SU963080A1 - Information display - Google Patents

Description

(54) DEVICE FOR DISPLAYING INFORMATION

. 1 The invention relates to automation and computer technology and can be used in devices for forming characters on the screen of an electronic tube (CRT). A device dp of displaying symbols on a screen of a cathode-ray tube is known, which contains a selection circuit whose outputs are connected to the character memory inputs, the other inputs of which are connected to the outputs of the distributor connected to the generator, and the outputs are connected to the inputs of the beam coordinate scanning units and to the trigger, The trigger of the illumination trigger is connected to the inputs of the blocks of the coordinate scanning of the beam and to the input of the generator fl. The disadvantage of this device is that all the characters in it are formed from a figured microraster, which limits the range of displayed characters, and consequently, the area where the device is changed. The closest in technical essence to the present invention is a device for displaying information, comprising a memory block connected to a register, a function voltage generator connected to a register, a code-time converter connected to a pulse generator by a register tied to a beam illumination unit, a counter addresses, logic block and pulse former connected to a pulse generator, a transducer which — time, a generator of functional voltages, a memory, a counter of address 1, and a logic A skid unit connected to the memory unit and an address counter connected to the code-time converter and the X2 memory unit. The disadvantage of the known 5UP device is the low speed due to the constant speed of the formation of the symbol vectors regardless of their length. This speed is determined by the time it takes to form a single vector. which, in turn, is limited by the minimum sample time of the code from the memory block. The purpose of the invention is to increase the speed of the device. The delivered circuit is achieved by the fact that in and; a device containing a pulse driver, the outputs of which are connected to the first inputs of a logic unit, an address counter, a memory unit, a generator of functional voltages of the pulse generator, the first and second inputs of the converter code - time, output which is connected to the first inputs of the register of micro-commands, the pulse generator and the second input of the address counter, the output of which is connected to the second input of the memory block, the output of which is connected to the third input of the converter code-time and with the second inputs of the pulse former, the logic block and the microinstructions register, the output of which is connected to the first input of the backlight unit and the second input of the function voltage generator, whose outputs are the outputs of the device, the third input of the logic block is the first input of the device, and the second input of the pulse generator is provided by the second input of the device, a controlled frequency divider and a trigger are additionally introduced, the first input of which is connected to the first inputs of the controlled frequency divider and the gene pulse generator, the second trigger input is connected to the output of the memory unit, and the output is connected to the second inputs of the backlight unit, the controlled frequency divider and the third input of the function voltage generator, the output of the pulse generator is connected to the third input of the controlled frequency divider connected by output to the third input of the pulse shaper. The drawing shows a block diagram of the device. The device contains 1 pulse generator shaper 2 pulses, logic block 3, address counter 4, memory block 5, code-time converter 6, micro-command register 7, function voltage generator 8, beam illumination unit 9, controlled frequency divider 1O, trigger 11. Positions 12-17 designate the codes and outputs of the device. The generator 1 of the control input pulses is connected to the synchronization input 13, the installation input to the input is connected to the input and the zero setting of the controlled frequency divider 10, the converted microprogram address of the symbol, which is used to select information from the memory block 5. The memory block S is designed for 6 code - time, trigger 11, device output 17; the first output of the pulse shaper 2, which is connected to the information output of the logic unit 3 by the second output; the third output is connected to the zero input address of the counter 4 , the fourth output is connected to the polling input of the memory block 5, the FIFTH output is connected to the counting input of the converter 6 code - time, the sixth output is connected to the enable input of the generator 8 functional voltages, the first information input of the logic unit 3 is input 12 of the device, and the second information input is connected to the output of memory block 5, the output of the magic block 3 is connected to the address input of the 4-address counter, which by its output is connected to the address input of memory block 5, the output of which is connected to the information input of the driver 2 impulses, converter 6 code time, register 7 micro-commands and trigger input 11, output converter 6 time code connected to the input of the driver 2 pulses, the counting input of the counter 4 addresses and the recording entry of the register information 7 micro-commands, output cat connected to the information inputs of the generator 8 of the functional voltage and the beam illumination unit 9, the outputs of which are outputs 14-16 of the device, the output of the pulse generator 1 is connected to the first input of the controlled frequency divider 10 connected to the output of the clock pulse generator input 2, the output of the trigger 11 is connected to the control inputs of the generator 8 function-voltage, a beam illumination unit 9, a controlled frequency divider 1O. Pulse generator 1 is designed to form a burst of clock pulses. The pulse former 2 is designed to form the main control signals between the units of the device. Logic block 3 It is a circuit of an information switch from two directions and is intended for switching the Symbol code from the input 12 of the device or the initial start code from the output of memory block 5. Technical implementation of it. can be performed on the elements 2I-OR. The address counter 4 is intended to record a character code or a code to begin and store the calls of the addresses and character codes of the characters. Preprogram 6 code - time is intended for dp of forming signalpun with time intervals proportional to the vector length code. Register 7 of microinstructions is intended for dp recording and storing vector codes for the time of their writing. The generator 8 of functional voltages is designed for forming the voltages of a symbol sweep along the coordinates V and. The beam illumination unit 9 is intended to generate the light signals of the symbol vectors. The controlled frequency divider 1O is designed to change the clock frequency at the input of a frequency of 2 pulses. Its technical implementation can be carried out, for example, on the basis of 133 IE8 microcircuits. A trigger 11 is designed to record and store a sign of the speed of formation of a character. The device works as follows. The command code from the input 12 of the device enters the first input of the predictive unit 3, and from the input 13 of the device impuls synchronization, the start-up generator 1 of impuls is started. From the generator output 1, a sequence of pulses through the control of the 1st divider of frequency U enters the first input of the pulse former 2, which at the first output generates a signal for writing the symbol code through the current bpock 3 to the address counter 4, and at the second output of the address to block 5 the memory ti. The code of the symbol from the output of the address 4 to the first access signal at the output of the memory block 5 generates the code of the initial (intermediate) address of the microprogram of the character, which is stored in the output register of the memory block 5 (not shown). The symbol's microprogram was recorded in the memory block 5 in two arrays. The first array contains codes for the addresses of characters, and the second for codes of their vectors. Each input character code has its own initial address code, which is the code address of the first syshop vector. After sampling the code of the initial address from memory 5, counter 4 of the address is reset to zero by a reset signal from the third output of the driver 2, which at the first output generates a signal to write the starting address code through the logical bpock: to counter 4, and on the second output to the 6nojcy 5 memory. By the code of the starting address from the output of the counter 4 and the second call, the code of the first symbol vector is formed at the output of the memory block 5. The character vector codes contain information on the scanning of the vectors by the X and Y coordinates (b bits), the vector illumination (1 bit), the vector length (3 bits), the symbol generation rate (1 bit in the first symbol vector) , on the end of the formation of a character (1 bit in the last vector). After sampling the code of the first vector of the symbol from the memory block 5, clock pulses begin to come from the fourth output of the formative 2 clock to the first input of the transducer – code – time, which at the initial moment of time generates a vectorout signal (SLE) corresponding to the vector, zero dpina . According to this signal, a 3-digit code for the length of the first vector of the symbol is entered into the code-time converter 6, and a 7-digit scanning code and vector illumination code are entered into the register of 7 micro-commands. At the same time, by this signal, the code of the start address at the output of counter 4 is increased by one junior bit, the next signal of accessing memory block 5 and the enable signal of generator 8 of functional voltages at the fifth output of driver 2 are generated. From the moment the first vector code is written A symbol in the register of 7 microinstructions. A generator of 8 functional voltages generates the sweep voltage of a symbol along the coordinates y and, the illumination block 9 determines the illumination of the CRT beam, and the 6 ks transducer translates into a vector. After the formation of the first vector of the symbol at the output of the converter 6, the code-time is forked by the SCR signal with a time interval proportional to the frequency of clock pulses at the first input and 3 bits to the vector length code at the second input. Similarly, the formation of all subsequent symbol vectors is performed. When forming the last vector of the symbol, its code contains the sign of the end of the symbol, which is fed to the second input of the imaging unit 2 pulses. According to this feature, at the sixth output of the imaging unit 2, a signal for the end of the symbol is generated, with which all devices are located into the zero state. At the same time, this signal arrives at the output 17 of the device for the v13 code of the next character. The time of the formation of symbols in the device proposed depends on the number of vectors in its circuit and the frequency of operation of the code-time converter 6. The number of vectors in the circuit is determined by the required configuration of the symbol, and the frequency of the clock pulses at the input of converter 6, the code-time is set by the controlled Divider 10 frequency based on the sign rate of the symbol formation. The sign of the rate of formation of a symbol in the form of a signal of a logical unit is written (it is in memory block 5 in one of the code bits of the first vector for only those characters that contain unit length vectors in their Contour. 20 By this feature trigger 11 is set the unit state, and at the output of the controlled divider 1O, the frequency of clock pulses is set to be equal to the maximum sampling rate of codes from memory block 5. In the absence of an indication of the rate of symbol generation, the frequency of clock pulses at the output of the control Divisor 10 is doubled, which reduces the symbol formation time by a factor of 2. Sign of the rate of formation of the symbol .c of trigger 11 also goes to the control inputs of the generator 8 functional n-apr and the illumination unit 9 for changing nor the amplitude of the output voltages with the symbol of preserving the size and luminance of the symbol Compared with the known device, the lengths of the vector of symbol vectors are taken into account, the formation rate of which can be increased by 2 times if there are no single ones in their composition. vectors. Therefore, when constructing a figure of a symbol, it is necessary to avoid using single vectors whenever possible (without 4S degrading quality), and thereby reduce the time to form a symbol by 2 times. The effectiveness of the device will increase with a decrease in the number of characters containing vectors. unit length Thus, the use of a predictable device can give a positive effect, consisting in the derivation of up to 08 information by means of a shortened time for the formation of symbols, with containing vector vectors of unit length. A device of the invention for displaying information comprising a pulse driver, the outputs of which are connected to the first inputs of a logic unit, an address counter, a memory unit, a function voltage generator, a pulse generator, the first and second inputs of a code-time converter, the output of which connected to the first inputs of the register of microinstructions, the driver of impulses AND the second BXOJEIOM of the address counter, the output of which is connected to the input of the memory unit, the output of which is connected to the third input of the time converter and with the second inputs of the pulse driver, the logic block and the microinstructor register, the output of which is connected to the first input of the backlight unit and the second input of the function voltage generator, the outputs of which are the device outputs, the third input of the logic unit is the first input of the device, and the second the input of the pulse generator is the second input of the device, which is due to the fact that a controllable frequency divider and a trigger, the first input of which is connected, is inserted into the device with a chain of speed of operation. the first inputs of the control unit Divider: Frequency1 and its generator, the second trigger input is connected to the output unit of the pn unit, and the output is connected to the second inputs of the backlight unit controlled by the frequency divider and the third input of the function voltage generator; the third input of the controlled Frequency Divider, whose outflow is connected to the third input of the pulse former .. Sources of information taken into account in the examination 1, Authors certificate of the USSR No. 343263, cn. Q 06 F 3/14, 1970. 2. USSR author's certificate No. 634322, cl. G 06 K 15 / 2O, 1976. (prototype).

/ 2 sipvol code

Outputs

Claims (1)

Claim A device for displaying information containing a pulse shaper whose outputs are connected to the first inputs of the logic block, address counter, memory block, functional voltage generator, pulse generator, the first 'and second inputs of the code-time converter, the output of which is connected to the first inputs of the micro-command register, the pulse shaper and the second input of the address counter, the output of which is connected to the second input of the memory block, the output of which is connected to the third input of the kOD-time converter and to the second inputs dams of the pulse shaper, the logic block and the register of microcommands, the output of which is connected to the first input of the backlight block and the second input of the functional voltage generator, the outputs of which are the outputs of the device, the third input of the logic block is the first input of the device, and the second input of the pulse generator is the second input of the device, The reason is that, with a speed improvement circuit, a controlled frequency divider and a trigger are introduced into the device, the first input of which is connected to the first inputs of the control frequency divider and pulse generator, the second input of the trigger is connected to the output of the memory unit, and the output is connected to the second inputs of the backlight unit, the controlled frequency divider and the third input of the functional voltage generator, the output of the pulse generator is connected to the third input of the controlled frequency divider, the output of which is connected with the third input of the pulse shaper.