DE2460644B2 - Base-linked flip-flops - Google Patents

Description

The main patent relates to a logic circuit with one, two amplifier stages, each with one Differential amplifier containing npn transistor, in which a second operating voltage is selected so that in the absence of an input signal, the second transistor is blocked and the signal output with the Koüektoranschluss one of the two transistors is connected, in which also the base terminals of the the two transistors are connected to one another and to ground via a resistor that the Emitter connection of the transistor of the first amplifier stage directly to the signal input and via a Resistance to the first operating voltage and the emitter connection of the transistor of the second amplifier stage are directly connected to a second operating voltage and when used as a transistor in the first amplifier stage with a multi-emitter transistor at least two separately led out emitter connections are provided and each emitter connection is separately connected to the first operating voltage via a resistor each, according to claim 4

) "> from patent ... (file number: P 24 51 579.5).

The logic circuits according to the main patent allow in a very simple manner the implementation of a AND, an exclusive OR link and other links that can be used in a particularly advantageous manner

«Ο for high frequencies and for low pulse delays, which can be in the subnanosecond range, for example.

In the present invention based on the older proposal according to the main patent The task set to find further logic circuits in the form of flip-flops that are as simple as possible and are also suitable for very high frequencies.

According to the invention the object is achieved in that a third npn transistor is provided, its

so collector connection with ground, its base connection with the collector connection of the multi-emitter transistor and its emitter connection with one of the two emitter connections of the multi-emitter transistor of the first amplifier stage are connected and that the collector-base direct current amplification of the multi-emitter transistor of the first amplifier stage is lower than that of the transistor of the second amplifier stage. These Circuit arrangement according to the invention represents the basic circuit of a flip-flop by switching on Emitter followers can be used to implement flip-flops for special purposes.

The flip-flop circuits according to the invention have a special one due to their very simple structure advantageous low power consumption at high frequencies that are lower than the comparable ECL-based flip-flops. Another major advantage of the flip-flop circuits according to the invention is that this despite its simple

Structure do not have a direct connection between signal input and signal output and thus harmful effects on the circuit arrangements in front of it in the signal path can be avoided. ',

In a preferred embodiment of the flip-flop circuits according to the invention, the collector-base gain is direct current gain of the mult.emitter transistor, the first amplifier stage about half as large as that of the Transistor of the second amplifier stage. This ensures that the two transistors are uniform can be controlled into the blocking range and so there is no falsification of the output level.

A further development of the flip-flop circuit according to the invention for the implementation of a reset-set-memory flip-flop, dr.s is to be referred to briefly as RS flip-flop in the following, results from the fact that a fourth npn transistor is provided, whose collector connection to ground, whose base connection to the Set input and its emitter connection with the connection point between the emitter connection of the third npn transistor and one emitter terminal of the multi-emitter transistor is connected and that one fifth npn transistor is provided, whose collector connection to ground, whose base connection to the? ■> inverse reset input and its emitter connection with the other emitter connection of the multi-emitter transistor connected is.

This RS flip-flop according to the invention has the particular advantage that its output signals are always defined for jii any sequential and mutually arriving control signals, since with simultaneous activation at the set input and at the reset input, the signals arriving at the reset input have priority over the set signals. The J5 decoupling of the inverse output terminal Q from the feedback terminal, which in the present case is formed by the base terminal of the third npn transistor 73, also results in a particularly precise curve shape of the output signal at the inverse output terminal Q.

An additional development of the flip-flop circuit according to the invention for realizing a data-collecting flip-flop, which is to be referred to briefly as D flip-flop in the following, results from the fact that a fourth npn transistor is provided, whose collector connection to ground, whose base connection to the Clock input and its emitter connection with the connection point between the emitter connection of the third transistor and one emitter terminal of the multi-emitter transistor is connected that a fifth and a sixth npn transistor are provided, the collector connections of which are connected to one another and to ground and their emitter connections with one another and with the other emitter connection of the multi-emitter transistor are connected and in which the base terminal of the fifth transistor to the input for the inverse Clock signal is connected and the base terminal of the sixth transistor represents the data terminal.

In this D flip-flop according to the invention, the 6ü is advantageously simple construction compared to the known, usually quite complex D-flip-flops are particularly clear.

On the basis of the embodiments shown in the drawing, the invention is to be added in the following are explained in more detail. It shows

F i g. 1 an RS flip-flop according to the invention and

F i g. 2 shows a D flip-flop according to the invention.

The RS flip-flop shown in Fig. 1 essentially serves as a memory for briefly ar offered information. As is known, an RS flip-flop can be composed of two cross-coupled NOR or NAND gates. It has a first, so-called set input 5 and a second so-called reset input R, which in the present case is designed as an input R to receive the inverse reset signal: in the present case, a logical "1" is used instead of a logical "0" . The RS flip-flop according to the invention according to FIG. 1 is set by the first brief pulse with the value logic "1" which is applied to the set input, so that its output Q assumes the value logic "1". This state at output Q is retained, i.e. stored, until the first reset pulse with the value logic "0" at reset input R resets the flip-flop if there are further changes at the set input. After resetting, the output Q of the RS flip-flop according to the invention has the value logic "0". Only a further set pulse following a reset pulse can change the logic state of the RS flip-flop again. The RS flip-flop according to the invention thus behaves like a generally known RS flip-flop.

The in the F i g. 1 of the circuit of the RS flip-flop according to the invention is based on the known circuit arrangement according to the main patent. A further npn transistor 73 acting as a feedback transistor is connected to the differential amplifier arrangement consisting of the two base-coupled npn transistors 71 and 72 and the resistors R0, Ri, R2, R3 and RA Ground and the emitter terminal of which is connected to one of the two emitter terminals of the multi-emitter transistor TX . Furthermore, two npn transistors TA and 75 connected as emitter followers are provided, the collector connections of which are each connected to ground. The emitter terminal of the first emitter follower 74 is connected to the connection point PX between the emitter terminal of the feedback transistor 73 and the first emitter terminal of the multi-emitter transistor 71. The input of this emitter follower is at the same time the set input S of the RS flip-flop according to the invention.

The emitter connection of the further emitter follower 75 is connected to the other emitter connection of the multi-filter transistor 71. The base connection of this emitter follower is also the input R for the inverse reset pulses.

In the present case, npn microwave transistors of the type BFR 35A were used for the transistors. The resistors were built up as so-called chip resistors on an epoxy resin fiberglass plate, where the resistor RO has a value of 1.8 kOhm, the resistors R 1 and R 2 have a value of 50 Ohm each and the resistors R 3 and RA a value of 100 each Ohms. The operating voltage

- In the present case, UB X has a value of —2.8 V, the operating voltage —UB2 with a value of

- 1.25 V was generated from the operating voltage - UB X in the manner already described in the main patent by means of a voltage divider and a downstream emitter follower.

A test showed that such an inventive

according to the RS flip-flop can change its logic state in a few 100 picoseconds. The transistors Ti and 7-2 were selected so that the collector-base equilibrium of the multi-emitter transistor Ti of the first amplifier stage was about half as large as that of the transistor T2 of the second amplifier stage.

Such an RS flip-flop according to the invention was used as a pulse shaper at different high pulse repetition frequencies used, with an exact setting and resetting function in the sub-nanosecond range revealed. In this case, the control took place via lines of different lengths with complementary lines Signals, so that short pulses with a very constant duration can be generated in a simple manner.

The D-F! Ipf! Op shown in Fig. 2 is mainly used to compensate for runtime differences, the / between signals to be linked occur. The compensation of the running time differences happens with the help of synchronizing clock pulses, until their occurrence the entered Signa! in remains stored in the D flip-flop.

The D flip-flop shown in FIG. 2 is constructed analogously to the RS flip-flop shown in FIG. 1 and also consists of a basic flip-flop circuit and upstream emitter followers. The basic flip-flop circuit is the same as that of the RS flip-flop. It consists of the npn multiemitter transistor 7t, the npn transistors 7 ~ 2 and Γ3, as well as the resistors R 5 to R 9. The value of the resistor / 5 is 1.8 kOhm. the values of the resistors R 6 and R 7 are 50 ohms and those of the resistors R 8 and R 9 are 100 ohms. At the connection point P2 between the emitter connection of the feedback transistor Γ3 and the one emitter connection of the multi-emitter transistor Tl, the emitter connection of an npn transistor 7-9 acting as an emitter follower is connected, the collector connection of which is connected to ground and the emitter connection of which represents the clock input C of the D flip-flop. The D flip-flop according to the invention contains two further emitter followers whose collectors are connected to one another and to ground and whose emitters are also connected to one another and are connected to the other emitter terminal of the multi-emitter transistor Ti . The base connection of one emitter follower T10 forms the connection C for the inverse clock signal, while the base connection of the other emitter follower represents the data input D.

The operating voltages correspond to those of FIG. 1. The operating voltage -UBi has a value of -2.8 V and the operating voltage -UB 2 has a value of -1.25 V, the operating voltage - UB2 in the same way as with the RS -Flip-flop according to the fig. 1 was generated from the operating voltage - UB i. Microwave transistors of the type BFR 35A were also used as transistors, the multi-emitter transistor TX being constructed from two microwave transistors of the type mentioned above.

The function of the D flip-flop according to the invention corresponds to the known D flip-flops.

A special application of the D flip-flop according to the invention relates to a so-called T flip-flop, which is created by inserting an additional delaying connection from the inverse output Q to the data input D. The delay in the signal fed back from the inverse output Q to the data input D is so great that the fed back signal only becomes effective after the previous clock pulses at the data input D have ended. Such TI lipflops are advantageously used in the construction of binary counters for very high frequencies.

1 sheet of drawings

Claims (4)

Patent claims: 1.Logic circuit with one, two amplifier stages each with a differential amplifier containing an npn transistor, in which a second operating voltage is selected so that the second transistor is blocked in the absence of an input signal and in which the signal output is connected to the collector terminal of one of the two transistors, In addition, the base terminals of the two transistors are connected to each other and via a resistor to ground, that the emitter terminal of the transistor of the first amplifier stage directly to the signal input and via a resistor to the first operating voltage and the emitter terminal of the transistor of the second amplifier stage directly to a second Operating voltage are connected and in which a multi-emitter transistor with at least two separately led out emitter connections is provided as a transistor in the first amplifier stage and each emitter connection is connected separately to the first operating voltage via a resistor Annung is connected, according to claim 4 of patent ... (file number: P 24 51 579.5), characterized in that a third npn transistor (T3) is provided, whose collector connection to ground, whose base connection to the collector connection of the multi-emitter transistor and the emitter terminal of which is connected to one of the two emitter terminals of the multi-emitter transistor (TX) of the first amplifier stage and that the collector-base direct current gain of the multi-emitter transistor (TX) of the first amplifier stage is lower than that of the transistor (T2) of the second amplifier stage. 2. Logic circuit according to claim 1, characterized in that the collector-base direct current gain of the multi-emitter transistor (Ti) of the first amplifier stage is about half as large as that of the transistor (T2) of the second amplifier stage. 3. Logic circuit according to claims 1 or 2 in the form of an RS memory flip-flop, thereby marked, that a fourth npn transistor (TA) is provided, whose collector connection to ground, whose base connection to the set input and whose emitter connection to the connection point (PX) between the emitter connection of the third npn transistor (T3) and one emitter connection of the multi-emitter transistor (TX) is connected and
that a fifth npn transistor (T5) is provided, whose collector connection is connected to ground, whose base connection is connected to the inverse reset input (R) and whose emitter connection is connected to the other emitter connection of the multi-emitter transistor (TX) . 4. Logic circuit according to claims 1 or 2 in the form of a data-collecting flip-flop, characterized in that that a fourth npn transistor (T9) is provided, its collector connection to ground, its base connection to the clock input (C) and its emitter connection to the connection point (P2) between the emitter connection of the third transistor (T3) and one emitter connection of the multi-emitter transistor ( TX) is connected,
that a fifth and a sixth npn transistor (T 10, TIl) are provided, whose collector terminals are connected to one another and to ground and whose emitter terminals are connected to one another and to the other emitter terminal of the multi-emitter transistor (TX) and in which the base status of the fifth transistor (T 10) is connected to the input for the inverse clock signal (C) and the base connection of the sixth transistor (TiX) represents the data connection ^.