DE3941840A1 - Electronic interface circuit for FEt and bipolar transistors - uses clamping FET saturation of bipolar transistor - Google Patents

Abstract

The circuit, comprising five FETs (M1...M4,MK) and two bipolar transistors (Q1,Q2) connected between supply voltage (V1) and earth (V2). The circuit is a FET-TTL Interface circuit, and the collector of the second bipolar transistor (Q2) is connected to a clamping FET (MK) which prevents the transistor (Q2) going too heavily into saturation. The ratio of the channel within of transistors (MK,M3) are defined. Pref., the FETs are CMOS devices, with complementary transistors (M1,M2) and (M1,M3). USE/ADVANTAGE - CMOS-TTL Interface circuits. Prevents saturation of output transistors.

Description

The present invention relates to a circuit according to the Preamble of claim 1.

In particular, the present invention is concerned with a CMOS-TTL implemented in BICMOS technology Interface circuit with two arranged in push-pull circuit Bipolar transistors, in which a control of a Bipolar transistor in an undesirably strong state of saturation is prevented.

Regarding the technological background of the invention, it should be noted that recently a need for CMOS-TTL interface circuits for use in such circuits arose, which has both CMOS circuits and TTL Have circuits. With such combined circuits for example, highly integrated logics in  CMOS technology is realized while that of these Logic driven driver circuits in bipolar Technology.

At the interface between CMOS circuits and TTL Circuits or bipolar circuits become interface circuits needed for level conversion and adjustment. The There are requirements for level conversion and adaptation from the fact that the CMOS technology essentially for the Driving purely capacitive loads is designed because the CMOS logic works statically currentless. On the other hand, work TTL circuits with bipolar transistors that function as current-controlled components take static electricity. At the latter circuits have the switching threshold between the two logical states at double a diode forward voltage and thus around 1.4 V. This switching threshold is based on the usual supply voltage of 5 V unbalanced. CMOS logics work usually also with a supply voltage of 5 V. In the case of CMOS logic, the switchover threshold freely in the middle between the supply voltage and the ground potential can be set to 2.5 V.

To adapt these two technologies to each other Interfaces or interface circuits required.

Thanks to the BICMOS technology that has been tried and tested for a few years there is now the possibility of a complete system from CMOS components and fast bipolar transistors to be integrated on a common chip. The necessary Interface circuits are made up of CMOS transistors and bipolar ones Transistors built. Another area of application CMOS-TTL interface circuits are peripheral Interface circuits that use the ones in the chip at the cip output CMOS level in the output often required Convert TTL level.  

From the Hitachi Electonic Components company brochure, BICMOS gate array HG 28, 1986, is already a CMOS-TTL Interface circuit known. In the known interface circuit a CMOS input stage is provided, the two Bipolar transistors in push-pull circuit follow by the CMOS input stage can be controlled. In this known A Schottky diode is located between the interface circuits the collector and the base of the lower of the two bipolar transistors arranged in push-pull circuit. This Schottky diode is used to prevent too strong Saturation state of this bipolar transistor, since that dynamic behavior of the bipolar transistor through a strong saturation is affected. In other words the switching speed of a bipolar transistor decreases if it is operated in too high a saturation, because the base carrier clearance in this state would take too long a time. The Schottky diode that parallel to the collector-base path this (lower) bipolar transistor has a lower forward voltage than the PN transition of the collector base path of the Bipolar transistor. Act as majority carrier components with Schottky diodes with their forward polarity no charge storage on, so that the parallel connection of the Schottky diode to the collector-base path of the lower one Transistor to prevent excessive saturation and to increase the switching speed the arrangement leads. However, it requires manufacturing the known interface circuit of the additional Process step of structuring the Schottky contact, another metal next to its implementation the commonly used aluminum in the manufacture must be applied. Furthermore, for the production of the Schottky contact the tub beneath it low doped be what a high integration of the interface circuit stands in the way, since this is only with highly endowed Areas is achievable.  

It is also from the technical publication vest, N .: Principals of CMOS-VLSI-Design, Addison-Wesly 1985, p. 143 to 227, known, an interface circuit for the above To realize applications in pure CMOS technology, where the interface circuit by several, connected in series Inverter is formed. One each the following inverter becomes larger by a certain factor dimensioned as the previous one, with the last inverter must be dimensioned so that it is within the TTL level the required current for one or more Can deliver standard TTL loads. The one required for this nMOS-FET has a large area.

Furthermore, from the specialist publication Miwa, H. et al .: A 13 ns / 359 mW 2 kW × 9 bit RAM using Hi-BiCOMS Technology, ESSCIRC 1988, Delft, an interface circuit known, whose output stage has a bipolar in its upper part npn transistor and has an nMOS FET in the lower part. Because the nMOS-FET does not have the saturation state mentioned above a bipolar transistor can assume no Schottky diode required here. However, here too nMOS-FET an undesirably large area requirement.

In the older, unpublished patent application P 38 24 694.5 from the applicant is an integrated semiconductor circuit described a CMOS input stage and comprises an output stage, the output stage consisting of a bipolar transistor in emitter circuit with an as constantly switched current source acting pMOS transistor is formed. Between the base and the emitter of the bipolar transistor is a constantly on nMOS transistor.

From EP-A1-02 61 528, Fig. 9, a circuit of the type mentioned is known. In its numerous figures, EP-A1-02 61 528 shows various embodiments of CMOS logic circuits with a bipolar transistor output stage for driving capacitive loads with high currents. The circuit shown in FIG. 9 has a field effect transistor whose source-drain path lies between a supply voltage and the base of the first bipolar transistor, a second field effect transistor whose drain-source path lies between the base of this bipolar transistor and the base of the second bipolar transistor , wherein the first and second field effect transistors are connected to an input terminal on the gate side. A fifth field effect transistor, which is also connected to the input terminal at the gate, lies with its drain-source path between the output of the circuit and the base of the second bipolar transistor. This is connected to ground via the three-source path of a fourth field effect transistor, which is connected to the base of the first bipolar transistor. A third field effect transistor has a drain-source path between the supply voltage and the base of the second bipolar transistor and is located on the gate side at the circuit input. The third field effect transistor is used to supply an additional base current to the second bipolar transistor in order to increase the rate of discharge of the load capacitance (page 3, lines 49 to 55). The fifth field effect transistor between the output terminal and the base of the second bipolar transistor is used in this circuit alone to supply a charge from the output of the circuit to the base of the second bipolar transistor for switching it through when the input signal is high (page 2, lines 15 and 16). With a high output level, the base current of the second transistor can flow via the field effect transistor, while with falling output potentials, the task of supplying the base current is taken over by the third field effect transistor in order to avoid signal deformation problems (page 4, lines 1 to 7). For the circuit of FIG. 9 is executed in this document (page 4, lines 7 to 11), that the second bipolar transistor is operated in the saturation region and that this circuit can not be considered for practical use because of problems caused by the charging the capacitive load on the output side is based on a potential above the ground potential due to a current flow from the supply voltage terminal via the third and fifth field effect transistors. Thus, this citation discards the circuit of FIG. 9 for practical use as a driver circuit for capacitive loads and suggests modified circuit configurations which are shown in FIGS. 10 to 20 of this document. These last-mentioned circuit configurations are likewise only described as driver circuits for capacitive loads and, because of their limited output potential range, are only suitable as such. Regulations on the dimensioning of the field effect transistors of the circuits according to FIGS. 1 to 20 cannot be found in this document. On page 4, lines 7 and 8 alone there is a note that the second bipolar transistor should be operated in the saturation range, from which the requirement for a high base current for the second bipolar transistor can be derived.

In view of this prior art, the present Invention, the object of a FET-TTL interface circuit to create the output TTL specifications fulfilled, compared to known FET-TTL interface circuits with a reduced number of process steps is producible and still high Has switching speed.

This task is done with a circuit according to the generic term of claim 1 by the in the characterizing Part of claim 1 specified features solved.  

In the FET-TTL interface circuit according to the invention a device for preventing the excessive state of saturation a bipolar transistor, which has a high Would exclude switching speed, not by that complex Schottky diode, but by means of a bracket FET that goes from the input of the FET Input stage of the FET-TTL interface circuit driven here becomes. In the circuit according to the invention are omitted not only those in the prior art for FET-TTL interface circuits required additional procedural steps for the Schottky process, but also the design restrictions resulting from the Schottky process for the circuit designer who among other things in the low doping required for the Schottky contact consist of a reduction in circuit size opposes. The replacement according to the invention in the state the Schottky diode deemed necessary in the art thanks to a controlled FET, it is easy to manufacture switching at high switching speed, whereby the designer remains completely free to choose the desired doping for the individual circuit areas. In particular, the FET-TTL according to the invention Interface circuit for an implementation in BICMOS Technology suitable so that the MOS-FETs and the bipolar transistors can be integrated monolithically. The invention Circuit is suitable for driving several Standard TTL loads. A standard TTL load is defined thanks to an L level of maximum 0.4 V at 1.6 mA current consumption through an H level of at least 2.4 V at 40 uA Power delivery and through a load capacitance CL of 15 pF.

Due to the dimensioning of the clamp FET based on that of the third FET becomes one Operating mode of the overall circuit reached, in contrast to the related requirement of the generic Citation too deep a state of saturation of the  second bipolar transistor is prevented in that when the collector potential drops at the second bipolar transistor reverses the current direction in the bracket FET part of the base current from the second bipolar transistor to derive away via its collector.

Preferred developments of the circuit according to the invention are the subject of subclaims two to seventeen.

Below are with reference to the accompanying Drawings preferred embodiments of the invention FET-TTL interface circuit explained in more detail. It shows

Fig. 1 shows a first embodiment of the FET-TTL interface circuit of the invention;

FIG. 2 shows a graphical representation of the dependency of the output voltage on the input voltage in the embodiment according to FIG. 1; FIG.

Figure 3 is a graphical representation of the currents shown in Fig 1 in response to the input voltage..;

FIG. 4 shows a time representation of the behavior of the output voltage of the circuit example shown in FIG. 1 as a function of the input voltage;

Figure 5 is a graphical representation of the time dependence of the currents from the time at the indicated in Figure 4 control the circuit shown in Fig. 1..;

Fig. 6 shows a second embodiment of the FET-TTL interface circuit of the invention;

Fig. 7 shows a third embodiment of the present invention FET-TTL interface circuit;

Fig. 8 shows a fourth embodiment of the present invention FET-TTL interface circuit; and

Fig. 9 shows a fifth embodiment of the FET-TTL interface circuit of the invention.

The first embodiment of the FET-TTL interface circuit shown in FIG. 1 comprises a first npn bipolar transistor Q 1 , which lies between a first potential V 1 and an output A of the circuit, and a second npn bipolar transistor Q 2 , which lies between the Output A and a second potential V 2 is connected, which is formed by the ground potential in the example. The second bipolar transistor Q 2 is arranged in an emitter circuit, while the first bipolar transistor Q 1 is connected in a collector circuit.

A first p-channel MOSFET M 1 is connected on the source side to the first potential, on the drain side on the base of the first bipolar transistor Q 1 and on the gate side to the input E of the circuit.

A second n-channel MOSFET M 2 is connected on the drain side to the base of the first bipolar transistor Q 1 and on the source side to the base of the second bipolar transistor Q 2 , while its gate is connected to the input E.

A third n-channel MOSFET M 3 is on the drain side at the first potential, on the source side at the base of the second bipolar transistor Q 2 and on the gate side also at the input E of the circuit. A fourth n-channel MOSFET M 4 is located on the drain side at the base of the second bipolar transistor Q 2 and on the source side at the second potential V 2 , the gate of which is connected to the output A of the circuit.

An n-channel clamp MOSFET MK is connected with its drain electrode to the output A and is connected with its source electrode to the base of the second bipolar transistor Q 2 , the gate of which is connected to the input E of the circuit.

The ratio of the channel width W to the channel length L of the MOSFERTs is defined as follows in the exemplary embodiment according to FIG. 1: M 1 : 50/3; M 2 : 12/3; M 3 : 12/3; M 4 : 3/3 and MK: 24/3.

The following considerations lead to the inventive dimensioning of the third MOSFET M 3 depending on the dimensioning of the clamped MOSFET MK:

In the case of the low potential at the output A of the FET-TTL interface circuit, the clamp FET MK must ensure that an excess base current of the second bipolar transistor Q 2 is derived to the collector thereof. Therefore, the clamp FET MK must have a sufficiently large channel width WK depending on the channel width W 3 of the third MOSFET M 3 . Since the first MOSFET M 1 and the first bipolar transistor Q 1 are in a blocked state, and since the second MOSFET M 2 has no current in the static state, the following equations apply:

IC = -I (V 6 ) (1)
I (V 7 ) = IC / beta (2)

where beta denotes the current gain of the second bipolar transistor Q 2 .

The ideal equations for MOSFETs are:

for the linear range;

for the saturation range;

Here mean:
IDS: drain-source current;
VGS: gate-source voltage;
VDS: drain-source voltage;
K: technology constant; and
VT: threshold voltage.

The following applies to the linear range:

VGS-VTVDS. (5)

The following applies to the saturation range:

VGS-VTVDS. (6)

It follows that the third MOSFET M 3 is in saturation and the clamped MOSFET MK is in its linear region.

This results in the following dependencies for the currents I (V 5 ) and I (V 6 ):

Since current I (V 7 ) is very small compared to current I (V 5 ), the following relationship applies:

I (V 5 ) = -I (V 6 ) (9)

Solving the above equations according to the ratio WK to W 3 gives the following relationship:

Within equation 10 above, VE denotes the upper value of the input voltage, which is 5 V in the exemplary embodiment, VBEQ 2 the base-emitter voltage of the second bipolar transistor Q 2 of approximately 0.8 V, VT the threshold voltage of approximately 0.8 V and VA is the saturation voltage of the inner transistor of approximately 0.1 V.

With these values, the following relationship results for the channel widths WK, W 3 of the clamp FET MK and the third MOSFET M 3 :

Experimental tests have shown that the invention FET-TTL interface circuit within the following range of the ratios of the channel widths satisfactory dynamic behavior shows:  

With the above numerical values, the following optimal value range results for the ratio of the channel widths WK, W 3 :

The following considerations are for compliance with the condition for the low TTL level of 0.4 V additionally consider:

With a loaded output A of the FET-TTL interface circuit according to the invention, an additional current -I (AUS) flows into the collector of the second bipolar transistor Q 2 . This additional current generates an additional voltage drop VBAHN at the path resistance of the second bipolar transistor between its collector and its emitter, which, together with the saturation voltage VA of the inner transistor, must not exceed the permissible low TTL level of 0.4 V. Therefore, the saturation voltage of the inner transistor VA must be chosen to be sufficiently low.

The static behavior of the embodiment of the FET-TTL interface circuit according to the invention shown in FIG. 1 is shown in FIGS. 2 and 3, while the dynamic behavior of this embodiment of the circuit is shown in FIGS. 4 and 5.

First, the static behavior of the circuit is explained.

This is used to simulate the TTL load at output A.  with a load resistance of 0.6 kOhm to the first potential VI laid.

At an input voltage VE of 0 V, the first MOSFET M 1 and the fourth MOSFET M 4 are conductive, while the second, third and the clamp MOSFET M 2 , M 3 , MK are blocked.

The first MOSFET M 1 connects the base of the first bipolar transistor Q 1 to the first potential V 1 , so that the first bipolar transistor Q 1 is switched on. No current is applied to the base of the second bipolar transistor Q 2 , so that it is blocked.

At output A, a potential corresponding to this first potential V 1 results from the load resistance which is at the first potential V 1 . This state corresponds to area 1 in FIG. 2.

If the input voltage VE is now gradually increased, the second and third MOSFETs M 2 , M 3 and the clamped MOSFET MK are turned on. In this state, the sum of the currents I (V 4 ) and I (V 5 ) is initially still smaller than the current I (V 8 ) flowing off via the fourth MOSFET M 4 . This state corresponds to the left-hand region of area 2 in FIG. 3.

The switched-on clamp FET MK fulfills the task in this area of supplying an additional current for supplying the base of the second bipolar transistor Q 2 . As soon as a positive base current I (V 7 ) flows into the base of the second bipolar transistor Q 2 , this bipolar transistor Q 2 becomes conductive, so that its output potential VA drops. The drop in the output potential VA is shown in area 2 of FIG. 2. When the output potential VA reaches a value of approximately 0.8 V and thus approximately the threshold voltage of the nMOSFET M 4 , this discharge transistor M 4 is blocked, whereupon the current I (V 7 ) flowing into the base of the second bipolar transistor Q 2 reaches a maximum reached. In this connection, reference is made to the right-hand part of area 2 of FIG. 3.

If the collector potential at the second bipolar transistor Q 2 drops further, the current direction in the clamp FET MK reverses, with some of the currents I (V 4 ) and I (V 5 ) being diverted away from the base of the second bipolar transistor Q 2 via its collector . This current derivation prevents the second bipolar transistor Q 2 from becoming too saturated, since, as the output potential VA drops, an increasing current I (V 6 ) is derived via the clamp FET MK from the base of the second bipolar transistor Q 2 , which further reduces the Output potential VA counteracts. This control mechanism results in a stable output potential of approximately 0.4 V, as is also represented by region 3 according to FIG. 2.

The dynamic behavior of the circuit shown in FIG. 1 is explained in more detail below with reference to FIGS. 4 and 5. This dynamic behavior depends on whether an increasing LH jump signal or a falling HL jump signal is present at input E of the interface circuit according to FIG. 1.

In the event of an LH jump signal at input E, the first MOSFET M 1 is blocked and the second and third MOSFET M 2 , M 3 and the clamped MOSFET M 4 are turned on . First, the base current I (V 1 ) of the first bipolar transistor Q 1 flows from the base thereof via the second MOSFET M 2 into the base of the second bipolar transistor Q 2 . An approximately equal current I (V 5 ) flows via the third MOSFET M 3 to the base of the second bipolar transistor Q 2 . However, the major part of the base current I (V 7 ) of the second bipolar transistor is the current I (V 6 ), which is supplied by the clamp FET MK. A very strong switch-on pulse thus reaches the base of the second bipolar transistor Q 2 , so that the collector current quickly pulls the output potential VA downward. In the L state, there is a reversal of the direction of the current I (V 6 ) through the clamp FET MK, so that with the corresponding current drain at the base of the second bipolar transistor Q 2, the output voltage V 8 is in a range from 0.3 to 0. 4 V is limited. In this connection, reference is made to FIG. 2, area 3 and FIG. 4 in the time range between 0.8 and 1.6 × 10 ^-8 s.

In the event of a falling HL jump signal at input E, the first MOSFET M 1 is opened, while the second and third MOSFET M 2 , M 3 and the clamped MOSFET MK are blocked. A very steep current pulse I (V 1 ) arises in the base of the first bipolar transistor Q 1 , so that it switches on very quickly and can supply a correspondingly high current pulse at output A for charging the load capacitance located there (not shown). With increasing output voltage VA, the current I (V 1 ) in the base of the first bipolar transistor Q 1 becomes smaller again and finally changes its sign. The reason for this is that no further current flows into the load capacitance when output A has reached its end voltage. Thus, the charge controlling the current flow in the base of the first bipolar transistor Q 1 must be reduced again, which is done by feeding it back into the source of the first potential V 1 . The base of the second bipolar transistor Q 2 is discharged by the fourth MOSFET M 4 , which is already switched on when the output voltage VA rises above a value of approximately 0.8 V.

The second to fifth exemplary embodiment according to FIGS. 6 to 9 correspond to the first exemplary embodiment of the inventive FET-TTL interface circuit according to FIG. 1, except for the deviations explained below.

Therefore, only the deviations to repetitions are explained the description is more consistent Avoid circuit parts.

In the second exemplary embodiment according to FIG. 6, the source of the second MOSFET M 2 is not connected to the base of the second bipolar transistor Q 2 , but is connected to the second potential V 2 , which is the ground potential in the example.

In the third exemplary embodiment according to FIG. 7, the third MOSFET M 3 is designed as a p-channel MOSFET in deviation from the first exemplary embodiment. Its source electrode is connected to the first potential and its drain electrode is connected to the base of the second bipolar transistor Q 2 . In this case, the gate of the third MOSFET is connected to the base of the first bipolar transistor Q 1 .

In the fourth embodiment according to FIG. 8, the clamp MOSFET MK is designed as a p-channel MOSFET. Its gate is connected to the base of the first bipolar transistor Q 1 .

In the fifth exemplary embodiment according to FIG. 9, both the third MOSFET M 3 and the clamp MOSFET MK are designed as p-channel MOSFETs. Compared to the first exemplary embodiment, the source and drain electrodes of these two MOSFETs are interchanged. The gates of these two MOSFETs M 3 , MK are connected to the base of the first bipolar transistor. Here, too, the source of the second MOSFET M 2 is connected to ground.

In Fig. 1 a special input stage for the embodiment of the invention is shown FET-TTL interface circuit. In deviation from this input stage, other FET input stages can also be used, which effect push-pull control of the two bipolar transistors Q 1 , Q 2 .

In the embodiment shown in FIG. 1, the first potential V 1 is higher than the second potential V 2 . If the polarities of these potentials V 1 , V 2 are reversed, the source or drain electrode of the respective MOSFETs must be interchanged.

Although an implementation of the FET-TTL- Interface switching using BICMOS technology as a monolithic integrated circuit is preferred also comes a structure of the circuit by means of discrete components in Consider.

In the described embodiment, the Bracket MOSFET connected directly to input E. For the function of the circuit according to the invention occurs however, it depends solely on the fact that the clamp MOSFET MK is dependent is controlled by the signal at input E, so that also an indirect control of the clamp MOSFET via switching elements located between the input E and this is possible.

Claims (17)

1st circuit
with a FET input stage, which has a first, second and third FET,
with two push-pull bipolar transistors, which are controlled by the FET input stage, and
with a further FET which is connected to the collector of the second bipolar transistor and the gate of which is operatively connected to the input of the FET input stage, the third FET being connected to the base of the second bipolar transistor, characterized in that
that the circuit is a FET-TTL interface circuit,
that the further FET connected to the collector of the second bipolar transistor (Q 2 ) is a clamped FET (MK) which is provided to prevent the second bipolar transistor (Q 2 ) from becoming too saturated, and
that the ratio of the channel widths (WK, W 3 ) of the bracket FET (MK) and the third FET (M 3 ), provided that the channel lengths of these FETs (M 3 , MK) are the same, is in the following range: where: VBEQ 2 is the base-emitter voltage of the second bipolar transistor (Q 2 ), VE is the upper value of the input voltage, VT is the threshold voltage and VA is the saturation voltage of the inner transistor of the second bipolar transistor (Q 2 ). 2nd circuit
with a FET input stage, which has a first, second and third FET,
with two push-pull bipolar transistors, which are controlled by the FET input stage, and
with a further FET which is connected to the collector of the second bipolar transistor and the gate of which is operatively connected to the input of the FET input stage, the third FET being connected to the base of the second bipolar transistor, characterized in that
that the circuit is a FET-TTL interface circuit,
that the further FET connected to the collector of the second bipolar transistor (Q 2 ) is a clamped FET (MK) which is provided to prevent the second bipolar transistor (Q 2 ) from becoming too saturated, and
that the ratio of the channel widths (WK, W 3 ) of the bracket FET (MK) and the third FET (M 3 ), assuming the same channel lengths of these FETs (M 3 , MK), is in the following range: 3. Circuit according to claim 1 or 2, characterized in that
that the FET input stage is a CMOS input stage and
that the FET-TTL interface circuit is a CMOS-TTL interface circuit. 4. Circuit according to one of claims 1 to 3, characterized in that
that the first bipolar transistor (Q 1 ) lies between a first potential (V 1 ) and an output (A) and the second bipolar transistor (Q 2 ) lies between the output (A) and the second potential (V 2 ). 5. Circuit according to claim 4, characterized in
that the FET input stage has a first FET (M 1 ), which lies between the first potential (V 1 ) and the base of the first bipolar transistor (Q 1 ) and is operatively connected on the gate side to the input (E) of the FET input stage, and a second FET (M 2 ), which is connected to the base of the first bipolar transistor (Q 1 ) and is operatively connected on the gate side to the input (E) of the FET input stage. 6. Circuit according to claim 5, characterized in that the channels of the first and second FET (M 1 , M 2 ) are doped in opposite directions. 7. Circuit according to one of claims 1 to 6, characterized in that the channels of the first and third FET (M 1 , M 3 ) are doped in opposite directions. 8. Circuit according to one of claims 4 to 7 in direct or indirect back-reference to claim 4, characterized in that the FET input stage has a fourth FET (M 4 ) which is between the base of the second bipolar transistor (Q 2 ) and the second Potential (V 2 ) is located and is operatively connected to the gate (A). 9. Circuit according to claim 8, characterized in
that the channels of the clamp FET (MK) and the fourth FET (M 4 ) are doped in the same way. 10. Circuit according to one of claims 1 to 9, characterized in
that the bipolar transistors (Q 1 , Q 2 ) are npn transistors, and
that the first FET (M 1 ) is a p-channel enhancement type FET and the second, third and fourth FET (M 2 , M 3 , M 4 ) and the bracket FET (MK) are n-channel enhancement type FETs . 11. Circuit according to one of claims 3 to 10 in direct or indirect reference to claim 3, thereby featured, that the FET-TTL interface circuit as an integrated BICMOS circuit is executed. 12. Circuit according to one of claims 1 to 11, characterized in that the third FET (M 3 ) is further connected to the first potential (V 1 ). 13. Circuit according to one of claims 1 to 12, characterized in that
that the third FET (M 3 ) is an enhancement type n-channel FET, and
that its gate is connected to the input of the FET-TTL interface circuit. 14. Circuit according to claim 1 or 2, characterized in that the third FET (M 3 ) is a p-channel FET of the enhancement type, the gate of which is connected to the base of the first bipolar transistor (Q 1 ). 15. Circuit according to one of claims 4 to 11, characterized in
that a fifth and a sixth p-channel FET (M 5 , M 6 ), which are connected in series with one another between the first potential (V 1 ) and the base of the second bipolar transistor (Q 2 ), are provided,
that the gates of the fifth and sixth FET (M 5 , M 6 ) are connected to the base of the first bipolar transistor (Q 1 ), and
that the bracket FET (MK) is between the collector of the second bipolar transistor (Q 2 ) and the common node of the fifth and sixth FET (M 5 , M 6 ). 16. Circuit according to one of claims 5 to 15, characterized in that the second FET (M 2 ) between the base of the first bipolar transistor (Q 1 ) and the base of the second bipolar transistor (Q 2 ). 17. Circuit according to one of claims 5 to 15, characterized in that the second FET (M 2 ) is between the base of the first bipolar transistor (Q 1 ) and the second potential (V 2 ).