RU2380762C2 - Visual display control device - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: device, which has a unit of addresses of rectangular zones, units for nodal values on X and Y axes and a two-coordinate interpolator, also includes a clock pulse generator, address counters on X and Y axes, first and second units of closing switches and units for opening switches on X and Y axes, a memory unit and an inverter.

EFFECT: faster formation of image field.

1 dwg

Description

The proposed device relates to control devices for visual indicators and can be used in indicators with raster and / or vector scan to correct geometric and scale distortions.

A device is known that contains digital-to-analog converters, deviation amplifiers, a cathode ray tube (CRT) with a deflecting system, nodal value blocks, an interpolator, and an address block. The inputs of the digital-to-analog converters, the interpolator, and the address block are the inputs of the device. The outputs of the nodal value blocks are connected to the second inputs of the deviation amplifiers along the X and Y axes, the first inputs of which are connected to the outputs of the corresponding digital-to-analog converters, and the outputs are connected to the deflecting coils of the deflecting CRT system, see USSR author certificate No. 791558 of 09.21.1977 for class B41B 19/00.

In this device, the functions of generating the coordinates of the nodes and the values of the deviation signals at the internode points are divided between the block of nodal values and the interpolator, respectively. Its adjustment is reduced to selecting the values of the deviation signals at the nodal points, calculating and entering the increment values for each of the zones into the memory of the interpolator. The address block, nodal value blocks and the interpolator of this device are an analog-to-digital (hybrid) functional converter of the functions of two variables along the X and Y axes, which is characterized by low accuracy due to the spread of parameters (mainly, the resistance of analog keys in the open state) and errors of performing operations of addition and multiplication in an analogous way.

A device is also known comprising a block of addresses of rectangular zones, a block of nodal values along the X axis, a block of nodal values along the Y axis, a two-coordinate interpolator along the X and Y axes. The outputs of the block of addresses of rectangular zones are connected to the inputs of the blocks of nodal values along the X and Y axes and the corresponding address inputs of a two-coordinate interpolator. The address inputs of the two-coordinate interpolator are connected to the outputs of the blocks of nodal values along the X and Y axes, respectively. The inputs of the deploying functions along the X and Y axes of the two-coordinate interpolator are connected to the inputs of the block of zone addresses and to the device inputs along the X and Y axes. The outputs of the two-coordinate interpolator are the device outputs along the X and Y axes, see patent for invention No. 2262747 dated 12.24.2003 for class G09G 1/07, 1/10, 1/18.

Its adjustment is reduced to selecting the values of the deviation signals along the X and Y axes at the nodal points and entering their coordinates into the nodal value blocks. This device is taken as a prototype.

The disadvantage of the prototype is the low speed due to the large volume of sequentially performed operations: generating zone addresses, reading the nodal values of the interpolating function along the X and Y axes, and, in addition, performing the calculations in the interpolator necessary to form the interpolating function.

The aim of the invention is to increase performance in operating mode.

The essence of the proposed device lies in the fact that it contains a block of addresses of rectangular zones, blocks of nodal values along the axes X and Y and a two-axis interpolator along axes X and Y. The outputs of the block of addresses of rectangular zones are connected to the address inputs of the two-coordinate interpolator and to the inputs of blocks of nodal values by axes X and Y, respectively. The inputs of the block of addresses of rectangular zones are connected to the inputs of the deploying functions along the X and Y axes of the two-coordinate interpolator, and the outputs of the blocks of nodal values along the X and Y axes are connected to the data inputs of the two-coordinate interpolator along the same axes.

In contrast to the prototype, a clock generator, an address counter along the X axis, an address counter along the Y axis, a first block of locking keys along the X axis, a first block of locking keys along the Y axis, a block of opening keys along the X axis, a block of opening keys along Y axis, a storage device, a second block of locking keys along the X axis, a second block of locking keys along the Y axis, an inverter and a control input.

The inputs of the blocks of the opening keys along the axes X and Y are connected to the inputs of the device along the corresponding axes. The outputs of the block of opening keys along the X axis and the first block of closing keys along the X axis are connected to the corresponding input of the block of addresses of rectangular zones and the input of the address of the storage device along the X axis. The output of the block of breaking keys along the Y axis and the first block of closing keys along the Y axis are connected to the corresponding the input of the block of addresses of rectangular zones and the input of the address of the storage device along the Y axis.

The clock generator is connected to the input of the address counter on the X axis. The output of the address counter on the X axis is connected to the input of the address counter on the Y axis and to the input of the first block of closing keys along the X axis. The output of the address counter on the axis Y is connected to the input of the first block of closing keys along the y axis.

The outputs of the two-coordinate interpolator along the X and Y axes through the second blocks of the closing keys are connected to the data input of the storage device along the axes of the same name, which are also the device outputs along the X and Y axes.

The control inputs of all keys and the recording permission input of the storage device are connected to the control input of the proposed device. The read permission input of the storage device is connected to the control input of the proposed device through an inverter.

The increase in performance of the proposed device in the operating mode is due to the fact that the adjusted values of the expanding functions along the X and Y axes are read from the storage device.

The drawing shows a block diagram of the proposed device.

The proposed device comprises a clock generator 1, an address counter 2 on the X axis, an address counter 3 on the Y axis, blocks 4 and 5 of the opening keys, respectively, along the X and Y axes, the first blocks 6 and 7 of the closing keys, respectively, along the X and Y axes, block 8 addresses of rectangular zones, blocks 9 and 10 of nodal values respectively on the X and Y axes, two-coordinate interpolator 11, second blocks 12 and 13 of the closing keys, respectively, on the X and Y axes, memory 14, inverter 15.

The inputs of blocks 4 and 5 of the disconnecting keys along the X axis and Y axis are connected to the input of the device along the corresponding axes. The clock generator 1 is connected to the input of the counter 2 address on the X axis, the output of which is connected to the input of the counter 3 address on the Y axis and the input of the first block 6 of closing keys along the X axis. The output of the counter 3 of the address along the axis Y is connected to the input of the first block 7 of closing keys along the y axis.

The outputs of the first block 4 of the opening keys and block 6 of the closing keys along the X axis are connected to the input of the block 8 of the addresses of the rectangular zones along the X axis and the input of the address along the X axis of the storage device 14.

The outputs of the first block 5 of the opening keys and the block 7 of the locking keys along the Y axis are connected to the input of the block 8 of the addresses of the rectangular zones along the Y axis and the input of the address along the Y axis of the storage device 14.

The first and second outputs of block 8 of the addresses of rectangular zones are connected to the address inputs of the two-coordinate interpolator 11 and to the first and second inputs of block 9 of the nodal values along the X axis and block 10 of the nodal values along the Y axis, respectively. The inputs of the block 8 addresses of rectangular zones are connected to the inputs of the deploying functions along the X and Y axes of the two-coordinate interpolator 11.

The outputs of blocks 9, 10 of the nodal values along the X and Y axes are connected to the corresponding data inputs of the two-coordinate interpolator.

The outputs of the two-coordinate interpolator along the X and Y axes through the second blocks 12, 13 of the closing keys are connected to the data inputs of the storage device 14 along the corresponding axes, which are also the outputs of the device along the X and Y axes.

The control inputs of the first 6, 7 and second 12, 13 blocks of closing keys and blocks 4, 5 of breaking keys along the X and Y axes and the recording permission input of the storage device 14 are connected to the control input of the device. The read enable input of the storage device 14 is connected to the control input of the device through the inverter 15.

The device operates in setup mode and in operating mode.

The device is configured in two stages:

- measurement;

- calibration.

Measurement consists in determining the nodal values of the interpolating function. Digital expanding functions along the X and Y axes in a rectangular coordinate system with a measuring range of 0 X K, 0 Y L. are received at the device’s inputs from the external graphics controller. Thus, an image field containing K × L pixels is formed. In this mode, there is no signal at the control input, and, therefore, the signal coming from the inverter output puts the memory device, in the cells of which the addresses of the same cells are previously entered, into the reading mode. The opening keys of the opening key blocks are closed, and the inputs of the device along the X and Y axes are connected to the corresponding address inputs of the storage device. Consequently, the values of the deployment functions along the X and Y axes at the corresponding inputs and outputs of the device are the same.

The image field is formed by the display device, which includes the proposed device. It is conditionally divided into zones forming a rectangular grid, the nodes of which have coordinates X ₀ , X ₁ , ..., X _m along the X axis and Y ₀ , Y ₁ , ..., Y _n along the Y axis. With the screen of the display device, which includes the proposed device, an optically coupled stencil with an image of a rectangular grid, the coordinates of X _ti , Y _tj nodes of which are associated with the coordinates of the nodes X _i , Y _{j of the} grid of the image field by the ratio:

X _ti = kX _i ;

Y _tj = kY _j ;

where k is the scale factor.

By changing the values of the expanding functions in the vicinity of the points with coordinates X _i , Y _j , they achieve a combination of the node formed on the screen with the node X _ti , Y _{tj of the} screen. The nodal values of the interpolating function X _{0i, j} selected along the X axis and Y _{0i, j} along the Y axis are selected in this way, for example, using the programmer, and are written into the nodal value blocks along the X axis and Y axis, respectively.

After measurement, the device is calibrated. Calibration consists in writing to the memory device the corrected values of the expanding functions for each pixel of the generated image field.

For calibration, a control signal is applied to the control input of the device. As a result, the keys in the blocks 4, 5 of the opening keys go into the open state, the keys in the blocks 6, 7 of the closing keys go into the closed state, the storage device 14 switches to the recording mode.

The duration of the repetition period of pulses generated by the clock generator 1 is longer than the sum of the times the zone address was determined by block 8 of the address of rectangular zones, the selection of nodal values of the interpolating function from blocks 9, 10 of the nodal values along the X and Y axes, the formation of the adjusted coordinates X _to , Y _to two-coordinate interpolator 11 and write data to the storage device 14.

The sequentially connected counters 2 and 3 address on the X axis and on the Y axis form from a sequence of pulses generated by the clock pulse generator 1 received at the input of the counter 2 address on the X axis, a sequence of linearly changing values of the address codes of the pixels of the image field. The division coefficients of the counters 2,3 address on the axes X and Y are equal to K and L, respectively. This ensures the formation of addresses for all K × L pixels of the image field.

From the outputs of the counters 2,3 address on the X axis and on the Y axis through the closed keys of blocks 6, 7 of the closing keys on the X axis and on the Y axis, the address codes are sent to the corresponding inputs of the block 8 of the addresses of rectangular zones, a two-coordinate interpolator 11 and a storage device 14.

Block 8 addresses of rectangular zones generates coordinates of rectangular zones, which are defined in their P, Q coordinate system, the axes of which coincide with the axes X, Y:

P = i for X _i X <X _i-1 ;

Q = j for Y _j Y <Y _{j + 1} .

Range of change of values of coordinates of zones:

P = 0, ... m-1;

Q = 0, ... n-1.

From the output of block 8 of zone addresses, the codes of zone addresses are sent to the address inputs of the two-coordinate interpolator 11 and the corresponding inputs of blocks 9, 10 of the nodal values along the X axis and the Y axis. In this case, the nodal values selected at the stage of measurement and entered in the blocks 9, 10 of nodal values the interpolating functions X _0ij along the X axis and Y _0ij along the Y axis are read from them and fed to the data inputs of the two-coordinate interpolator 11, the inputs of the expanding functions of which also receive the address codes of the image field pixels along the X and Y axes.

According to the codes of the image pixel addresses along the X, Y axes of the addresses of the zones P, Q and the nodal values of the interpolating function X _{0i, j} , Y _{0i, j,} two-coordinate interpolator 11, using one of the known methods (piecewise linear interpolation, spline interpolation, etc. .), calculates the corrected coordinates of the pixels of the image field X _k , Y _k .

From the outputs of the two-coordinate interpolator 11 through the closed keys of the blocks 12, 13 of the closing keys, the corrected coordinates of the image pixels X _k , Y _k are supplied to the corresponding data inputs of the storage device 14, to the address inputs of which the uncorrected coordinates of the pixels of the image field are received. Thus, in each cell of the storage device 14 with the address X, Y, the corrected coordinates X _k, Y _k are entered. The setup process ends after recording the corrected coordinates in all K × L cells of the storage device 14.

To enter the operating mode, the signal is removed from the control input of the proposed device. At the same time, the signal coming from the output of the inverter 15 puts the storage device 14 in read mode. The keys of blocks 4, 5 of the closing keys are closed, and the inputs of the device along the X, Y axes are connected to the corresponding address inputs of the storage device 14. The keys of the blocks 12, 13 of the opening keys are open, and the outputs of the device along the X, Y axes are connected to the corresponding data outputs of the storage device 14. Thus, the expanding functions along the X, Y axes arrive at the corresponding address inputs of the storage device 14, from the outputs of which the corrected values of the expanding function X _k , Y _{k are} read out in one reading cycle.

A model of the proposed device was developed and tested, all functional blocks, except for the storage device, are implemented on the FPGA f. Xilix. The storage device was made on a permanent storage device Am 29LV033C-90EE type FLAH.

The speed of the device in operating mode is determined by the minimum allowable reading cycle of the storage device, which in this case is 90 ns.

Claims (1)

A visual indicator control device comprising a block of addresses of rectangular zones, blocks of nodal values along the X and Y axes and a two-coordinate interpolator, the outputs of the block of addresses of rectangular zones being connected to the address inputs of the two-coordinate interpolator and to the inputs of blocks of nodal values along the X and Y axes, respectively, the inputs of the block the addresses of the rectangular zones are connected to the inputs of the deployment functions along the X and Y axes of the two-coordinate interpolator, and the outputs of the nodal value blocks along the X and Y axes are connected to the data inputs of the two-axis interpolator a regular interpolator along the axes of the same name, characterized in that, in order to improve performance in the operating mode, a clock pulse generator, address counters along the X and Y axes, first and second blocks of the closing keys along the X and Y axes, blocks of opening keys along the the X and Y axes, a storage device and an inverter, while the clock generator is connected to the input of the address counter on the X axis, the output of which is connected to the input of the address counter on the Y axis, and the outputs of the address counters on the X and Y axes are connected to the inputs of the same name the first locking keys along the X and Y axes, the inputs of the opening key blocks along the X and Y axes are connected to the device inputs along the axes of the same name, the outputs of the first locking key block along the X axis and the locking key block along the X axis are connected to the first input of the block of rectangular zone addresses and the address input along the X axis of the storage device, the outputs of the first block of opening keys along the Y axis and the block of closing keys along the Y axis are connected to the second input of the block of addresses of rectangular zones and the input of the address along the axis Y of the storage device, outputs are two-coordinate the interpolator along the X and Y axes through the second blocks of the locking keys are connected to the data inputs of the storage device along the axes of the same name, which are also the outputs of the device along the X and Y axes, the other control inputs of the first and second blocks of the closing keys and blocks of the opening keys along the X axes and Y and the recording permission input of the storage device are connected to the control input of the device, and the read permission input of the storage device is connected to the control input of the device through an inverter.