SU433640A1 - - Google Patents

Description

one

The invention relates to the field of automation and telemechanics.

Distributor circuits are known that contain a series of cells, each of which is used as a pulse shaper of the required parameters.

However, aging of the circuit elements and temperature changes cause inaccuracy of the phase shift of pulses in the cells, and random signals can trigger one or several cells, as a result of which, for an arbitrarily long time, two or more cells can be in the on-state circuit for an arbitrarily long time (interference circulation) which is typical for ring distributors.

The purpose of the invention is to increase the accuracy of the phase shift of the output pulses of the cells and improve the noise immunity of the device.

This is achieved by introducing into the distributor a controlled blanking cascade, the input of which is connected to the anode of the diode, the cathode of which is connected to the output of the clock generator and the anode of another diode, the cathode of which is connected to the outputs of all of the discharge cells, the output of the stage of blanking is connected to the input cells of the first discharge, and the control. my input of the blanking cascade is connected to

cells of all bits except the last.

The drawing shows a block diagram of the proposed distributor.

The distributor contains a series of serially connected cells 1, each of which is an impulse shaper, for example a retarded blocking generator. The input 2 of the first cell is connected to the output of the controlled cascade of blanking 3, the control input 4 of which is connected to the cells of all bits except the last. The inputs 5 of all the cells are connected to the output of the breaking pulses of the clock generator 6, assembled according to the block-generator circuit operating in the auto-oscillatory mode, without quenching the back edge of the output pulse. The clock pulse generator is designed to form two sequences of alternating pulses: positive and negative, with negative pulses being delayed relatively positive by the duration of the latter, since emitting at the falling edge of the positive pulse is used to obtain a negative pulse, which is achieved using two diodes 7 and 8, included at the output of the clock generator so that -. the cathode of one and the anode of the other is connected to the common exit point of this generator, and the anode Vågå of said diode is connected to the input of a controllable blanking stage, the second cathode - is connected to the inputs of all the cells of the distributor. Diodes 7 and 8 separate the pulses of the clock generator into negative and positive, forming the outputs of triggering and disrupting pulses. Positive pulses are applied to all cells at the same time and are used as tearing pulses, blocking cells, and negative pulses are fed through the blanking cascade only to the first cell and used as triggering cells. Moreover, the trigger pulse passing through the blanking cascade is possible only if all cells are in the closed state, as a result of which no control voltage is applied to the cascade cascade. In the absence of a control voltage, the blanking ascade is locked and the start-up pulses are passed to the input of the first cell. If there is a control voltage on the input of the blanking cascade control circuit, the latter, while in the open state, shunts the negative trigger pulses — not letting them go to the input of the first cell. : The device works as follows. At the initial moment, when the supply voltage is switched on, all cells are in the locked state, which does not change with the arrival of the first break pulse. Immediately after the termination of the pulse, the first negative trigger pulse arrives at the input of the blanking stage, which passes to the input of the first cell and starts it. From the moment the first cell is switched on to the control circuit of the blanking cascade, the control voltage from the output of the same cell is applied, preventing the passage of the following trigger pulses to its input until the end of the formation process and impulse. With the arrival of the second tearing pulse, the first cell closes forming the rear edge of the output pulse, which simultaneously, after differentiation, is supplied to start the second cell — the former together with the second break pulse — the generator pulse duration is shorter than the duration of the differential pulse formed by the cell. The second cell opens, and the control piping is applied again to the cascade of blanking. With the arrival of the third break pulse, the second cell closes, its input pulse differentiates and the third cell starts the third pulse, the control voltage from which at this moment begins to apply to the control circuit input of the blanking cascade, etc. With the inclusion of the last cell, the output of which is not connected to the control circuit input of the blanking cascade, the latter is restored at the end of the control voltage from the previous cell and with the arrival of the next trigger pulse passes it to the input of the first cell. There is a certain time from locking the open cell with the stall pulse and starting it with the output pulse of the next cell, due to the inertia of transients, during which all the cell-formers are locked and the control circuit of the blanking cascade is not given. equal voltage, which under certain conditions can cause a failure in the pulse distributor. To avoid a false start of the first cell (so that the trigger pulses do not pass through the cascade of blanking to the input of the first cell during the transient time), a constant delay time of the controlled blanking cascade is necessary to choose many times these transients, which is achieved by introducing an integrating element to the control circuit of the blanking cascade. Thus, the presence of blanking in the distributor circuit of the cascade, as well as the control of the work of the cells-shapers by the generator of clock pulses, provide a high degree of accuracy of the phase shift of the OUTPUT cell impulses relative to each other. When starting any cell with a random signal, the interference does not have the conditions for continuous circulation through the cell-driver circuits, since the input of the first cell is associated with the output of the trigger pulses of the clock generator, and not with the output of the last cell. Preferred Invention A pulse distributor containing a clock generator and serially connected discharge cells, each of which contains a pulse driver, characterized in that, in order to increase the accuracy of the phase shift between output pulses and increase noise suppressors (device height, a controlled blanking stage was entered, whose input connected to the anode of the diode, the cathode of which is connected to the output of the clock generator and to the anode of another diode, the cathode of which is connected to the outputs of all the cells of the bits, the output askada blanking connected to an input of the first discharge cell, and a controllable input stage is connected with blanking che1kam7vsohraGr rows kbp M7 of the latter.