SU510722A1 - Device for determining the voltage increment module - Google Patents

Description

one

The invention relates to the field of computer technology and can be used in hardware analysis of voltage graphs.

A device for determining a voltage increment module is known, which contains a differentiator connected to the device input, the output of which is connected via two-sided threshold element to the control inputs of two keys, two cells with diode-capacitive memory connected to the input terminal through the keys specified, the outputs of the storage cells connected to the inputs of the subtraction unit.

The drawback of the device is the presence of redundant logical connections between the circuit elements.

To simplify the device proposed in it, the output of each of the two diode-capacitive storage cells is connected to the input of the device through a diode, the polarity of which is inverse to the polarity of the diode of the corresponding storage cell.

FIG. 1 is a block diagram of the described device; in fig. 2 - graphics

voltage changes on circuit elements as a function of time.

The device contains differentiator 1, two-sided threshold element 2, keys 3,4, diode-capacitive memory cells 5,6, respectively, of the opposite direct polarity, separation diodes 7,8, subtraction unit 9.

The device works as follows. The voltage U is fed to the input of the differentiator 1, as well as through the keys and isolating diodes applied to the storage capacitors of the storage cells 5 and 6. The threshold element 2 is triggered when the predetermined value of the modulus of the derivative and

There are three main conditions in the operation of the device.

Claims (4)

1. The derivative of the input signal is positive (U) and at time t-) (Fig. 2) reaches a critical value. This triggers the threshold element 2 and removes the voltage from the control inputs of the keys 3 and 4. The keys are closed, as a result, the charge circuit of the capacitor and the capacitor a of the i cell 6 is broken. The voltage at the cell output 6 in the interval i, - t remains constant and (i) —Capacitor of cell 5 continues to charge through diode 7, the voltage across its plates in this interval repeats the input voltage curve. At the output of the device, a voltage of 17 - U appears (t is equal to the signal increment in this area 2. When reducing the derivative value and below the critical value of tg (Fig. 2), the output of the threshold element 2 is the voltage causing the keys 3 and 4 to open. The capacitor of the storage cell 6 abruptly charges to the value of the input voltage U (tj) Further, until fc, this capacitor continues to charge through key 4, and the voltage at output i of cell 6 repeats the input voltage curve. The capacitor of cell 5 in this interval is charged through diode 7, and the output voltage This cell also repeats the input curve on the In the interval tJ-t4, the memory cell de-energizers are discharged via switch 3 and diode 8, respectively. The output voltage of the device in the interval tj, t-y is zero, since the same voltages are applied to the inputs of the subtraction unit. 3. At time b, the derivative module U again reaches a critical value, triggers threshold element 2 and closes keys 3 and 4. As a result, the voltage at the output of the cell 5 in the interval is maintained at a constant value of U (t). The voltage at the output due to the analogous discharge circuit through diode 8 repeats the curve of the input signal U. At the output of the device, a voltage appears and (t) - and. equal to the negative value of the input signal increment in this region. But, since the increment Alf in the plot is negative, the impulse :; output voltage (voltage has a positive polarity, as in the first case. Thus, the output voltage of the device is equal to the input voltage increment module in areas with large (greater than a predetermined level) derivative values. The formula is from A device for determining the voltage gain module, containing a differentiator connected to the device input, the output of which is connected via two-sided threshold element to the control inputs of two keys, two diode capacitance memory cells of different polarity and, connected to the input terminal through the indicated keys, the outputs of the storage cells are connected to the inputs of the subtraction unit, so that, in order to simplify the device, the output of each of the two diodemic storage cells is connected to the input of the device through a diode, the polarity of which is the inverse of the polarity of the diode of the corresponding storage cell. m I P