ELECTRICAL CIRCUIT

Abstract

The invention relates to an electrical circuit in the form of a transimpedance amplifier stage, and to a method for operating this circuit. The invention furthermore relates to a circuit containing at least one signal amplifier that has at least one output connection, at least one input connection or at least one pair of differential input connections and at least two voltage supply connections, one of which may also be an earth or ground connection, wherein the signal amplifier has at least one additional connection that is connected internally to at least one of the input connections or the input connection via at least one further component, for example a diode.

Claims

1. An electrical circuit configured as a transimpedance amplifier stage, comprising: an input node (IN), an output node, a feedback node, at least one signal amplifier comprising at least one output connection, and at least one input connection or at least one pair of differential input connections, wherein an input signal applied to the at least one input connection or the at least one pair of differential input connections is converted into a multiple amplified output signal emitted at the at least one output connection, wherein the at least one output connection is connected or is connectable the output node directly or via at least one further component, and wherein at least one of the at least one input connection or the at least one pair of differential input connections is connected to or is connectable to the input node directly or via at least one further component, wherein, in a case of an individual input connection of the at least one input connection a, reference potential of a signal amplifier or, in a case of a pair of differential input connections of the at least one pair of differential input connections, the potential of an other input connection which is not connected or cannot be connected to the input node is a first reference potential, at least one feedback element connected to or connectable to the input node with a first connection directly or via at least one further component and to the feedback node with a second connection directly or via at least one further component, at least one feedback control element connected to or connectable to the feedback node with a first connection directly or via at least one further component and to the output node with a second connection directly or via at least one further component, at least one first switch through which the feedback node is connectable to a second reference potential directly or via at least one further component, and at least one second switch through which the output node is connectable to the input node directly or via at least one further component.

2. The electrical circuit as claimed in claim 1, wherein the feedback control element is formed by a resistor, a capacitor, or a circuit arrangement made up of one or a plurality of resistors and/or one or a plurality of capacitors.

3. An electrical circuit configured as a transimpedance amplifier stage, comprising: an input node, an output node, at least one signal amplifier which comprises at least one output connection and at least one input connection or at least one pair of differential input connections, wherein an input signal applied to the at least one input connection or the at least one pair of differential input connections is converted into a multiple amplified output signal emitted at the at least one output connection, wherein the at least one output connection is connected to or connectable to the output node directly or via at least one further component, and wherein the at least one input connection or the at least one pair of differential input connections is connected to or connectable to the input node directly or via at least one further component, wherein, in a case of an individual input connection of the at least one input connection a reference potential of a signal amplifier or, in a case of a pair of differential input connections of the at least one pair of differential input connections a potential of an other input connection which is not connected or cannot be connected to the input node (IN) is a first reference potential, at least one feedback element which is connected to or connectable to the input node with a first connection directly or via at least one further component, and is connected to or connectable to the output node with a second connection directly or via at least one further component, at least one further signal amplifier which comprises at least one further output connection and at least one further input connection or at least one further pair of differential input connections, wherein an input signal applied to the at least one further input connection is converted into a multiple amplified output signal emitted at the at least one further output connection, wherein the at least one further output connection is connected to a second switch directly or via at least one further component and at least one further input connection is connected to the output node directly or via at least one further component, wherein, in a case of an individual further input connection of the at least one further input connection, a reference potential of a further signal amplifier or, in a case of a further pair of differential input connections of the at least one pair of differential input connections, a potential of an other further input connection which is not connected or cannot be connected to the output node is referred to as a second reference potential, and at least one second switch through which the further output connection is connectable to the input node directly or via at least one further component.

4. The electrical circuit as claimed in claim 3 wherein the second reference potential corresponds to the first reference potential.

5. The electrical circuit as claimed in claim 1 wherein the first and/or the second switch is controllable by electrical control signals, wherein the electrical circuit further comprises a control device for controlling the switching of the first and/or the second switch, wherein the control device is set up, in a first operation mode, to switch the first and/or the second switch into switch positions through which a current flowing into the input node is converted into an amplified, integrated or otherwise dependent output signal at the output node and, in a second operation mode, the control device is set up to switch the first and/or the second switch into switch positions through which the electrical circuit is actively regulated to a neutral state.

6. The electrical circuit as claimed in claim 5, wherein the control device is set up to switch the first and the second switch in a same direction.

7. The circuit arrangement as claimed in claim 5 wherein the feedback control element is designed as a third switch which is switched by the control device in an opposite direction to the first switch, wherein the first and the third switch are can be designed as individual switches or as a common changeover switch.

8. A method for operating a circuit as claimed in claim 1 wherein the feedback element is reset to a neutral state by actively regulating a voltage across the feedback element to a specific value.

9. The method as claimed in claim 8, wherein in a first operation mode of the electrical circuit, a current flowing into the input node is converted into an amplified, integrated or otherwise dependent output signal at the output node of the electrical circuit, and in a second operation mode of the electrical circuit, the electrical circuit is actively regulated to a neutral state, wherein the first and the second operation mode are switchable.

10. The method as claimed in claim 8 wherein the feedback element is formed by a resistor, a capacitor, or a circuit arrangement made up of a plurality of resistors and/or a plurality of capacitors.

11. The electrical circuit as claimed in claim 1 further comprising at least one current limiting component connected in series to the at least one second switch, wherein the at least one currently limiting component has a current transfer characteristic through which substantially no current flows when a voltage applied to the at least one current limiting component is small, but in a case of a larger voltage, a current flows which is larger by more than a ratio of the voltage and the larger voltage.

12. The electrical circuit as claimed in claim 11, wherein the at least one current limiting component is formed by input protection diodes integrated in a signal amplifier.

13. The electrical circuit as claimed claim 1 wherein the output node is coupled with a differentiator.

14. A circuit, comprising: at least one signal amplifier comprising at least one output connection, at least one input connection, or at least one pair of differential input connections, at least two voltage supply connections, wherein one of the at least two voltage supply connections is functionable as an earth or ground connection, wherein the at least one signal amplifier comprises at least one additional connection which is connected internally in the at least one signal amplifier via at least one further component to at least one of the at least one input connection, and at least one component connected to the at least one additional connection, wherein an electrical current is fed into the at least one additional connection or an electrical voltage is applied to the at least one additional connection.

15. The electrical circuit as claimed in claim 1 the second reference potential corresponds to the first reference potential.

16. The electrical circuit as claimed in claim 3 wherein the first and/or the second switch is controllable by electrical control signals, wherein the electrical circuit further comprises a control device for controlling the switching of the first and/or the second switch, wherein the control device is set up, in a first operation mode, to switch the first and/or the second switch into switch positions through which a current flowing into the input node is converted into an amplified, integrated or otherwise dependent output signal at the output and, in a second operation mode, the control device is set up to switch the first and/or the second switch into switch positions through which the electrical circuit is actively regulated to a neutral state.

17. The electrical circuit as claimed in claim 16, wherein the control device is set up to switch the first and the second switch in a same direction.

18. The electrical circuit as claimed in claim 1 further comprising at least one current limiting component connected in series to the at least one second switch, wherein the at least one currently limiting component has a current transfer characteristic through which substantially no current flows when a voltage applied to the at least one current limiting component is small, but in a case of a larger voltage, a current flows which is larger by more than a ratio of the voltage and the larger voltage.

Description

[0051] The invention is explained in greater detail hereinafter by means of exemplary embodiments using drawings. In the drawings

[0052] FIG. 1—shows a first embodiment of an electrical circuit and

[0053] FIGS. 2, 3—show a second embodiment of an electrical circuit in a first and a second operation mode and

[0054] FIGS. 4, 5—show a third embodiment of an electrical circuit in a first and a second operation mode and

[0055] FIG. 6—shows a fourth embodiment of an electrical circuit and

[0056] FIG. 7—shows a fifth embodiment of an electrical circuit and

[0057] FIG. 8—shows a sixth embodiment of an electrical circuit.

[0058] The circuits represented in FIGS. 1 to 8 are represented by way of example as a transimpedance amplifier stage in each case. Other embodiments are also possible.

[0059] FIG. 1 shows the circuit with a signal amplifier V1, a feedback element RE, a first switch S1 and a second switch S2. The signal amplifier V1 has a negative input connection 1, a positive input connection 2 and an output connection 3. The first switch S1 and the second switch S2 are represented as on/off switches by way of example. They each have two switch positions. In one switch position, a contact C is connected to a contact A of the respective switch S1, S2, in another switch position, the switches are open.

[0060] At the input node IN, an input signal which is to be measured is fed in, in this case an input current I.sub.IN. The input node IN is connected to the negative input connection 1, a first connection of the feedback element RE and the contact C of the second switch S2. The positive input connection 2 is connected to a fixed voltage potential, the first reference potential REF1, for example earth potential.

[0061] The output connection 3 is connected to the output node at which the output signal U.sub.OUT is provided. This is further connected to the contact A of the second switch S2 and the first connection of the feedback control element RSE. The second connection of the feedback element RE, the second connection of the feedback control element RSE and the contact A of the first switch S1 are connected to the feedback node FB. The contact C of the first switch S1 is connected to a second reference potential REF2, for example to the earth potential.

[0062] In the adjacent box, different exemplary embodiments of the feedback control element are shown, for example a resistor R1, a network N1 as well as an on/off switch S3.

[0063] The circuit is in a first operation mode in which the normal measurement and amplification function of the transimpedance amplifier stage can be carried out.

[0064] FIG. 2 shows an exemplary embodiment in which a capacitor CF is used as a feed-back element RE and a switch S3, which switches in the opposite direction to S1 and connects the contacts A and B, is used as a feedback control element. The on/off switches S1 and S3 were advantageously combined to form a changeover switch S1.

[0065] FIG. 2 shows the circuit in a first operation mode in which the normal measurement and amplification function of the transimpedance amplifier stage can be carried out. In the first operation mode, a connection is established between an output connection 3 and the second connection of the feedback element C.sub.F via the first switch S1. The second switch S2 disconnects the output connection 3 from the negative input connection 1. In this state, the circuit can be operated as a normal capacitive transimpedance amplifier stage, for example. The current I.sub.IN supplied at the input side is converted into a multiple amplified or integrated output signal U.sub.OUT via the transimpedance amplifier stage. Depending on the input signal, it may be necessary to discharge the feedback element C.sub.F in order to avoid disruptive effects if the maximum permissible voltage at the feedback element C.sub.F is reached as a result of the integrating function. For this purpose, the circuit is set to a second operation mode, which is represented in FIG. 3.

[0066] In comparison to FIG. 2, in the second operation mode, the first and the second switch S1, S2 are switched. The second connection of the feedback element C.sub.F is now connected to the contact C via the first switch S1 and thus to the second reference potential which is connected there. Via the second switch S2, a connection is established between the output connection 3 and the negative input connection 1 and thus also with the first connection of the feedback element C.sub.F. In this state, the feedback element C.sub.F is rapidly discharged or charged by the signal amplifier V1 to a voltage which corresponds to the potential difference between the second reference potential at the contact C of the first switch S1 and the first reference potential at the positive input connection 2. If the voltage difference between these voltage potentials is equal to zero, the feedback element C.sub.F is thus completely discharged.

[0067] FIGS. 4 and 5 show an embodiment of the circuit which differs from FIGS. 2 and 3 in such a way that a current limiting element D1, D2 is connected in series in the con-nection from the output connection 3 via the second switch S2 to the negative input connection 1. The current limiting element D1, D2 can be designed as two diodes connected in antiparallel. This can further minimize interference effects through leakage currents and/or charge injections as a result of the first and the second switch S1, S2. Moreover, FIG. 4 shows the circuit in the first operation mode, FIG. 5 shows the circuit in the second operation mode. The mode of operation otherwise corresponds to the mode of operation of the circuit in FIGS. 2 and 3.

[0068] FIG. 6 shows a further variant of the circuit in which the feedback control element RSE has been replaced by a short circuit and the therefore superfluous switch S1 removed. The second connection of the feedback element RE, in this case the capacitor C.sub.F, is therefore directly connected to the output node OUT. Since the output of the signal amplifier V1 is now permanently connected to the second connection of the feedback element, it can no longer perform the regulating function according to the invention. In order to still be able to provide the regulating function according to the invention, a second signal amplifier V2 is connected to the output node with its positive input, to the second reference potential with its negative input and to the contact A of the switch S2 with its output. This also tends to minimize the potential difference between its inputs and thus drives a current into the input node until the potential at the second connection of the feedback element corresponds to the second reference potential.

[0069] FIG. 7 shows an embodiment of the circuit which, like the embodiment in FIGS. 4 and 5, has a current limiting element D1, D2 in series with the second switch S2. However, the current limiting element D1, D2 is not realized by an external diode circuit in this case, but rather by protection diodes integrated in the signal amplifier V1. A guard connection 4 of the signal amplifier V1 can be used for this purpose, for example. The second switch S2 is then simply connected to the guard connection 4. As a result of the internal wiring of the signal amplifier V1, the connection via the current limiting element D1, D2 to the negative input connection 1 is therefore already established.

[0070] FIG. 8 shows the circuit known from FIG. 6, likewise using a current limiting element realized via protection diodes D1, D2 integrated in the signal amplifier V1.