SU830511A1 - Device for displaying three-dimensional information - Google Patents

Description

The invention relates to computing technology can be used in the design of display devices.

A device for displaying information is known that contains a register, a control unit, imj) analogue converters, deviation amplifiers and an indicator l.

The closest in technical essence is a device for displaying volumetric information, containing a register connected to digital and analogue converters in X, Y, Z coordinates and through a pulse shaper with an indicator, and through an image scale block with adder of X coordinate codes, Ui code adder coordinates 2, Y, digital-to-analog converters on coordinates X and Z through adders of coordinate codes X, Y and 2, X, Y, respectively, are connected to amplifiers of deviation on coordinates X and Z, and digital-analog conversion va-

tel coordinate Y is connected to the second input of the adder codes of coordinates 2, X,

The main disadvantage of these devices is the lack of the ability to construct volumetric images in any axonometric projection, including oblique and rectangular.

The purpose of the invention is to expand the field of application of the device by providing the ability to display volumetric information in any of the axonometric projections.

Delivered. Aim reaches-. with the fact that the device contains a voltage corrector in the X and Y coordinates, connected to the recorder, C | ({) by the canal converters in the X and Y coordinates, and also the adder of the Z, X, Y coordinate codes.

Claims (2)

FIG. I is a block diagram of the device for displaying bulk information in FIG. 2 - construction of a spatial image in isometry. The device dp displaying volumetric information contains a register 1 connected to a diffraction converter 2 at coordinates X, with a digital-to-analog converter 3 at coordinate Y, with an integrated analog-converter converter 4 at coordinate 2 and through a driver 5 pulses with an indicator 6 in the form of a memory CRT that is connected to an amplifier 7 deviations in the X coordinate and to the amplifier. 8 deviations in the Z coordinate, each of which is connected respectively to the adder 9 of the X, Y coordinate codes and the adder 1O of the 2 X, Y coordinate code, which in In turn, they are associated with a set of 11 scale objectives. The corrector 12 is voltage on the coordinates X and Y is connected to chi}) by the analogue converter 2 by the coordinate X, the adder 9, the codes of the coordinates X, Y, and the analogue by the analogue converter 3 by the coordinate Y, the adder 1O of the codes. coordinates Z, X, U. The device works as follows. The input register 1 of the device receives information from the computer in the form of codes about the coordinates X, У Z, onalichii or absence of illumination pulses and the type of projection. G output of the input register 1 data on the coordinates X, Y, Z are fed respectively to the digital two-way converters 2-4. A constant voltage from the analog-to-analog converter 4, determining the coordinate 2, enters the first input of the adder 1 of the coordinate codes Z, X, Y and, in the absence of data on the X, Y coordinates, without any changes, goes to the amplifier 8 of the Z deviation and then to the deviating an indicator recording section system based on a CRT memory. The illumination pulses from the input register 1 through the pulse generator 5 arrive at the third input of the indicator 6 on the basis of the memory CRT, providing a sub-informational point. At the same time, on the screen, the indicator is constructed and the axis is perceived (vertical line) as shown in FIG. 2. When information on the X coordinate is received, the Y and Z coordinates are absent, i.e. X axis should be plotted at an angle of 30 to the horizontal line on the indicator screen in case of a specific projection; in the case of a horizontal isometric projection (GOST 2.317-69, etc.) of both outputs of the digital-to-analog converter 2, equal in size, the signals arrive at the first input of the dummy 9 coordinate codes X, Y and the corector 12 voltages along the coordinates X and Y. From the output of the adder 9 of the X-coordinate code Xp, a constant voltage across the silicon 7, the deviation along the X coordinate is accessed by the deflecting system, and the indicator records on the (electron storage tube) ZELT. Simultaneously with this corrected (weakened in cases where the angle Hai of the X-axis-to-horizontal line on the indicator screen is less than 45, for example, 30 when isometric, or reinforced in cases where this angle is more than 45, such as 60 for horizontal iso / metric projection) voltage with tiep. the output of the voltage corrector 12 is fed to the adder XO, X, Y and then through the amplifier 8 of the deviation 2 to the deflecting system of the NELT indicator recording section, providing the output of the ZELT Recording Beam to the specified point on the X axis. through the pulse shaper 5 into the indicator 6 on the ZELT, the line is recorded and played, which is the X axis. The degree of correction (weakening or amplification) of the voltage in the voltage corrector 12 determines the angle of the X axis to the horizontal line on the screen It is not an indicator and is specified by a code message coming from the input register and determining the type of axonometric projection, including rectangular and oblique. Similarly, the axis is constructed with the difference that in this case there is no data on the coordinates X and 2, and information on the coordinate Y comes from input register 1 through qi || roanapogovy converter 3 according to the coordinate Y on the adder 9 coordinates X, Y and corrector 12 voltage. Further passage of signals is similar to the described case when building the X axis. GOST 2.317.69 provides for the possibility of constructing axonometric projections without distortion along the axes X, Y, Z, or with distortions along the axes X, Y, Z. In the device this is realized by the unit 11 sets of scales, controlled by code parcels, arriving at its input from the input register and determining the type of axonometric projection and the presence or absence of distortions along the axes X, Y, Z. For example, when the distortion coefficients are less than a unit, the voltages of the outputs of the block 11 setting the headquarters to the outputs of the adders 9 and 10 are such that, algebraically added in the sum of the matrices 9 and 10, to the voltages that determine the corresponding coordinate, ultimately decrease the length of the path traveled by the beam recording the recording CRT along the axis along which the corresponding distortion coefficient is introduced. To build a line in the X plane (for example, lines A and B, Fig. 2) in the absence of the Y coordinate, information about the X coordinate comes through Qi {) ro-analog converter 2 to the adder 9 coordinates. XY and further than the amplifier 7 deviations in the X coordinate for the indicator recording section. On the CRT memory. Simultaneously with the input of the voltage from the square-analog converter 2 along the X coordinate to the adder 9 XY, it goes to the voltage equalizer 12 and then to the adder 10 along the coordinates Z, X, Y, where it is combined with the incoming from the analog converter 4 to the Z coordinate by the voltage defining the Z coordinate, and then the voltage through the amplifier 8 deviations in the Z coordinate is detected by the voltage on the opening system of the indicator recording section behind the ZELT. The arrival of the screw in this case the light pulses provide recording and reproduction of the line AB, as shown in FIG. 2. Spatial lines are constructed while receiving signals on the coordinates X, Y, Z. In this case, adder 9, X, Y will calculate the voltage, determining the coordinate X and Y, and the adder 1О, Z, X, Y summarizes the voltage, coming from the digital-analog converter 4 along the Z coordinate, and determining the coordinate Z, with the voltage corrector corrected by 12, the voltages defining the coordinates X and Y. If, for example, the voltage defining the X coordinate changes linearly from the value determined at the initial time point A, and at the final moment of time the origin of coordinates, voltage, determining the coordinate inati Y varies in li116 and not law, for a range of values, defining respectively the initial and final moments of time the position of points K and L on the Y axis, and the voltage specifying coordinate Z. also varies linearly from zero to the value that determines the position of point B, then the result of the light pulse receiving is built and reproduced a piece of spatial straight K L. The corrector of 12 voltages in accordance with the incoming codes determines the type of projection, and the scale setting unit 11 - the distortion factor for the axes. The more complex laws of voltage variation from the digital-to-analog converters 2-4 provide for the construction and display of curves and surfaces of the second bitch In the simplest case, when constructing, for example, a circle (in Fig. 2 is represented as an ellipse) in the X Z plane and coordinates, the voltage with qi | roanapog transducers 2 and 4 varying in a sinusoidal law (with a shift: in phase by 9O) correspond respectively to the adders 9 and 1O, and to the czgmmator 1O, the corrected voltage equalizer 12 correlates to the position of the point along the X axis Considering the adder 9 and 10, in addition to these sinusoidally varying voltages, constant voltages determine the Y coordinate (on the adder 9 directly from the single analog converter 3 on the Y coordinate, and on the adder 1O through the corrector or 12 voltages. The output voltages from the outputs of adders 9 and 1O through the silicon 7 and 8 deviations to the deviating system of the recording section of the memory CRT are provided in the presence of pulses of a single ellipse, which is a projection of a circle in the plane Z (Fig. 2) The introduction of a new voltage-corrector node of 12 voltages and a new connection realized by it between the digital-to-digital converter 2 on the corank X and the adder 1O of the Z coordinates,, Y distinguishes the device for displaying information from the known due to a change in the angle of inclination of this X and Y to the horizontal line in the screen of the indicator, it is possible to construct any of the axonometric projections of both rectangular and oblique. This is necessary when carrying out design projects of various kinds, design and artwork, computer modeling of complex profiles of curved surfaces in any axonometric project. Thus, the functionality of the device is significantly expanded, which expands the range of its application in various fields of science and technology. The device can be implemented on the basis of storage CRT with a visible image, combining the functions of storage and information visualization, and on the basis of storage CRT with an optical output signal. Claims. A device for displaying volumetric information, containing a register, connected to a digital-threshold conversion zone in coordinates X, Y and Z, and form | The world of pulses, which is connected with the indicator, and the unit for setting the image scale ba, which is connected to the X, Y and X8 coordinate codes adder, to the Z, Y coordinate codes maker, and the electronic analogue converters on X and 21 coordinates are connected to the first inputs of the code adders coordinates X, Y and ZX, Y respectively, which are connected to the deviation amplifiers - by the coordinates X and Z, and col |) the analogue converter by the Y coordinate is connected to the second input of the coordinate adder 2 | X, Y, characterized in that, in order to expand the field of application of the device by providing the ability to display volumetric information in any of the axonometric projections, it contains a voltage corrector along the X and Y coordinates, connected to the register, with digital-to-analogue converters along the X coordinates and Y and adder codes of coordinates 2., X, Y .. Sources of information taken into account during the examination 1. Author's certificate of the USSR No. 484539, cl GO6 K 15/20, 1975. 2. USSR author's certificate for application number 2592648 (18-24) ,. cl. G06 K 15/20, 1978 (prototype).