DE1057173B - Self-locking transistor circuit - Google Patents

Description

GERMAN

The present invention relates to electrical Trigger circuit and in particular such circuits equipped with transistors, in which a current flow through a transistor upon receipt of an electrical signal to a predetermined Time initiated or upon receipt of an electrical signal from a predetermined one Minimum size is triggered.

The use of transistors of opposite conductivity has been used earlier, in the following also called complementary transistors, known in a freely oscillating multivibrator. Included becomes the voltage dropping between emitter and collector of each transistor between emitter and Base of the other transistor applied, so that the two transistors in a similar conduction state to move. A positive feedback path from the output transistor to the other transistor is formed by a capacitor and thus a cyclical on-off oscillation circuit created. This known multivibrator is essentially an astable device and is suitable not for optional bistable operation. In addition, the use of transistors that made of different semiconducting materials, not very good in this circuit carry out. However, it is often desirable to use transistors of this type. Also changes the timing curve of the circuit changes with changes in the applied electrode biases. This property is undesirable for many circuit applications.

There is also known a bistable transistor circuit made up of two interconnected transistors is formed. The known arrangement is a kind of switch that, controlled by the Level of the applied voltage, once a threshold value has been exceeded, the other one Times a low resistance in a circuit. This circuit is designed as a two-pole and knows no difference between output and input signal. An adjustable delay between input and output signal is accordingly not possible.

One purpose of the present invention is to provide a timing trip circuit for the generation of an output signal at a predetermined adjustable time after the Giving an input signal.

Another purpose of the invention is to provide a bistable trip circuit, the transistors -Used, transistors, which are formed from different semiconducting materials, without disadvantageous Effects can be used.

Self-locking transistor circuit

Applicant:

Westinghouse Electric Corporation,
East Pittsburgh, Pa. (V. St. A.)

Representative: Dipl.-Ing. A. Essel, patent attorney,
Munich 2, Witteisbacherplatz 2

Claimed priority:
V. St. v. America March 27, 1956

Walter Bernhard Guggi, Palo Alto, Calif. (V. St. Α.),
has been named as the inventor

Another purpose of the invention is to provide a delayed release circuit which is shown in with respect to its time setting characteristic is essentially independent of voltage fluctuations.

Another purpose of the invention is to provide a bistable trigger circuit for generation of an output signal after receiving an input signal, each time the input signal correct length reached.

The above-mentioned tasks are solved without the deficiencies inherent in the acquaintance, if at a normally-off transistor circuit with two input and two output terminals and two complementary transistors with feedback branches between the collector of one and the base of the other transistor according to the invention, the emitter potential of the output transistor for the purpose of adjustable time delay between input and output signal.

To set the emitter potential, a

Voltage divider with movable tap are used.

According to a development of the invention, the

Base of the output transistor with the collector of the other transistor via a diode in the forward direction be connected.

Advantages and features of the present invention are detailed below Description in conjunction with the drawing, which represents a preferred embodiment of the invention, made clear. However, it is expressly pointed out that the drawing is only for the purpose of It is intended to be illustrative and not intended as a definition of the limits of this invention.

909 510.330

In the drawing, two transistors 23 and 30 of opposite conductivity types are shown, where transistor 23 is shown as type NPN and transistor 30 is shown as type PNP. Through appropriate Changes in electrode bias and polarity of the circuit components described below the conductivity types of the transistors shown in the drawing can be interchanged will. A bias source 1 is provided for the transistors 23 and 30, which bias source Potential sources 2 and 3 includes either batteries or a power supply regulated voltage, with potentiometer 5 connected in parallel to potenti.alquelle 2; ._ is and potentiometer 9 and resistor 13, which are in series are connected, connected in parallel to the potential source 3 are. The negative connection of the potential source 2 is connected to the positive connection of the source 3. The collector terminal 31 of the transistor 30 is connected to the negative terminal dfer source 3 via the output impedance 15 connected to which the output terminals 14 and 16 are located. The emitter 35 of the transistor 30 is connected to a tap 7 of the potentiometer 5. The base electrode 33 of the Transistor 30 and the collector electrode 29 of transistor 23 are through a half-wave rectifier 45 connected, the purpose of which is to reduce the leakage current between said transistors, which occurs when transistor 30 is made of semiconducting materials such as silicon and / or germanium, to a minimum to reduce. The leakage current in case of temperature changes is higher with germanium, so that the Voltage fluctuation between collector 29 and base 33, which is thereby described in the herein Circuit arises, detrimental effects on the operation of the circuit described below exercises.

Preferably, rectifier 45 is made of silicon, so that the leakage current with temperature changes greatly is low. The base bias for transistor 23 is provided by rectifier 17, the between the junction of potentiometers 5 and 9 and the base 27, so that the cathode of the rectifier is connected to base 27, is switched. Resistor 18, the emitter 25 of the transistor 23 connects to the tap 11 of the potentiometer 9, the purpose is to give the transistor the character of Basic circuit to give the circuit in fioch greater extent from changes in the voltage supply becomes almost independent.

A capacitor 37 is between the positive terminal of the potential source 2 and the collector 29 of the Transistor 23 switched and has the purpose of switching the speed of the .Wechels the emitter and Determine the collector bias of transistor 23. For certain applications, stray capacitance can be used a total capacitance between the electrodes and lines form, which is sufficient to omit the capacitor 37. The input terminals 39 and 41, to which a controllable variable resistance device may be connected, e.g. B. a A transistor, a photodiode, a transductor or a relay are connected to the .connections of the capacitor 37 connected. _ ':> ·

A positive feedback circuit from collector 31 of transistor 30? U, r base 27 of transistor 23 is through capacitor 21 and half-wave rectifier 19 connected in parallel, the Cathode of the rectifier;)}.? connected to base 27 is. Task of the Konden§a, to.rs. 21 it is- ,, a-signal, which brings the transistor to saturation or to block, pass from collector 31 to base 27 depending on the sense of the voltage change at collector 31. Rectifier 19 has the purpose of To keep transistor 23 in the switching state of transistor 30.

The base bias for transistor 23 provided by potentiometer 9 is set so that Transistor 23 in the region of its characteristic curve

ίο (collector current to voltage between emitter and Collector) works where the collector current with voltage change between emitter and collector in the is essentially constant. Capacitor 37 is thus charged by a live circuit, from the line from the emitter to the collector of the transistor 23, the resistor 18, the part of the Potentiometer 9 between tap 11 and the junction of potentiometers 5 and 9 and the Potential source 2 exists. ,

. The operation of the circuit described above is described below:

The circuit is believed to be in a stable "on" state, which creates a Output voltage is supplied via output impedance 15. Base 33 is negative with respect to Emitter 35 due to the positive bias on emitter 35, which is supplied by ..Potentiometer'5; the transistor 30 is therefore conductive. The positive bias on collector 31 with respect to point 11 am Potentiometer 9 is applied to base 27 by rectifier 19 to make transistor 23 conductive do. Collector 31 is positive with respect to base 27 when tap 7 of potentiometer 5 is correct is set in order to compensate for the voltage drop across transistor 30. Now suppose that

.. capacitor 37 through the to the terminals 39 and 41 connected control device is short-circuited. Base 33 is with respect to emitter 35 by the Voltage between tap 7 and terminal 39 ″ positive in order to reduce the current flow through transistor 30 and to lower the voltage across resistor 15. Capacitor 21 transmits the voltage surge at collector 31 on base 27, and the collector current flowing through transistor 23 will therefore drop steeply.

The negative voltage surge on base 27 is

... strengthens, reversed and led back to base 33, whereby the current flow through transistor 30 is further reduced until the current flow through it is complete ceases and this causes the output voltage at the output impedance 15 to disappear. It was found that even with a very slow and. minor change caused by connections 39 and 41 going input voltage when approaching a certain switching voltage the circuit is subject to a tilting effect.

If the short circuit of the 'capacitor 37 is removed, the capacitor charges through the charging path described above. The condenser loads itself with constant and. certain speed until base 33 with respect to emitter 35 a negative Reached value and thus a current flow through transistor 30 causes. A voltage occurs in output impedance 15 and between base 33 and collector 31; on. This tension is applied to the base 27 of the transistor 23 placed, amplified, reversed and ■ given on base 33, uni so the current flow through Increase transistor 30 further. The circuit breaks then into a conductive state and generates an output voltage at "resistor. 15, which essentially

borrowed a step function is ... : "". ' .

The position of the tap 7 of the potentiometer 5 determines the charging voltage on the capacitor 37, at which the switching process takes place. Typically, tap 7 is as close to the junction as possible to attach the potentiometer 5 and 9, in order to take advantage of the advantage of the full charge. the However, the position of the tap serves as a time selector, since its local position with the switching time is practical for all Purposes are linearly related.

The circuit described above for transistor 23 with a zero potential base is insofar advantageous as it helps to compensate for time changes caused by voltage fluctuations. The basic circuit generates a proportional constant change in current as Function of the supply voltage change and therefore reduces the time for the setting cycle at increasing tension, and vice versa. In addition, an increasing voltage also increases proportionally adjusts the adjustment cycle due to the increased voltage in adjustment capacitor 37 and therefore compensates for the decrease in time caused by the increase in the constant current in transistor 23. The circuit should therefore approach 100% equalization with every voltage change if the transistor 23 is connected to a grounded base.

It should be noted that rectifier 17, in addition to having the bias voltage supplied by potentiometer 9 Base 27 of transistor 23 couples, including the formation of a short circuit between collector 31 and the Junction of potentiometers 5 and 9 prevented when transistor 30 is conductive. Next is to note that rectifier 45 covers base 33 of capacitor 37 while the capacitor is charging separates and at the end of the charging process still ensures current flow, so that the setting circuit for all practical purposes relieved and the charging of the capacitor as a function of time is linear. In addition, if transistor 30 and capacitor 37 were made of semiconducting germanium, the above-mentioned leakage current would occur would be charged, which the rectifier 45 prevents.

While the implementation of the invention according to the preceding description is preferred, those skilled in the art will see further possible applications of this invention in its broadest interpretation do not deviate from the present invention.

Claims (3)

Patent claims: 1. Self-locking transistor circuit with two input and two output terminals and two complementary transistors with feedback branches between the collector of one and Base of the other transistor, characterized in that the emitter potential of the output transistor for the purpose of the adjustable time delay between input and output signal is adjustable. 2. Self-locking transistor circuit according to claim 1, characterized in that for setting A voltage divider with a movable tap is used for the emitter potential. 3. Self-locking transistor circuit according to claim 1 or 2, characterized in that the base (33) of the output transistor to the collector (29) of the other transistor (23) a diode (45) is connected in the forward direction. Considered publications:
U.S. Patent No. 2655609. 1 sheet of drawings © 909 510/330 5.59