CS260780B1 - Voltage component's generator for forming vectors and spots on devices representing in rectangular coordinate system - Google Patents

Description

The voltage component generator is intended to drive a deflection amplifier for one of the axes when displayed in a rectangular array. It solves the problem of increasing the number of groups when generating vectors with a constant time integration method. The principle of the connection is that the integration resistor is divided into at least three parts, with the last part, whose value is equal to one quarter of its total value and through which the inverting input of the amplifier is connected only to the end of its previous part, wherein its control input is coupled to a second output of the driving and compensating circuits, the first output of which is coupled to the inverting input of the amplifier, and its input is coupled to the first generator wiring input to which a digital signal identifying groups of vectors is applied. The generator can also be used as a separate source of saw-tooth voltage, eventually in the generators function.

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SUMMARY OF THE INVENTION The present invention provides a voltage component generator for generating vectors and points on devices displaying in a rectangular coordinate system for driving a deflection amplifier for one of the display axes, for example, graphical vector monitors or coordinate recorders. to groups that match different times so that the drawing speed at the group boundaries is constant, equal to the maximum value, containing the digital inputs connected to the data source, such as a graphics processor or control unit and analog output.

To display vectors and points in a rectangular coordinate system, it is necessary, based on instructions and digital data from ^A, to tell the coordinates of the points, respectively. incremental vector coordinates, generate analogue voltage components that move the electron beam across the screen shade or scribe by paper across the recorder by means of the deflection amplifiers for the X and Y axes. In order not to differentiate the displayed vectors of different length and direction, mainly by the different intensity of the lines when displayed on the display devices, their drawing speed must be constant, or the correction of the brightness must be performed.

In practice, compliance with the constant velocity condition is difficult to realize, mainly because solutions are most often used in the analog generation mode in which the vectors are displayed at a constant velocity in the direction of the larger component or are displayed at a constant time. When drawing at a constant speed in the direction of the larger component, position generating circuits and saw-tooth voltage generating circuits are used separately.

Sawtooth voltages can be generated by the integration method in integrators or directly in deflection coils, requiring a proportion of components, or multiplying converters. The length of the vectors is defined by time or analog comparators. The disadvantage of this quasi-constant speed drawing is the need for at least four digital-to-analog converters, or a combination of several digital-to-analog and multiplier converters, in addition to the proportion of components realized by digital or analogue mode. by overcoming the resulting voltage, furthermore the need for sawtooth voltage polarity switches, or alternatively, voltage component switches on individual axes, if the major component is always processed in the same circuits, and the need for fast and accurate level comparators.

In constant time drawing, a precise method is used using the a, 1-a method, which has the disadvantage of requiring at least four digital-analogue converters and luminance correction circuits, or an integration method. In this case, vectors are dependent on the lengths, respectively. from the lengths of the components divided into groups, to which different times correspond, so that the drawing speed at the group boundaries is constant, equal to the maximum. The times in each group and the number of groups are selected so that the change in drawing speed in the groups is minimal, the groups are easy to implement and also whether the brightness correction of the displayed information is used.

Groups can be realized in the analog part by switching elements forming the integrator time constant and the length of the vectors is defined by the analog comparators or time. However, when you create a larger number of groups, the number of elements increases, and setting and compliance is complicated. Due to the simple distinction of the vector component increments · sequentially divided by half from the maximum length and the numerical form shifts of such increments, such grouping is associated with the temporal definition of the vector length most often. The disadvantage of this method of generating vectors is the smaller amount of information displayed than when drawing at quasi-constant speed and due to the large variation in the drawing speed in the group also the necessary brightness correction circuits of the displayed information.

The principle of connecting the voltage component generator for generating vectors and points on devices displaying in a rectangular coordinate system is that the integration resistor is divided into at least three parts, with the last part of which the inverting input of the amplifier is connected to the end of its previous array, the first switch is connected in parallel, its control input being connected to the second output of the driving and compensating circuits. the first output of which is connected to the input of the generator connection.

The advantages of said voltage component generator connection for generating vectors and points on devices displaying in a rectangular display system, in addition to using a minimum number of digital-to-analog converters, does not include circuits for generating positions and generating sawtooth voltage, eliminating the possibility of output overshoot does not use an analog switch to change the polarity of the voltage when changing the direction of vector generation, compensates for integration and timing errors in point mode, so they do not accumulate gradually and thus become inaccurate and use memory mode to work as a sampler, so the analog-to-analog converter does not appear on the output terminal of the generator in that the division of each existing group into two halves is created by a simple buffer in the analog part, by doubling the number of groups n decreases the ratio of maximum and minimum) of vector drawing speed in groups from 2.83: 1 to 1.89: 1, so that there are smaller decreases to maximum speed, which makes better use of the speed of the deflecting amplifiers, increasing the amount of displayable information; No luminance correction.

An example of a particular voltage component generator connection for generating vectors and points on devices depicting a rectangular array of the invention is shown in the accompanying drawing.

The voltage component generator for generating vectors and points on devices displaying in a rectangular coordinate system in a particular embodiment of the invention comprises digital inputs 1-4, a digital-analog converter 5, a multifunction integrator 6, and an analog output 23. The multifunction integrator S comprises an amplifier 14 with inverting and a non-inverting input and output, a split integrating resistor S, whose parts 10, 11, 12 are connected in series, an integrating capacitor 13, a second capacitor 19, switches 8, 16, 1.7, 21 with input, output and control input with respective excitation and compensating circuits 7, 15, 18, inverting summing amplifier 22 with two input and output terminals and ground terminal 20.

To the inverting input of the amplifier 14, which is connected via a third switch 17 to the ground terminal 26 is via ^de] ený integrating resistor 9 connected output digital-to-analogue converters with, then through the integration capacitor 13 of the output, further second output of the second 15 and first outlet of third thistles and compensating circuits · 1S. The non-inverting input of the amplifier 14, which is connected via the second capacitor 13 to the ground terminal 29, is connected to the second output of the third excitation and compensating circuits 18 and via the fourth switch 21 the output of the inverting summing amplifier. The amplifier 14 is connected to the analog output 23 of the generator, and its second input is connected to the output of a digital-analog converter 5 connected to the beginning of the first part 10 of the split integration resistor 9.

The input of the analog-to-analog converter 5 is connected to the second input 2 of the generator wiring. The end of the first part 10 connected to the beginning of the next part 11 of the split integration resistor 9 is connected via the second switch 16 to the ground terminal 29, its control input being connected to the first output of the second excitation and compensating circuits 15 whose input is connected to the third generator input 3. The control inputs of the third 17 and the fourth switch 21 are coupled to the third output of the third excitation and compensation circuits

18, the input of which is connected to the fourth generator input 4 of the generator.

A first switch 8 is connected in parallel to the last part 12 of the split integration resistor 9, one end of which is connected to the inverting input of the amplifier 14, and its control input is connected to the second output of the first excitation and compensation circuits 7, an inverting input of the amplifier 14 and their input is coupled to the first generator wiring input.

The generator function is as follows. The digital signals corresponding to the displayed components of the vectors or points supplied to the second input 2 of the generator are converted to pulse voltage by the digital-analog converter 5. Depending on the digital signal applied to the fourth input 4 of the generator, which determines the mode of the multifunction integrator 6, the pulse voltage corresponding to the point components when the switches 17, 21 is switched is transmitted with opposite polarity u to the output 23 of the generator.

In case the switches 17, 21 are opened and the switch 16 is closed, the output voltage of the generator remains unchanged, so that the digital signals at the second input 2 of the generator can be changed so that the output voltage of the analog-to-analog converter 5 is proportional to Lodrv. to create sawtooth tension by incrementing vector components. By opening the second switch 16 with a digital signal on the third input 3 of the generator determining the vector generation time, integration occurs so that the flood voltage at the integration capacity 13 starts to increase or decrease linearly depending on a time constant equal to the product of integration capacity 13 and integration resistance 9 and the magnitude and polarity of the voltage at the output of the digital-to-analog converter 5.

Switching on the second switch 16 terminates the generation of sawtooth voltage. The second input of the generator is supplied with digital signals corresponding to the bc-components and, after switching the switches 17, 21, the end point voltage of the vector component is overwritten by the voltage of the digital-to-analog converter 5 and thereby corrects for possible errors. When the first switch 8 is opened, the generation of sawtooth with different slope in groups and the division of the vector components into groups is given by digital signals at the second input 2 of the generator.

the individual groups are created in such a way that the maximum length of the component is divided in half, resulting in groups from max. lengths to% max., from Ϋ2 max. lengths up to you max, etc., downwards This means that the components 7ϊ max. up to max. are generated in time T, components V max. up to max2 max. for T / 2, etc.

Applying a digital signal to the first

280780 generator input 1, by switching on the first switch 8, shortens the last part 12 of the integration decoder 9 in generating all the components of the longitudinal vector in the first half in each of the preceding groups, i. j. from max2 max. lengths to% max., from 1/4 max. lengths of 3/8 max, etc. 'so that the number of groups doubles. If the value of the last part 1 of the integrating resistor 9 is equal to V 1 of its total value, this time decreases the time constant and also the original generation time of the vector components in the new groups, from T to% T from T / 2 to 3 /. 8 T, etc '.

Based on the ratio of the lengths of the components and their drawing times, the drawing speed at the group boundaries is constant, equal to max. Value. With the flood count, the rate of generation of vector components in groups was reduced from max. to ^] / 2 max. speed, at twice the number of groups is a decrease to% max. speed.

The switches 8, 18, 17, 21 may be unipolar FET transistors. The excitation circuitry 7, 15, 115 serves. - as a TTL converter to switch voltage control and to compensate switch hubs. The amplifier 14 may be formed by an operational amplifier, the output of which is routed through a current amplifier to achieve higher generator run rates. The inverting summing amplifier 22 may be formed by an operational amplifier in an appropriate circuit.

The digital-to-analog converter 5 may be a bipolar type with a voltage output. To display vectors. and hcdov, two generators are required, the control digital signals at inputs 1, 3, 4 being common to their components. To achieve consistent polarity of the output voltage of the generator with the output voltage of the digital-analog converter 5 and also because of the separation of the multifunction integrator 6 from the excited circuits, it is advisable to include an opener amplifier in inverting connection.

The voltage component generator for generating vectors and points on alignments displaying in a rectangular coordinate system can also be used as a separate controlled sawtooth voltage source, possibly in function generators.

Claims (1)

260780 7 generator 1 input with a switch. the first portion 8 shortens the last portion 12 of the integration odipper 9 in generating all of the vector components belonging to the first half half length in each of the preceding groups, ie, from Ϋ2 max. length to% max., from 1/4 max. 3/8 max, etc., so the number of groups is doubled. If the value of the last part of the integration resistance 9 is equal to V i of its total value by this value, the time constant and the flood generation time of the component groups in the new groups are reduced, from T to% Tz T / 2 to 3/8 T, etc. From the ratio of the lengths of the components and the times of their drawing, the rate of drawing at the boundaries of the groups is based on a constant, equal to the maximum value. In the case of a good number of groups, the decrease in the rate of generation of vector components in groups was from max to] / 2 max. speed. Switches 8, 18, 17, 21 can be made up of polar FET transistors. The excitation circuits 7, 15, 115 serve. TTL level transmitter to control switchgear and compensate switching transients. The amplifier 14 can be formed by an operational amplifier whose output is passed through a current amplifier to achieve a higher rate of generator overrun. To view the vector. and said two generators are required, wherein digital control signals 1, 3, 4 are common to their components. In order to obtain the same polarity of the output voltage of the generator with the output voltage of the digital-to-analog converter 5 and also because of the separation of the multi-function integrator S from the excited circuits, it is suitable to include a 0-amplifier amplifier in the inverting connection at the output 28 of the generator. The voltage component generator for forming the points and points on the devices displaying in the rectangular coordinate system can also be used as a stand-alone controlled sawtooth source. OBJECT Generator of a voltage component for creating a vector and a point on devices displaying in a rectangular coordinate system, designed to drive a deflection amplifier for one of the display axes, for example, graphical vector monitors, or city hall recorders, the vector being represented by the integration method with and at the same time, they are divided into groups corresponding to barbecue times such that the rate of drawing at the group boundaries is constant, equal to the maximum value containing the numeric inputs connected to the data source, e.g., a graphics processor or an analog controller an output, a digital analog transceiver, and a multifunctional integrator that further includes an invert and non-inverting amplifier, an integrating resistor composed of a plurality of portions connected in series, an integrating capacitor, a second capacitor, min. three switches with input, output control input with appropriate excitation and compensation circuits, inverting amplifier with at least two outputs and output and ground terminal, with inverting input of amplifier connected via third switch with ground terminal, not integrating resistor connected the numerical-analogue output, the output through the capacitor, the second output of the second and the first output of the third and compensating circuits, the non-inverting input connected via the second capacitor to the ground terminal, the second output of the third excitation and com- in the aspect of the retirement circuits and through the fourth switch, the inverting summation amplifier, the first input of which is connected to the output of the amplifier, and connected to the analog output of the generator, while its second output is connected to the output of the numerical-ana-ló .-ka converter connected to the start m of the first portion of the integrating resistor, wherein the digital-to-analogue converter input is coupled to the second input of the generator input to which digital signals are inputted to display the components of the vectors and points, further at least in the end; the part connected to the beginning of the next part of the integrating resistor is connected to the second switch with the ground terminal, its control input being connected to the first output of the second excitation circuits, the input of which is connected by the generator input wiring input, which is the digital input the vector generating time signal, the control input, the third and the fourth switches are connected by a third output of the third drive and compensation circuits, the input of which is coupled to a wide input of the generator connection to which the generator mode digital signal is applied, that the integration resistor (9) is divided at least into three parts (10, 11, 12), with its last part (12) through which the inverting input of the amplifier (14) is connected to its cone the previous part (11), the first connected switch (8) is parallel, while its control input is 260780 9 10. associated with the second output of the first excitation and compensation circuits (7), the first output of which is connected to the inverting input of the amplifier (14) and their input is connected to the first input (1) of the generator. 1 sheet of drawings