SU470821A1 - Device for testing and adjusting functional converters of two variables - Google Patents

Description

The invention relates to the field of analog computing and is intended to visually investigate the errors of blocks of nonlinear functions of two variables. A device is known for checking and adjusting functional converters of two variables, comprising a recorder, the first and second inputs of which are connected to the outputs of the projective image block, and a difference block, the inputs of which are connected to the outputs of the checked and exemplary blocks of a nonlinear function, the inputs of which are connected to the first and second inputs of the device, and the output is connected to the first input of the unit to determine the excess of the error, the second input of which is connected to the third input of the device; the output of the error detection unit is connected to the key input, a control, whose input is connected to the output of the control unit, the inputs of which are connected to the first and second inputs of the device and the outputs of the first and second voltage generators of a triangular shape. The disadvantages of the known device are that, with its help, it is impossible to depict the coordinate axes of the projective image of the three-dimensional space and highlight the various elements of the image, as well as the high speed of the key. The aim of the invention is to expand the functionality, for which the proposed device comprises a block for forming coordinate axes and a block for brightness, the inputs of which are connected to the key output and the outputs of the block for creating coordinate axes, and the output connected to the third input of the recorder; the first input of the unit for forming the coordinate axes is connected to the output of the key, and its second and third inputs are connected to the outputs of the first and second voltage generators of a triangular form, respectively; the outputs of the block for the formation of coordinate axes are connected to the inputs of the block of the projective image. The block diagram of the device shown in the drawing. The device contains a tunable block 1 of a nonlinear function, an exemplary block 2 of a nonlinear function, a block of difference 3, a block 4 for determining the excess of error, a control block 5, a key 6, a generator of 7 and 8 triangular voltages, a block 9 for luminance, a block 10 of formation coordinate axes, projective image block 11, and a recorder (oscilloscope) 12. The device operates as follows. The variables Xi and Xg, varying according to any law necessary for testing, are simultaneously applied to the inputs of blocks 1 and 2. The JPa3HOCTb of their output values, obtained on the output of the difference block 3, is the norpei.ueness of the checked block 1 of the nonlinear function. It is fed to one of the inputs of the error determination unit 4, the second input of which is fed in is easily set with the necessary accuracy by the value of Dz. The value of e at the output of block 4 satisfies the equation. I D - Dz at D AZ 0; S - I Opri - Dz A. SDz; {D + Dz with, i.e., block 4 is a non-linearity of the type "sensitivity zone with adjustable boundaries" of the zone. Through the key 6, at the moments when it is in the closed state, is supplied to the input of the block 10 of the formation of coordinate axes. The remaining two of its inputs are given signals XI and X from the outputs of generators 7 and 8. Signals e, Xj, Xg are converted by the block 10 into g, Xl, X and fed to the inputs of the AND block of the projective image that implements the equations: X XfcOS -X2COS J , y-s -A smc -A | sinO, where X is the voltage at one of the outputs of block 11 connected to the horizontal input of the recorder 12; Y is the voltage at the second output of block 11 connected to the vertical input of the recorder 12; φ is the angle between the direction of horizontal scanning of the recorder 12 and the projective image of the axis, corresponding to its variable X; ij) is the angle between the direction of horizontal scanning and the projective image of the opposite direction of the axis corresponding to its variable X2. The angles φ and | are taken so that on the screen of the recorder 12 to obtain a convenient for perception projective image of three-dimensional space. A change in the values of φ and |) corresponds to the rotation of the image in three-dimensional space. The key 6 is in the closed state at the moments determined by the control unit 5, which acts on the key 6 on the control input. This allows continuously, during the verification process, to create on the oscilloscope screen the instantaneous values of the function exceeding the error level Dz and the plane displaying this level. The image of the coordinate axes is performed by block 10 as follows: at times when -0, 0, where is constant, in block 10 a 6x2 pulse signal is produced, increasing the instantaneous value of the signal X2, which enters the input of block 11; at times, when -0,5т1 х2 0.5t1, where r is constant, in block 10 a pulse signal 5 I- is generated, increasing the instantaneous value of signal Xi, entering the input of block 11, and when simultaneously for both Xi and X satisfies these inequalities; in block 10, a pulse signal 8i is produced, which increases the instantaneous value of the signal e at the input of block 11. At the moment when the signal at the output of switch 6 is not zero, the pulses 6, vi, One, Sj are not generated . The described pulse changes Xl, X2 and e in block 10 are perceived on the oscilloscope screen as bursts directed along the coordinate axes of the projective image of the three-dimensional space. The values of t, and rf are taken minimal, and then the bursts are perceived as straight lines in three-dimensional space, depicting the coordinate axes. The pulses from the output of the switch 6 are fed through the luminance extraction unit 9 to the oscilloscope beam modulation input 12. The ego leads to an increase in the brightness of the image obtained at the moments of their appearance. The change in the ratio of the amplitudes of the indicated pulses in block 9 is perceived as highlighting, by the brightness of the images, the function of exceeding the error and (or) any of the coordinate axes, and in comparison with them - the plane defining the level Dz. The pulses from the output of the key 6 highlight the peak of the bursts, which form the image of the error exceeding function, which greatly reduces the speed requirements of the key 6. The described device can be used to visually examine the various functions of two variables. In this case, the key 6 is given a signal e Y-fДз, where Y is the instantaneous values of the function under study, and instantaneous values of the arguments are fed to the inputs of the control unit 5, then on the screen of the recorder 12, at a sufficient rate of change Xl and Xg, a projective image of the function under investigation is observed the whole range of instantaneous values taken by Xx Xs, and, simultaneously, the plane intersecting it at the level Dz, as well as all three coordinate axes or direct parallel to them. The subject of the invention is a device for checking and adjusting functional converters of two variables, comprising a recorder, the first and second inputs of which are connected to the local outputs of a projective image, and a difference block, the inputs of which are connected to the outputs of a rotated and exemplary blocks of a nonlinear function, the inputs of which are connected to the first and the second inputs of the device, and the output is connected to the nerve input of the error detection unit, the second input of which is connected to the third input of the device; the output of the error detection unit is connected to the key input, the control input of which is connected to the output of the control unit, the inputs of which are connected to the first and second inputs of the device and the outputs of the first and second voltage generators of a triangular shape, in order to expand functional

capabilities, it contains a block of formation of coordinate axes and a block of brightness, the inputs of which are connected to the output of the key and the outputs of the block of formation of coordinate axes, and the output is connected to the third input of the recorder; the first input of the axis formation unit is connected to the output of the key, and its second and third inputs are connected to the outputs of the first and second triangular voltage generators, respectively; the outputs of the block for the formation of coordinate axes are connected to the inputs of the block of the projective image.