JPS58218223A - One-shot multivibrator - Google Patents

Abstract

PURPOSE:To prevent malfunction due to power source variation, by providing a switching transistor (TR) between a power source and the base of the 2nd TR of a one-shot multivibrator consisting of the 1st and the 2nd TRs which operate in inversion relation each other. CONSTITUTION:When a trigger switch 4 is not closed, i.e. in a stationary state, a TR1 is off, a TR6 is on, and the collector potential is at a level L, so a TR12 is on. When the emitter resistance 13 of the TR12 is set much less than a resistance 9 for setting an inversion time, the base current of the TR6 is supplied through the resistance 13 and the TR6 never malfunctions to turn off even when a capacitor 7 is discharged through a resistance 2 owing to variation in power supply voltage. Once the switch 4 is closed, the TR1 turns on, the TR6 turns off, and the TR12 is biased reversely to turn off. Consequently, the resistance 13 becomes irrelevant to the operation and the inverting operation time is set by the resistance 9 and capacitor 7.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a one-shot multivibrator, and particularly to a one-shot multivibrator suitable for low voltage power supplies.

The circuit shown in FIG. 1 is a conventionally commonly used one-shot multivibrator. In the figure, (1
) is the first transistor constituting the circuit, its emitter is grounded, its collector is connected to the power supply line (3) via a resistor (2), and its base is a trigger switch that is closed in reverse operation. (4) and is connected to the power supply line (3) via the resistor (5). (6) is a second transistor whose base is connected to the collector of the first transistor (1) through a capacitor (7) and whose emitter is grounded, and whose collector is connected through a resistor (8). It is connected to the power line (3). (9) is connected between the base of the second transistor (6) and the power supply line (3), and works with the capacitor (7) to set the inversion operation time of the one-shot multivibrator. An inversion time setting resistor (10) is a feedback resistor connected between the collector of the second transistor (6) and the base of the first transistor (1), and Ql is an output terminal. In such a circuit, in a steady state when the trigger switch (4) is open, the first transistor (1) is in a non-conducting state and the second transistor (6) is in a conducting state, so that the output terminal aυ has an L (low ) level signal is being output. In such a state, the trigger switch (4
) is closed, the resistor (5) and the trigger switch (4
), a bias current is supplied to the base of the first transistor (1), so that the first transistor (1) is inverted to a conductive state. When the first transistor (1) is inverted to a conductive state, the base potential of the second transistor (6) drops through the capacitor (7), so that the second transistor (f6)ld is inverted to a non-conductive state. When the second transistor (6) is reversed to a non-conducting state, the collector potential increases, and the increased voltage is applied to the base of the first transistor (1) via the feedback resistor (1@), so that the trigger switch (4) Even when the first transistor (1) is opened, the first transistor (1) remains conductive.

When the first transistor (1) is in a conductive state, the capacitor (power is charged by the current supplied through the inversion time setting resistor (9), and as the charging is carried out, the second transistor (6) ) increases. When the base potential of the second transistor (6) reaches a predetermined value, the second transistor (6) is reversed from a non-conductive state to a conductive state, and as a result, the first transistor (1) is reversed from the conductive state to the non-conductive state, and the "one-shot multi-by-play" returns to the steady state. When the trigger switch (4) is closed, the above-mentioned operation 1- is carried out, and as a result, +al'jJ terminal 0υ Signal system at H (high) level for a predetermined time: Output. In such a circuit, when the potential of the power supply line (3) drops due to fluctuations, the electric charge stored in the capacitor (7) is transferred through the resistor (2). When such a discharging operation is performed, a current flows through the inversion time setting resistor (9) to supplement the discharge current of the capacitor (7), but the inversion time setting that constitutes the one-shot multivibrator is Since the resistance value of the reversal time setting resistor (9) is large, the inversion time setting resistor (9) has a large resistance value.
The current flowing through the capacitor (9) will flow through the capacitor (force), resulting in insufficient current flowing to the base of the second transistor (6).
6) is reversed to a non-conducting state. When the second transistor (6) is reversed to a non-conducting state, the feedback resistor (
10) through 1 to the base of the Ml transistor (1), so that the first transistor (1)
) becomes conductive, and the same operation as when the trigger switch (4) is closed is performed. As described above, the one-shot multivibrator shown in FIG. 1 has a problem in that it malfunctions when the potential of the power supply line (3) drops due to fluctuations in the power supply voltage. One way to solve this problem is to configure the second transistor (6) with a Darlington-connected transistor, but in this method, the operating base potential of the Darlington-connected transistor is necessarily high, so the power supply voltage is low. The present invention was made in view of the above points, and the second
A detailed explanation will be given with reference to the embodiment shown in the figures. In the figure, the same parts as those in the conventional example shown in FIG. 1 are given the same numbers. In FIG. 2, (1) is a switching transistor whose emitter is connected to the power supply line (3) and whose lid is connected to the base of the second transistor (6) via a control resistor θ3,
Its base is connected to the collector of said second transistor (6) via a resistor Q4). In such a configuration, the resistance value of the control resistor (13) is set to a sufficiently smaller value than the resistance value of the inversion time setting resistor (9).

The present invention is constructed as described above, and its operation will be explained next. In a steady state where the trigger switch (4) is not closed, the first transistor (
1) is in a non-conducting state, and the second transistor (6) is in a conducting state. When the second transistor (6) is in a conductive state, the collector potential of the second transistor (6) is at L level, so the switching transistor (121) whose base is connected to the collector of the second transistor (6) is It is biased and conductive.Therefore, under normal operating conditions, the switching transistor 〇′
Due to the conduction of IJ, the control resistor 03 becomes the inversion time setting resistor (
9), and the pace current is supplied to the second transistor (6) mostly through the control resistor Q3), which has a small resistance value. As a result, the potential of the power supply line (3) drops due to fluctuations in the power supply voltage, and even if the charge stored in the capacitor (power) is discharged through the resistor (2), a current that compensates for the discharge current and a second transistor (6) are generated. Since the biasing current flows through the control resistor 0, a malfunction in which the second transistor (6) is reversed to a non-conducting state does not occur.

In this way, the present invention operates in a constant state, and next, the inverse i operation will be explained in detail. When the trigger switch (4) is closed, the first transistor (1
) is reversed to a conductive state, and the second transistor (6) is accordingly reversed to a non-conductive state. When the second transistor (6) is inverted to a non-conductive state, the collector potential becomes H level, so that the switching transistor 04 is reverse biased and becomes non-conductive. Therefore, when the one-shot multivibrator is inverted, the switching transistor α becomes non-conductive and the control resistor 03 becomes irrelevant to the circuit operation, so the inversion time is determined by the inversion time setting resistor (9) and the capacitor (
It will be set by force.

As explained above, the one-shot multivibrator of the present invention not only can prevent malfunctions due to fluctuations in power supply voltage with a simple circuit configuration, but also has no effect on the reversing operation time. Settings can be made easily, and the operating potential of the transcinator does not become high, so it is extremely effective when implemented in a power supply voltage gate device.

[Brief explanation of the drawing]

FIG. 1 shows a conventional one-shot multivibrator, and FIG. 2 shows an embodiment of the present invention. Explanation of main drawing numbers (1)...First transistor, (3)...Power line, (4)...Trigger switch, (6)...Second
Transistor, (7)... Capacitor, (9)...
・・Resistance for setting the inversion time, α ・・Switching transistor, (131 ・・Control resistor. Fig. 1)

Claims (1)

[Claims] (1) A first transistor that is inverted to a conductive state by a switching operation of a switching means provided in a base circuit, and a base is connected to the collector of the first transistor via a capacitor, and the conductive state of the first transistor is a second transistor that is inverted to a non-conducting state by inversion of , and an inversion time setting device that is connected between the base of the second transistor and the power supply line and that sets an inversion operation time in cooperation with the capacitor. In a one-shot multivibrator consisting of a resistor, a control resistor having a resistance value sufficiently smaller than the emitter-collector path of the switching transistor and the inversion time setting resistor is connected in series between the base of the second transistor and the power supply line. A one-shot multivibrator 0 characterized in that, at the same time, the switching transistor is connected so as to be reversed to a non-conducting state by reversing the second transistor to a non-conducting state.