claims (8)

RCA 71611 / Sch / Vu USSN 864765 dated Dec. 27, 1977 USSN 864764 dated Dec. 27, 1977 RCA Corporation, New York, N.Y. (V.St.A.) Claims A method for the colored display of information on a scanning raster medium , characterized in that in a first step the luminance data are supplied in a form that they are displayed as a pattern of dot elements arranged in a plurality of lines, and in that in a second step the color signals are provided in a form that they represent the color of a plurality of adjacent dot elements which form subsets of a length less than a full line length. 2) Method according to claim 1, characterized in that in the first step the luminance data as binary information, with one bit corresponding to each point element in the reproduction, stored and that the luminance data are sequentially 909828/0948 ORfGINAL INSPECTED are stored, and that in the second step the color data are stored as groups of three bits for each subgroup, with one bit of a group representing the red, blue and green components corresponds to the color of the points of the subgroup, and that the color data from a subgroup simultaneously with the saving of the luminance data corresponding to the point element within the subgroup are stored. 3) The method according to claim 2, characterized in that the provision of background data are provided as further steps, which are to be displayed in the absence of dot elements, and the scanning of the color data as color signals for the Raster scan medium when the luminance data indicates that a dot element is to be displayed, as well as scanning the background data as color signals to the scanning raster medium when the luminance data indicate that no dot element is to be reproduced is. 4) arrangement for performing the method according to claim 3 for the colored display of information on a scanning raster medium, with a control device for the delivery of control signals (television sync signals, etc.) and with a device which provides signals under control of the control signals in a sequence which provides the luminance signals in a form that a pattern is represented by existing and non-existing point elements on the scanning raster medium, characterized in that that a first color selection device (9,10,11) is provided, which under control of the control signals first color signals (at 7, 17 and 27) to determine the color of Groups of adjacent point elements forming a subgroup determine, if the point elements are present, that a second Color selection device (16 in Fig. 1; 19, 20, 21 in Fig. 2) is provided which, under the control of the control signals, supply second color signals (at 8, 18, 28 in Fig. 1; at 22, 23, 26 in Fig. 2), which determine the color of groups of neighboring point elements when the point elements are not present, and that 909826/0948 a logic circuit with gate circuits (7,8,17,18,27.28 in Fig. 1; 7,22,17,23,27,26 in Fig. 2) is provided, which is under control through the signals representing the information to be reproduced, the first color signals pass to the raster scanning medium lets when the dot elements are present and lets the second color signals pass to the raster scanning medium when the dot elements are not available (hidden). 5) Arrangement according to claim 4, characterized by a background color selection device (29,16 in Fig. 2) for supplying (at 8,18,28) alternating color signals, a circuit (30,31) which under the control of the control signals, provides activation signals indicating that an active area of the medium is scanned, and by additional gate circuits (8,18,28) which, in the absence of the activation signals, the alternating color signals couple to raster scanning medium. 6) Arrangement according to claim 5, characterized in that the background color selection device has a memory (16) for the alternating Color signals and an adjuster (29) which, under control of the control signals, selectively those in the Signals stored in memory. T) arrangement according to claim 4 or 5, characterized in that the control signals contain address signals and that the adjuster (16), which, under the control of the control signals, supplies signals in a sequence which contain the information to be displayed represent, a first memory (2) for storing the luminance information corresponding to the displayed Having signals and that the first and second means supplying the first and second color signals have a second memory (3) for storing the first and second signals. 8) arrangement for performing the method according to claim 3, for controlling the color of a raster scan display medium which transfers dot elements from digital storage onto the raster transmits, characterized in that 9Q9826 / Q948 the digital memory contains a data memory (2) which stores binary digits in its memory locations, the luminance information correspond to the respective point elements to be represented that a synchronizing device (1,5) is provided is what sync signals (television sync signals, etc.) generated for the raster scan display medium and that with the Data memory (2) coupled address means (4) for storing out the binary digits from the data storage locations are provided in the correct relationship to the synchronizing signals, and that the auxiliary memory (3) has fewer storage spaces than the data memory (2) and has coloring information at each of its storage locations stores, which indicates the color in which a plurality of neighboring dot elements are reproduced which make up a block of a Height of at least two rows of point elements and a length less than a full line length constitute the synchronizing Address means also to the auxiliary memory for storing out the color information in the correct relation to the synchronizing signals are coupled in that the addressing means further includes a second plurality of addressing signal means for the Auxiliary memory locations from which the color information is to be saved and that the second plurality of address signal means is a suitable subset of the first plurality of address signal means corresponds to that the color selection means (16 in Fig. 1; 19,20,21 in Fig. 2) supplies signals for a background color and that the gate circuits (7,8,17,22,23,26) under control of the luminance information, the color signals from the auxiliary memory to the raster scan display scan through when the luminance signals have a binary value, and scan the signals from the color selector when the luminance information has the other binary value. 909826/0948