SU1029177A1 - Device for information output onto crt screen - Google Patents

Description

its switch is connected to the input of the memory unit whose output is connected to the inputs of the group code registers, the outputs of which are connected to the inputs of the corresponding linear analog converters of the group, the outputs of the odd group code registers are connected to the inputs of the first switch, the output of which is connected to the first input of the first adder The second input of which is connected to the output of the second switch, the output of the first adder is connected to the first input of the pulse distributor, the second input of which is the third input of the device The first and second inputs of the second switch are connected respectively to the outputs of the first and second coordinate registers, the first input of the radiator is connected to the first input of the second summitter, and the second input of the encoder is connected to the first input of the third adder, the EXIT of the encoder is connected to the control the inputs of the switch groups, the outputs of the first and second linear digital-to-analog converters of the group are connected respectively to the inputs of the first and second inverters, the outputs of which are connected to the first inputs of odd and even numbers group second adders, the second inputs of the first two analog adders of the Group are connected respectively to the outputs of the first and second linear digital-to-analog converters of the group, the second inputs of the last two analog adders of the group are connected respectively to the outputs of the last two linear digital-analog converters of the group, the inputs of the first division block are connected respectively to the outputs of the odd analog adders of the group, and the inputs of the second dividing unit - with the outputs of the even analog adders of the group, with m calculating unit corrections; contains the first, second, third and fourth inverters first, second, third and fourth

adders, first, second and third multiplying units, with the input of the first inverter, the first input of the first sum of the mathor, the input of the second inverter, the first input of the second adder in each correction calculation unit connected to the outputs of the corresponding 4 group switches, the first inputs of the first and

The second multiplication unit of each correction unit is connected to the output of the first division unit, and the first input of the third multiplication unit of each correction unit is connected to the output of the second division unit, the output of the first inverter is connected to the second input of the first adder, the first input of the third adder and the first input of the fourth adder the output of the second inverter is connected to the second input of the second adder, and the input of the third inverter is combined with the first input of the second adder, the outputs of the first and second adders cheny respectively to second inputs of the first and second multiplying units, first multiplying block output connection a second input of the third adder and the input of the fourth inverter, the second multiplying unit output is connected to a third input of the third adder, the output of the third inverter is connected to a fourth input of the third adder, a third adder output

connected to the second input of the third multiplication unit, the output of the fourth inverter is connected to the second input 4eTeeptoro of the adder, the output of the third multiplication unit is connected to the third input of the fourth adder, the outputs of the fourth adders of each correction calculator are connected to the output of the corrector of the corresponding amplifiers, the outputs of the pulse distributor are connected to the control the inputs of the first, second and third switches, the first and second counters, and the memory block.

one

The invention relates to automation and computing and can be used in output devices.

in particular, in microfilming devices and machine decisions in cases where the presentation and coordinate accuracy of the image. A device is known, where the task of correcting coordinate distortions can be solved by converting deflection of sound signals according to a given law tl 3 “However, the formation of astigmatism correction currents with this method n KCA XVAiV tA ,, X + A4Vj-A5Vv), .BjX B4.V - BS X5), where K is a coefficient determined by the construction of a four-pole lens Ajj. the astigmatism coefficients of the deviation of his device (it, 2, ..., 5h is very difficult due to the complexity and duration of the process of determining the coefficients AI and B, both computationally and experimentally. The prototype is a device for controlling the output of information on the screen of the CRT that provides correction of image distortions that occur when electron beams deviate by forming tabular values of dynamic focusing currents and currents to currents1 (and coordinate distortions for the screen, limited defined boundary points. Such a device is an integral part of the output device. J. The device contains input registers in the X and Y coordinates, linear digital-to-analogue converters in the deflection currents, a non-linear digital-to-analogue converter connected to the deflection and focusing circuits, di-diffusers in the control circuits of the digital-to-analog converter and amplifiers in the deflection and focusing circuits. The non-linear digital-to-analog converter in the formation circuits of each of the corrected These control tube signals generate a tabular correction constant for each zone of the screen bounded by certain X and Y coordinates. In addition, an interpolating D / A converter is installed in the horizontal deflection control signal forming circuit of the X coordinate and the bus tabular amendment. The disadvantage of the device is low accuracy, as well as the fact that it does not provide a high resolution (it cnoct HOCTH images generated at different points on the screen. This deficiency is caused by the absence of interpolating blocks in vertical deviations and focus chains, and also the absence of circuits for the formation of control signals for the correction of astigmatism of deviation. Dissemination of the principle adopted in the current generation curve of the deviation along the X axis to other circuits would lead to a significant increase in the number of regulating elements since for each screen area it would be necessary to set not only the value of the tabular correction, but also the value of the correction increment within the zone. The selection of boundary points is accomplished by decoding only the higher bits of the deviation codes, which makes it impossible for the the turn leads to the need to increase their number. The circuit of the invention is the expansion of the field of application of the device by increasing the resolution and accuracy in the output of information. This goal is achieved in that the device containing the first and second coordinate registers, the first and second linear D / A converters, the nonlinear digital-to-analog converter, the decoder group, the first group of amplifiers, the first input of the first coordinate register being the first input of the device, the first input of the second the coordinate register is the second input of the device, the second inputs of the first and second register registers are combined and are the third input of the device, the input of the first linear digital-analogue The first converter is connected to the output of the first coordinate register, and the input of the second linear digital-to-analog converter is connected to the output of the second coordinate register, the outputs of the amplifiers ARE the device outputs, the outputs of the first and second linear digital-analog converters are connected to the coordinate inputs of the first and second amplifiers of the group, respectively, the pulse distributor is entered , first, second and third switches.

rpvvma switches, first, second and third adders, memory block, first and second counters, group of elements And, encoder, group of code registers, group of linear 1x digital / south converters, first and second inverters, group of analog adders, first and second dividing units, a group of correction calculation units, the non-linear digital-to-analog converter contains a group of keys, a matrix of current sources, a second group of amplifiers, and the outputs of the keys are connected to the inputs of current sources of the corresponding ctpoka matrix, and The outputs of the current sources of the matrix row are connected to the inputs of the corresponding amplifiers of the second group, the outputs of which are connected to the inputs of the corresponding switches of the group, and the inputs of the keys, except the first and last, are connected to the outputs of the corresponding AND elements of the group, whose inputs are connected to the outputs of the corresponding decoders of the group, and the input the first and last keys are connected to the corresponding output of the first and last decoders of the group, the inputs of the group decoders are combined with the first, second, third and fourth inputs The third switch, the first input of the second adder and the first input of the third adder, respectively, are connected to the outputs of the first counter, second adder, second counter and third adder, respectively, the second input of the second and second input of the third adder are the fourth and fifth inputs of the device, output the third switch is connected to the input of the memory unit, the output of which is connected to the inputs of registers of the group of codes, the outputs of which are connected to the inputs of the corresponding linear digital-to-analogue group converters, the outputs of the odd group code registers are connected to the inputs of the first switch, the output of which is connected to the first input of the first second input of which is connected to the output of the second switch, the output of the first adder is connected to the first input of the pulse distributor, the second input of which is the third input devices, the first and second inputs of the second switch are connected respectively to the outputs of the first and second registers

coordinates, the first input of the encoder is combined with the first input of the second adder, and the second input of the encoder is connected to the first input of the third adder, the output of the encoder is connected to the control inputs of the group switches, the outputs of the first and second linear digital-analog converters of the group are connected respectively to the inputs of the first and second inverters, the outputs of which are connected to the first inputs of odd and even analog adders, the group, the second inputs of the first two analog adders of the group are connected respectively to the output The first and second linear digital-to-analog converters of the group, the second inputs of the last two analog adders of the group are connected respectively to the outputs of the last two linear digital-analog converters of the group, the inputs of the first division block are connected respectively to the outputs of the odd analog adders of the group, and the inputs of the second division block - with the outputs of even analog adders, with the correction calculation block containing the first, second, third, and fourth inverters, the first, second, third, and fourth su mmators, first, second and third multiplication blocks, while the input of the first inverter, the first input of the first adder, the input of the second inverter, the first input of the second adder in each correction calculation unit are connected to the outputs of the corresponding group switches, the first inputs of the first and second multiplication blocks of each block the computation of corrections is connected to the output of the first division unit, and the first input of the third multiplication unit of each computation unit is connected to the output of the second division unit, the output of the first inverter is connected to the first input of the first adder, the first input of the third adder and the first input of the fourth adder, the output of the second inverter is connected to the second input of the second sum of the matrix, and the input of the third inverter is connected to the first input of the second adder, the outputs of the first and second adders are connected respectively to the second inputs of the first and second the second multiplication unit, the output of the first multiplication unit is connected to the second input of the third adder and the input of the fourth inverter, the output of the second multiplication unit is connected to the third input of the third summation Pa, the output of the third and the inverter is connected to the fourth input of the third adder, the output of the third adder is connected to the second input of the third multiplication unit, the output of the fourth inverter is connected to the second input of the fourth adder, the output of the third multiplication unit is connected to the third input of the fourth adder, the outputs of the fourth adders of each block calculating the corrections from Klume1 1 to the inputs of the corrections of the corresponding amplifiers, the outputs of the distribution of the pulse bodies are connected to the control inputs of the first, second and third switches, first and second counters and memory block. Thus, the formation of control signals for dynamic focusing and correction of deviation astigmatism is performed by summing the tabular component of the signal generated for one of the boundary points of the corresponding screen area and the intraband correction calculated from the values of the tabular component of the signal at the four boundary points of this n. corrections to the linear components of the deflection signals are formed. Increasing the resolution and accuracy of the image is achieved by forming an intra-zone correction for all control signals with regard to the deflection of the beam both vertically and horizontally, and the application of the invention gives a significant advantage compared to solving the problem of qualitative The complexity of the prototype. This is achieved due to the fact that each boundary point corresponds to only one regulating element in the center stage of the formation of each control signal. FIG. Figure 1 shows the layout of the working floor of a CRT screen into zones. The seven horizontal and seven vertical boundary lines are divided into 36 zones. Each zone is bounded by two horizontal and two vertical boundary lines. The points of intersection of the boundary lines are denoted by the letter Z with an index containing information about the numbers of the vertical and horizontal boundary lines. Thus, the designation 72 3 testifies that this point is located at the intersection of the second vertical and third horizontal boundary lines. . Any boundary point, except for the points Z-., Z .. 3L. and - “LJ belongs to several zones. The position of points belonging to several (two or four) adjacent zones in each zone differs from the position in the remaining zones. , taking the Dlezhasche to four adjacent zones, occupies the lower left in one of them, the lower right in the other, the upper left in the third and the upper, right position in the fourth. The principle of calculating the correction from the values of the tabular component of the signal at the four boundary points of the zone of illusion is shown in FIG. 2. Let the arbitrary Point Z be set inside the zone bounded by the points Taking into account that with sufficient accuracy for practical applications “) -V (Z, -, j), j),.,). ) NKdHHO-VitUtJ.ll (., Л 5. / Г ZHJ. - ,, 4...), .Г) -Ik (2:., M 1 I. .-. J (V), - / U ) .U,; j) iM.j. V4i-AV (z. J ,,) correction value in the K channel When the beam is tilted to the point Zjt iffn, j.fCOOTBeTCTBeHHO, to the l path of the deflection current along the X-axis, K, 2 for the channel to form the current of the deflection along the Y-axis 3 for formation channels. Astigmatism correction shafts, K 5 for the channel of formation of the eye of dynamic focusing, .WX, .. CV,. ,, X ,, (V,.,.) l J l y. . Yy ), J41 - H-lij -t coordinates X (Y / corresponding points, as well as the fact that with the orientation of the bottom lines along the coordinate lines this y –y y y 7t t: 7--7. .... HKi .J d +, 1:.. Lj t4l,) 14., J + 1% jf) V ,, kl iz iJ-Jv (Z -) - V U-) -Г X -y. I K, i, Hi, j 1.1 C ,, “44ijilSfv. .- .. Hj .. The correction is calculated in accordance with the expression (2 In Fig. 3 and M is a block diagram of the device. The device contains the input coordinate buses X and Y 1 and 2, the input bus signal tracking information 3, the X coordinate registers and Y 4 and 5, linear digital-to-analog converters in the X and Y coordinate channels 6 and 7 pulse distributor.8, commutators 9–11, counters 12 and 13, sum mator, memory block 17, decoders 18–21, elements 22 30, 3161, 62-68, non-linear digital-to-analog converter b9, switches 70-7, encoder 75, blocks computing nor amendments 76-80, ycills 81-85, focusing system 86, deflecting system 87, electron-beam tube 88, registers of coordinate codes of boundary points 89-92, linear digital-to-analog converters of codes of the coordinates of boundary points 93-96, inverters 97 and 98 , analog adders 99 102, division blocks 103 and 10 A. Non-linear digital-analog converter consists of a group of keys 105, 106-112-113-1 5-1 6-152-153, adjustable current sources 15-388 and amplifiers 389- + 08. The device blocks are connected using tires 409-516. The tire is formed by the union of tires, the tire is formed by the association of tires, the tire is formed by the association of tires, the tire “33 is formed by the association of tires. Tires 90-506 are the tabular control signal components at the first boundary point, tires 91-507 are the control signal tabular component tires at the second boundary point, and tires 92-508 are the control signal tabular components in The third boundary point, tires 93509, are the tires of the tabular components of the control signals at the fourth boundary point. The current sources 159-189 194-3 A, 3 9-379, and 38 are used to form the tabular component of the correction of the X coordinate deviation signal, current sources 155, 160-190 195-3 5, 350-380, 385 (not shown) are intended to form a component of the correction signal of the deviation along the y axis, current sources 156, 161-191-196-3 6, 351-381, 386 are not shown) are intended to form a tabular component of the first deviation astigmatism correction signal, sources 157j 1b21 2 , 197-37, 352-382, 387 (not shown} are intended to form the tabular component of the second corrected signal The astigmatism of the deviation, and the sources 158, 163-193, 198-3 8, 353-383, 388 are designed to form the table component of the focus signal. The sources forming the table component of each of the signals are distributed into four groups (by the Number of boundary points each zone). The sources of each group are connected to one of the four output amplifiers of the digital-to-analog converter. The total number of amplifiers during the formation of the tabular components of the five control signals is 20. The distribution into groups is made in such a way that the current sources corresponding to the four boundary points of any zone belong to different groups. This is done in order to allow the tabular components for all four boundary points to be simultaneously obtained at the output of the nonlinear digital-analogue converter. The distribution of sources into groups is shown in FIG. 5. Sources of the same group are denoted by the same. Latin letters (a, b, c or d). Each boundary point belonging to more than one zone occupies a different one. position in different zones. Thus, the tabular component, the form

depending on the position of the zone, it may correspond to the first, second, third, or fourth boundary point of the zone. For normal operation of the correction block 7b-80, it is necessary that the tabular components for each of the boundary zones arrive at certain inputs of these blocks. In order to ensure that the signals of the tabular constituent signals correspond equally to the inputs of the correction calculation blocks 76-80, the switches 70-7 are installed at the output of the nonlinear digital-to-analogue converter 69. The control of the switches is carried out using the encoder 75 The inputs of the encoder are connected to the outputs of counters 12 and 13. Depending on the states of the counters, i.e. Depending on the position of the zone on the bus 479, a control code is generated, providing four options for connecting the outputs of the blocks 70-7 to their inputs. Capital letters A, B, C, 1} indicate connection options for each of them on the zones. 5. In option A, the first outputs of switches 70-7 are connected to their first inputs connected to amplifiers of group a (), and the second outputs to inputs connected to amplifiers of group 4 (SSO-tOfi), the third outputs from the third inputs are connected to amplifiers of the group with O91-07), and the fourth outputs are from the fourth inputs connected to amplifiers of the group d {392-A08).

In option B, the first outputs of the switches 70-7 are connected to the second inputs, the second outputs to the third inputs, the third outputs to the fourth inputs and the fourth outputs to the first inputs.

In option C, the first outputs of the switches 70-7 are connected to the third inputs, the second outputs to the even inputs, the third outputs to the first inputs and the fourth outputs to the SECOND inputs. ...

In option T, the first outputs of the taps 70-7 are connected to the fourth input, the second outputs to the first inputs, the third outputs to the second inputs and the fourth outputs. entrance entrances.

Thus, on tires (EO, (not shown) - 5П6 always forms, iluv1

Table Cs signal component for the first (lower left boundary point of any zone, on tires 491, 495 not shown) —507 always forms the tabular component of the signal of the second (lower right) boundary point of any zone, on tires 492,496 (not shown) - 508 a tabular component is always formed for the third 1 upper left) boundary point of any zone and finally on tires 493 497 (not shown) - 509 the tabular component for the fourth (upper right) boundary point is always formed

To ensure the simultaneous selection of keys (and, consequently, current sources) of the converter 69 corresponding to all four positive points of a given zone, four (by the number of boundary points of the zone) 18 and 21 diagrams are installed in the circuit.

Since most of the boundary points belong to 2-4 adjacent zones, they occupy a different position in each of the zones, and the corresponding keys. non-linear) analogue converter 69 can be selected by different 1 and decoders, the outputs of the decoders are connected to the corresponding keys through the elements And. The inputs of the decoder 18 are connected to the outputs of the counters 12 and 13, the inputs of the depot encoder 19 - to the inputs of the adder 15 and the counter 13 inputs of the decoder 20 - to the outputs of the counter 12 and the adder 16, the inputs of the decoder 21 to the outputs of the adders 15 and 16. The decoder 18 selects the keys corresponding to the first boundary points of the zones (z V 4 the de-distributor 19 carries out the keys corresponding to the second boundary points of the zones, the decoder 20 selects the keys corresponding to the third boundary zones, and the decoder 21 selects the keys corresponding to the fourth boundary points of the zones.

The block diagram of the correction calculation block is presented in FIG. 6. The indicated bus numbers with which the block is connected to other blocks of the device correspond to block 70, the block includes inverters, adders 521-524 and multipliers 525527.

The device works as follows. 13. The tracking information pulse, coming through bus 3 to the device input, records the X and Y coordinate codes from buses 1 and 2 to the registers and 5. From the output, registers 4 and 5, the coordinate codes X and Y are sent to the input of the switch 10 and linear digital-to-analog converters 5 and 7, which form a linear component of clone signals transmitted via buses 43 and A35 to the inputs of amplifiers and 82. Simultaneously with recording the codes of the coordinates into the registers t and 5, the pulse distributor 8 starts to work out the program we generate signals that synchronize operation of the device blocks. . The signal generated on the ifll bus is used to connect the outputs of the switch 11 to its inputs connected via buses (18, 419 and 20 with outputs c4et4HKa 12. At the same time, the address inputs of the memory block 17 are connected to the outputs of the counter 12. At when there is no signal on bus 17, the code formed at the address inputs is perceived as the code of the address of the coordinates of the vertical boundary line. At the time described, the counter 12 is in the zero state and the code formed at the input of the memory block is the code of the address of the coordinate of the first vertical face. The memory unit 1 7 at its outputs generates the code of the X coordinate of the first vertical boundary line stored at this address. The code on the bus 86 goes to the inputs of registers 89-92. On the control signal, which is present on the bus jll, writing the X coordinate code of the first vertical boundary line B register 89. Next, the pulse distributor stops generating the control signal on the bus til and generates a control signal on the bus 12. At the same time, the outputs of the switch 11 are connected to its second input box connected with vyhrddy adder 15. Adder 15 is connected by the first inputs to the outputs of counter 12, and the second code is supplied with the code number 1. Thus, the adder 18 adds 12 to the output code of the counter. In this case, when at the outputs of counter 12, the address code of the coordinate of the first vertical boundary line is formed, you are 7 “; during the adder 18, the address code of the second vertical boundary line is generated. Since the formation of the control signal on bus 12 begins, a control signal is established on bus 09, so that the outputs of switch 9 are connected to its inputs connected by bus to outputs of register 30, and the outputs of switch 10 to its inputs connected to outputs of register k . At the inputs of the adder 1 connected to the direct outputs of the switch 9 and the inverse outputs of the switch 10, the direct code of the X coordinate of the displayed electron-tube of the image element (point) and the reverse code of the X coordinate of the second boundary line are set. At the output of the sum of the matrix t, a difference code is generated. If his sign is positive, i.e. if the X coordinate of the output point is greater than the X coordinate of the second boundary line, pulse distributor 8 generates a control signal on bus 15. According to this signal, counter 12 increases its state by one, after which the described process repeats, but only at the end it in register 89 contains the code of the X coordinate of the second vertical i-boundary line, and in register 90 the code of the X coordinate of the third vertical boundary line. In the event that the code of the coordinate of the next boundary line recorded in the register 90 is greater than the code of the X coordinate of the output point, the output of the sign bit of the adder k generates a signal which, acting on the pulse distributor 8, ensures that the formation of the signals controlling the overwriting of the information in the registers 89 and 90. Similarly, automatic identification of coordinate codes is made at the horizontal boundary lines bounding the zone corresponding to the coordinates of the light spot and recording these rows into registers 91 and 92. The outputs of registers 9092 codes the coordinates of the boundary lines to the inputs of linear digital to analog converters. The output of converter 93 through inverter 97 is connected to the first inputs of adders 99 and 102, and the output of converter 9 through inverter 98 is connected to the first inputs of adders 100 and 101. At the output of adder 99, connected by a second input to the output of digital analog converter 6, a signal is generated X2 -)., J, Ha output of the adder 100, connected by a second input to the output of the digital-to-analog converter 7, a signal 1 is generated, the output of the adder 101 is a signal (3 output of the adder 102 - signal / i; d) 7 .-. С. You go the adders 99 and 100 signals arrive at the inputs of the blocks, dividing 03 and 10J. The transfer coefficient of unit 103 is equal to y –K, and the coefficient iHJ Sj of giving unit io is L .. If the zone size is chosen constant, the dividing units can be made in the form of simple relay voltage dividers, thus eliminating the need for register; pax 91, 92 and digital-to-analog converters 95 and 96. From the outputs of division blocks 103 and 10 .j, the signals f × - Z:; ..: t: iHi i, 4 "NG 1.1 buses L9b and arrive at the inputs of the calculation blocks Amendments 76-80, connected via switches to the outputs of the non-linear digital-to-analog converter B9. From the outputs of the converter 69, signals are received from the switches 69) La1Fm.kC2,, F3, 1) through the switches. Correction calculation units perform signal processing in accordance with the expression, (2). Correction signals are received at the inputs of amplifiers 81-85. 8 channels of forming currents (amplifiers 81 and 82 | ° add up to the linear component of the transmitting signal, and the amplifiers are amplified, and in the channels of forming the currents of dynamic focusing and astigmatism correction, deviations are simply amplified by 83-85 amplifiers. Using the described device This method allows to increase the resolution and accuracy by 2-3 times and at the same time almost completely eliminate image distortions at the junction zones, which greatly expands the scope of application of such devices. Flo compared with the device by you, in which correction of asthma is achieved by processing OTJ control signals; by cloning according to a given law, the setting or reconfiguration time of the device is reduced by a factor of 10–20. r, j Z25 "% - 2g." .. 24t - - "- GR - Zjj - - - 222 - 32 - 2 - - Z / f% - L - III. I fui.l ZZ (75 -. Zgj - Zyj. Zg2 - 72 - Isi 61 271 III

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Claims (1)

Device for On-Screen display cathode ray tube, (having first and second coordinate registers, the first and second linear digital to analog converters, digital to analog nonlinear ^{pre-;!.-Forming,} group of decoders, the first group of amplifiers, the first coordinate is vhod.pervogo register first. the device’s input, the first input of the second coordinate register is the second device input, the second inputs of the first and second coordinate registers are combined and are the third device input, the input of the first the linear digital-to-analog converter is connected to the output of the first coordinate register, and the input of the second linear digital-to-analog converter is connected to the output of the second coordinate register, the outputs of the amplifiers are the device outputs, the outputs of the first and second linear digital-to-analog converters are connected to the coordinate inputs of the first and second amplifiers rpyrftiw respectively, characterized by the fact that, in order to expand the scope of application of the device by increasing the resolution and accuracy in the output of information In addition, the pulse distributor, the first, second and third switches, the group of switches, the first, second and third adders, the memory block, the first and second counters, the group of AND elements, the encoder, the group of code registers, the group of Linear digital-to-analog converters, the first AND the second inverters, the group of analog adders, the first and second blocks of Division, the group of blocks for calculating corrections, while the nonlinear digital-to-analog converter contains a group of keys, a matrix of current sources, a second group of amplifiers, ¹ the outputs of the keys are connected to the inputs of the current sources of the corresponding matrix row, and the outputs of the sources of the current of the matrix row are connected to the inputs of the corresponding amplifiers of the second group, the outputs of which are connected to the inputs of the corresponding switches of the group, and the inputs of the keys, except the first and last, are connected to the outputs of the corresponding elements AND groups, the inputs of which are connected to the outputs of the corresponding decoders, groups, and the input of the first and last keys is connected to the corresponding output of the first and last decoders pp, the inputs of the group decoders are combined with the first, second, third and fourth inputs of the third switch, the first input of the second adder and the first input of the third adder, respectively, and are connected to the outputs of the first counter, second adder, second counter and third adder, respectively, the second input of the second and second the input of the third adders are the fourth and fifth inputs of the device, respectively. The output of the third t029177 of its switch is connected to the input of the memory unit, the output of which is connected to the inputs of the code registers ups whose outputs are connected to the inputs of the corresponding linear digital-to-analog converters of the group, the output of the odd registers of group codes are connected to the inputs of the first switch, the output of which is connected to the first input of the first adder, the second input of which is connected to the output of the second switch, the output of the first adder is connected to the first input of the distributor pulses, the second input of which is the third input of the device, the first and second inputs of the second switch are connected respectively to the outputs of the first and second coordinate registers, the first input of the encoder is combined: with the first input of the second adder, and the second input of the encoder is connected to the first input of the third adder, the output of the encoder is connected to the control inputs of the group switches, the outputs of the first and second linear digital-to-analog converters of the group are connected respectively to the inputs of the first and second inverters whose outputs are connected to the first inputs of the odd and even analog group adders, the second inputs of the first two analog adders of the Group are connected respectively to the outputs of the first and second linear digital-to-analog converters of the group, the second inputs of the last two analog adders of the group are connected respectively to the outputs of the last two linear digital-to-analog converters of the group, the inputs of the first division block are connected, respectively. with the outputs of the odd analog adders of the group, and the inputs of the second division block with the outputs of the even analog adders of the group, while the correction unit contains the first, second, third and fourth inverters, the first, second, third and fourth adders, the first, second and third blocks multiplication, while the input of the first inverter, the first input of the first adder, the input of the second inverter, the first input of the second adder in each correction calculation unit are connected to the outputs of the corresponding group switches, the first inputs of the first and ΐ w Each of the multiplication blocks of each correction calculation block is connected to the output of the first division block, and the first input of the third multiplication block of each correction calculation block is connected to the output of the second division block, the output of the first inverter is connected to the second input of the first adder, the first input of the third adder, and the first input of the fourth adder, the output of the second inverter is connected to the second input of the second adder, and the input of the third inverter is combined with the first input of the second adder, the outputs of the first and second adders are connected respectively, to the second inputs of the first and second multiplication units, the output of the first multiplication unit is connected to the second input of the third adder and the input of the fourth inverter, the output of the second multiplication unit is connected to the third input of the third adder, the output of the third inverter is connected to the fourth input of the third adder, the output of the third the adder i is connected to the second input of the third multiplication unit, the output of the fourth inverter is connected to the second input of the fourth + adder, the output of the third multiplication unit is connected to the third input of tvertogo adder outputs fourth adders each blo, ka calculating corrections are connected to the correction input of the respective amplifiers, the pulse distributor outputs connected to control inputs of said first, second and third switches, the first and second counters and memory unit.