DE19607802A1 - Circuit arrangement for generating a supply voltage - Google Patents

Description

The invention relates to a circuit arrangement for generating a Ver supply voltage according to the preamble of claim 1.

Such circuit arrangements with a subsequent filter stage are used, for. B. sensors with a voltage that has an improved signal-to-noise ratio compared to the input voltage. Circuitry is usually used for this purpose, which keeps the supply voltage for the sensor by a certain amount ΔU below the input voltage. The amount of the voltage difference ΔU is constant. This reduced voltage is fed to a smoothing and filtering stage to filter out voltage peaks and fluctuations. If the consumer to be supplied works over a wide range of the input voltage, it is necessary to adjust the amount of the voltage difference ΔU by which the input voltage is reduced to the absolute amount of the input voltage. It has proven to be advantageous to keep the voltage difference with which the supply voltage for the consumer is below the input voltage, as shown in FIG. 2, up to a first value of the input voltage at a most constant value and from one to keep a certain value of the input voltage constant at a second, larger value. In the transition area in between, the supply voltage remains constant and is independent of the input voltage.

The object of the invention is to create a circuit arrangement for generating egg ner supply voltage with which the above described Ver supply voltage depending on the input voltage can be easily achieved.  

This problem is solved by a circuit arrangement with the Merk paint the claim 1. The advantageous embodiment of the invention is carried out according to the features of the dependent claims.

In the following an embodiment of the invention based on the Figures explained. Show it:

Fig. 1 picture, the circuit arrangement according to the invention in the basic circuit,

Fig. 2 is a diagram of the supply voltage as a function of the input voltage,

Fig. 3 shows a first embodiment of the circuit arrangement accelerator as Fig. 1,

Fig. 4 is an enlarged diagram of the circuit of FIG. 3.

Fig. 1 shows the basic principle of the circuit arrangement according to the inven tion in the block diagram. The input voltage V _IN is connected to the opposing R _DU and the controllable current source I 1 with the ground potential. Depending on the current I through the current source I 1 and the _opposing R _DU , a voltage drop V _RDU arises along the resistance. The connection point between the current source I₁ and the resistor R _DU is connected to the input of an impedance converter or driver / buffer amplifier. The supply voltage for the consumer is made available at its output. At the same time, this output is connected to the ground potential via a voltage divider consisting of the two resistors R 1 and R 2. The first input of a comparator stage K is connected at the connection point of the two resistors. The second input of the comparator stage is connected to a reference _voltage V _REF . The output is connected to the control input of the controllable current source I₁. The supply voltage V _OUT can be represented by the following equation:

V _OUT = V _IN - V _RDU = V _IN - I₁ _* R _DU

The current I₁ is dependent on the output signal of the comparator stage K.

As shown in FIG. 2, the circuit arrangement can assume three states. For small input voltages, a minimum current I _MIN = I _C = I _{C1 flows} through the current source I₁. At the resistor R _DU , a voltage drops over the first range and the supply voltage V _OUT has a first constant voltage difference V _B to the input voltage V _IN .

If the input voltage V _{IN is} in the range between a first threshold voltage V _S1 and a second threshold voltage V _S2 , then the control circuit running via the comparator K engages and the supply voltage V _OUT is kept at a constant value. A current flows in the process

I _C = I _C1 + K · IC₂ with 0 K 1

through the resistance R _DU . The supply voltage V _OUT is such that the voltage VT at the connection point of the two resistors R₁, R₂ of the voltage divider is equal to the reference voltage V _REF .

Towards higher voltages, the maximum current I _max = I _C = I _C1 + I _{C2 flows} through the controllable current source I 1. Then the supply voltage V _{OUT has} a second constant voltage difference VA to the input voltage V _IN .

In the circuit arrangement shown in FIG. 3 is shown the embodiment of the controlled current sources ge detail. A reference current source I _REF supplies the current mirror from the input transistor Q _A connected as a diode and the two transistors Q _B1 and Q _B2 with a constant input current I _A. The constant input current I _A in the integrated variant of the circuit arrangement is dependent on the temperature in such a way that the temperature dependence of the resistance R _{DU is} compensated for. This compensates for the temperature coefficient of the integrated resistor R _DU . The emitter of the transistor Q _A connected as a diode is connected to the resistor RA with the ground potential. The collector of the first mirror transistor Q _B1 is connected to the resistor R _DU and the input of the buffer amplifier 1 . The emitter is connected to ground potential via the resistor R _B1 . The base is connected to the base of Q _A. The Emit ter collector path of the second mirror transistor Q _B2 is switched off in this working point. A constant current I _{C1 flows} through this transistor against the ground potential. The size of this current determines the voltage drop V _RDU and thus the size of the voltage difference V _B for small input voltages. Parallel to the first transistor Q _B1 is a second ter mirror transistor Q _B2 , the collector of which is connected to the collector of the first transistor Q _B1 and whose base is connected to the base of the first transistor Q _B1 . Its emitter is connected to the ground potential via the resistor R _B2 . The emitter of the second transistor Q _B2 is also connected to the output of the controllable current source I₂, which in turn is controlled by the output of the comparator stage. At low input voltages, the second transistor Q _{B2 is} switched off, since the product I _{R *} R _B2 = voltage at emitter Q _{B2 is} greater than the base voltage of Q _B2 minus U _BE . Then only the current I _{C1 flows} through the first transistor Q _B1 through the resistor R _DU . At high input voltages, the current I _C2 additionally flows through the transistor Q _B2 , so that the current I _C = I _C1 + I _C2 flows through the resistor R _DU . In between is a control range in which, in addition to the current I _C1 through the first transistor Q _B1, a second current K * I _C2 (with 0 K 1) flows through the second transistor Q _B2 . In this area, the supply voltage V _{OUT is kept} at a constant value.

In the circuit arrangement shown in FIG. 4 is further for an execution of the comparator K shown. It consists of a differential amplifier consisting of the transistors Q₃ and Q₄, the emitters of which are connected to a current source I _D , the base of the transistor Q₃ having the voltage reference V _REF and the base of the transistor Q₄ having the voltage at the junction of the two resistors of the voltage divider is connected. The output of the differential stage is mirrored by a current consisting of the transistors Q₁ and Q₂, which reflects the current in the collector branch of the transistor Q₃ in the connection point between the second transistor Q _{B2 of} the first current mirror with the resistor R _B2 with a certain factor n . With this arrangement, the supply voltage V _OUT can be generated in the simplest manner with the desired properties.

The supply voltage V _{OUT of} the circuit arrangement can, for example, be used to supply a voltage to a voltage follower stage, the output voltage of which can only change at a certain maximum speed. The voltage gap which is always present to the input voltage V _IN represents a working range of this subsequent stage. A reduction in the interference on the supply voltage V _OUT with respect to the input voltage V _{IN is} thus achieved.

Claims (7)

1. Circuit arrangement for generating a supply voltage (V _OUT ) as a function of an input voltage supplied to the circuit arrangement (V _IN ), characterized in that

• - That a first resistor (R _DU ) is connected on the one hand to the input voltage (V _IN ) and on the other hand via a controllable current source (I₁) to the ground potential, so that at the connection point of the first resistor (R _DU ) with the controllable current source (I₁) a reduced voltage (V _DU ) is present,
• - That an impedance converter ( 1 ) is supplied with the reduced voltage (V _DU ) at its input and provides the supply voltage (V _OUT ) at its output,
• - That the controllable current source (I₁) is controlled as a function of the supply voltage (V _OUT ).

2. Circuit arrangement according to claim 1, characterized in that a comparator (K) is provided which compares the supply voltage (V _OUT ) with a reference voltage (V _REF ) and _controls the controllable current source (I₁) according to the result of the comparison. 3. Circuit arrangement according to claim 2, characterized in that the comparator (K), the supply voltage (V _OUT ) via a voltage divider (R₁, R₂) is supplied. 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the controllable current source (I₁) consists of a reference current source (I _REF ) and a current mirror circuit (Q _A , Q _B1 , Q _B2 ). 5. Circuit arrangement according to one of claims 1 to 4, characterized in that the supply voltage (V _OUT ) at low input voltages (V _IN ) has a first constant voltage difference (V _B ) to the input voltage. 6. Circuit arrangement according to one of claims 1 to 5, characterized in that the supply voltage (V _OUT ) at large input voltages gene (V _IN ) has a second constant voltage difference (V _A ) to the input voltage. 7. Circuit arrangement according to claim 5 or 6, characterized in that in a transition region between small and large input voltages (V _IN ) the supply voltage (V _OUT ) has a variable voltage difference (V) to the input voltage according to V _B VV _A.