SU577650A1 - Saw-tooth pulse generator - Google Patents

Description

The invention relates to a pulse technique. It can be used in various fields of radio engineering and automation. A generator of triangular pulses is known, which contains a reference element, a pulse amplifier and an emitter follower (1 |. However, such a device does not ensure the generation of symmetric oscillations. The closest technical change is a triangular pulse generator containing a threshold stabilizer element, a diode , the time setting the capacitor, in parallel with which the bit element 2 is turned on. However, such a device has a limited frequency tuning range The aim of the invention is to expand the range of tuning the oscillation frequency. For this purpose, a triangular pulse generator containing a threshold element, a current stabilizing element, a discharge element, a diode and a time specifying a capacitor is connected to an amplifier whose input is connected to the Be.i. element, the non-inverting output — with the input of the threshold element MeHi; j, and the inverted output — with the input of the discharge element. In the drawing, a structurally available E.pkgpneska scheme of the proposed tri-generator generator is given. The device contains a threshold element I, which can be used as a single-transistor transistor or other switching devices, time setting capacitor 2, current stabilization element 3, as which can serve as a transistor cascade, creating a voltage-independent collector and current, low-voltage element 4, the diode 5 and the amplifier 6. The device operates as follows. After switching on the power source, the charge of the capacitor 2 starts through diode 5 and the current stabilizing element 3. At this time, the locking voltage from the load of the inverting output of the amplifier 6 is applied to the discharge element 4. The threshold device 1 is closed at this moment, the amplifier 6 is locked. When the voltage at the anode of diode 5 exceeds a level equal to the sum of the level of operation of threshold device 1 and the voltage between the input of amplifier 6 and the single-ended output, the threshold device I turns on, its input impedance is lost. by leap

The voltage at the anode of diode 5 is changed, causing it to be locked, which ensures that the current-stabilizing element 3 is disconnected from the capacitor 2. At the same time, turning on the threshold device 1 causes the amplifier 6 to unlock, the voltage drop on the inverter output of the amplifier b decreases, | 1, the supply of the blocking voltage to the current stabilizing element 3 and the discharge element 4 is opened. The capacitor 2 begins to discharge through the current-stabilizing element 3. As soon as the voltage on the capacitor 2 drops to the closing level of the threshold device 1, the diode 5 is opened, the current flowing through the threshold device I decreases, which causes the fast locking of the threshold device 1, the locking of amplifier 6 , the discharge element 4 and the connection through diode 5 of the current-stabilizing element 3 to the capacitor 2. A new charge cycle of the capacitor 2 begins, the processes in the device are repeated. The output voltage is removed from capacitor 2.

The oscillation period of the device is determined by the sum of the charge and discharge times of capacitor i, which depend on the voltage U, equal to the difference between the turn-on and turn-off voltage of threshold device I. If the charge and discharge of capacitor 2 are made through current-stabilizing element 3 and discharge The first element 4 is the charge current L „is equal to the current

J

bit Yes (); then the oscillation period of the device can be determined by the formula

  and „, С,

2 .- "with,

: G - 5 3JP

where C is the capacitance of the capacitor 2

Claims (2)

1. Copyright certificate (((. R № 351305, M.Kl.I 03 K 4/50, 1970. 2. Instruments and equipment - experiment, 1974. № 2. fig. four.