CS205348B1 - Connexion of analog voltage change-over switch - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an analog voltage switch circuit comprising at least one switching member having analog and control inputs, a decoupling resistor and a switching and auxiliary unipolar transistor, an amplifier section having an operational amplifier with resistors and capacitors. wherein the outputs formed by the emitters of the switching unipolar transistors of the switching members are connected to the inverting input of the operational amplifier of the amplifying portion. (

A series of wiring of analog voltage switches consists of an input switching section and a connected amplifying section. The closest known circuit of such an analog voltage amplifier consists of a parallel combination of switching elements in which one analog switching element is used for one switching channel. This switching element consists of a pair of unipolar transistors controlled by an electric field and an auxiliary decoupling resistor. The switching member thus consists of a switching unipolar transistor whose collector is connected to the collector of the auxiliary unipolar transistor and connected via a separating resistor to the input terminal of the switching member. The auxiliary unipolar transistor emitter is connected to the zero bus, between which the input voltage of the switching channel of any polarity is applied between the input terminal and the input terminal. The control electrode of the switching unipolar transistor is coupled to the first control input of the switch between which a control voltage of such polarity that the switching unipolar transistor is energized in the operating state is applied between and the zero bus. The auxiliary unipolar transistor control electrode is coupled to a second control input of the switching member between which a control voltage for the auxiliary unipolar transistor is applied between and the zero bus.

The switching unipolar transistor emitter is coupled to the switching unipolar transistor emitters of the other switching members to the input of the amplifier portion of the analog voltage switch. This amplification section consists of an operational amplifier provided with a feedback network. The input of the amplifier section is an inverting input of the operational amplifier, which is connected in series with two resistors and a capacitor connected in parallel to this series combination with the output of the operational amplifier, which simultaneously represents the output of the wiring. The center of said series combination of two resistors is connected to the zero bus by another resistor. The inverting input of the operational amplifier is connected to the non-inverting input of this amplifier through a series combination of capacitor and resistor, which is connected to the neutral bus by another resistor.

A substantial disadvantage of the described known analog voltage switch circuitry is that the circuitry does not allow different amplification of switched analogue voltages to be set in the individual switching channels.

Essentially, these disadvantages are overcome by the invention, wherein the first actuating inputs of the switching members are connected via a series combination of a decoupling diode and a decoupling resistor to a cross-field, where the anode of the decoupling diodes are connected based on feedback transistors. Their collectors are connected via collector resistors to the node point of the first and second resistors of the amplifying part, the emitters are connected to each other on the ground part. and control computer inputs. The output connected is the output of the operational amplifier of the amplifying part.

The wiring of the analog voltage switch according to the invention makes it possible to set the gain in any of the switched channels to any value and at the same time to change the gain in any of these channels by means of an external voltage.

The switch is multichannel and allows to switch analog voltage of any polarity and with the possibility of setting the gain in any switched channel to a defined value.

. The attached drawing shows a detailed wiring diagram with individual blocks.

The wiring consists of an input portion 300, an amplification portion 13, and a feedback member 250. This feedback member 250 connected between the input portion 300 of the analog voltage switch and the amplification portion 13 is a new feature. Its connection allows setting the gain of a defined value in any channel and further allows to change the gain in any of the switched channels by external voltage. The inlet portion 300 consists of individual switching members 301, 302, 303 for each of the switched channels.

The switching member 301 consists of two unipolar transistors 20, 30 controlled by an electric field whose collectors K are connected to each other and connected by means of a decoupling resistor 10 to the input terminal 100 of the switching member 301. The emitter E of the switching unipolar transistor 20 is co-emitted. The switching electrodes of the switching unipolar transistors 21 and 22 of the other switching members 302 and 303 are connected to the input 90 of the amplifying part 13. The control electrode of this switching unipolar transistor 20 is connected to the first control input 120 of the switching member 301 diodes 40 to the cross-section 210 of the feedback member 250, the wiring of which will be described later. The emitter E of the auxiliary unipolar transistor 30 is coupled to the null bus 50 and its control electrode is coupled to the second control input 110 of the switching member 301. Analogously, the other switching members 302 and 303 consisting of unipolar transistors 21, 31 and 22, 32 are connected. isolating resistors 11 and 12. These switching members 302 and 303 are analogically provided with input terminals 101 and 102, first control inputs 121 and 122, second control inputs 111, 112, and series combinations of decoupling resistors 46, 47 with decoupling diodes 41, 42 connected. to the crossfield 210.

The amplifier section 13 consists of an inverting input operational amplifier 1, the output of which is connected to a series combination of the first and second resistors 2 and 3, one of the terminals of the first resistor 2 being a joint. only with the output of the operational amplifier 1 and the second with its outlet to the node 91 of the first and second resistors 2 and 3. A feedback member 250 is connected between this node 91 and the null bus 50. whose second terminal is connected to the inverting input of the operational amplifier 1.

Between the output of the operational amplifier 1 and its inverting input Is the compensating capacitor 7 connected and between the inverting input of the operational amplifier 1 and the neutral bus 50 connected the parallel combination? The non-inverting input of the operational amplifier 1 is connected to the neutral bus 50 by the resistor 6. The output of the operational amplifier 1 is also connected to the output terminal 140 of the wiring.

The feedback member 250 consists of transistors 70, 71, 72 and 73, preferably unipolar, whose emitters E are connected to the zero bus 50 and to whose collectors K are connected resistors 80, 81, 82 and 83, the other terminals of which are connected to the node The control electrodes of the transistors 70, 71, 72 and 73 are coupled to the individual vertical conductors 206, 207 of the cross-field 210. To the horizontal conductors 200, 201 and 202 of this cross-field 210 are The above-mentioned series combinations of the separating resistors 45, 46 and 47 and the separating diodes 40, 41 and 42 are connected. The vertical conductors 206, 207, 208 and 209 of the cross-section 210 are connected to the control input terminals 160, 161, 162 and 163.

In the illustrated embodiment, the horizontal conductor 200 is coupled to the vertical conductors 206 and 207, the horizontal conductor 201 is not coupled to any vertical conductor for the aluminum conductor, and the horizontal conductor 202 is coupled to all the vertical conductors 206, 207, 208. 209.

The operation of the analog voltage switch according to the invention is in accordance with the described example, wiring as follows:

The switched analog voltages q of any polarity are applied to the input terminals 100, 101, 102 of the switching members 301, 302, 303. These analog voltages are arbitrarily switched by the control voltage applied between the first control inputs 120, 121, 122 of these switching members 301 ,. 302, 303. The polarity of this control voltage is such that the respective switching unipolar transistor 20, 21, 22 is energized by this control voltage. The respective second control inputs 110, 111, 112 of the switching members 301, 302, 303 are simultaneously supplied with a voltage of such polarity that the respective auxiliary unipolar transistor 30; 31, 32 is open. When the wiring is not in operation, all the switching unipolar transistors 20, 21, 22 are in the open state and the auxiliary unipolar transistors 30, 31, 32 are in the closed state. If it is desired that a voltage from one input terminal, e.g., input terminal 100, be applied to the output terminal 140, the respective switching member 301 is actuated. Thus, the first control input 120 receives the control voltage which and the switching unipolar is energized. transistor 20 wherein the control voltage applied simultaneously to the second control input 110 opens the auxiliary unipolar transistor 30. The input voltage applied to the input terminal 100 of the switching member 301 is thus applied via the decoupling resistor 10 to the switching unipolar transistor 20 The operational amplifier 1 amplifies the applied voltage, the magnitude of the amplification being independent of the actual feedback network of the operational amplifier 1, i.e. the values of the first and second resistors 2 and 3, and the characteristics and instantaneous connection of the external feedback member 250 The individual switching members 301, 302, 303 at the input portion 300 are coupled to the feedback member 250 by means of a series of separations, resistors 45, 46, 47, and separators, diodes 40, 41, 42, such that e switching of a particular switching member, for example switching member 301, corresponds to a certain state of the feedback member 250, in the illustrated example of switching on transistors 70, 72. The amplification amplitude of the operational amplifier 1 is then determined by the feedback network consisting of the first and second resistors 2, 3 and 82, in this state of the feedback member 250, the node 91 of the first and second resistors 2, 3 to the zero bus 50. In the case of the switching member 303, i.e. the switching unipolar transistor 22, all unipolar transistors 70, 71, 72 and 73 of the feedback member 250, so that the amplification of the operational amplifier 1 is determined by the feedback network consisting of the first and second resistors 2, 3 and the resistors 80, 81, 82 and 83 connecting the node 91 of the first and second resistors. 2 and 3 with a zero bus 50. Finally, in the case closing of the switching member 302 does not close any of the transistor 250's feedback transistors, so that the amplification of the opamp is determined only by resistors 2 and 3.

By using four transistors 70, 71, 72, 73 in parallel in the feedback member 210, sixteen different gain values can be achieved in each channel. An external voltage that can be connected to the control input terminals 180, 161, 182, 183 can be used to permanently turn on any transistor 71, 72, 73, 74 in the feedback member 250. This voltage is separated by a diode and a separation resistor from the respective switching member. . This means that the switching unipolar transistor does not close. In the example, P-channel electrical field control transistors are required to energize the feedback member transistor 250 by applying negative polarity voltage to the control input terminals 160, 161, 162, 183 relative to the zero power bus 50. The decoupling diode, e.g. the decoupling resistor 45 does not allow the switching unipolar transistor 20 to close.

In certain exemplary embodiments, the assignment of certain switching member feedback states 250 to a particular switching member is accomplished by a cross field 210 that allows for easy change of this assignment. However, it will be understood that this cross-field 210 may be replaced by suitable switches.

The wiring of the analog voltage switch according to the invention can be used wherever it is desired to switch analog voltages with different gains in the individual switched channels. This situation occurs especially when evaluating analog signals from different sensors, where the signals from individual sensors have different levels, which would be an obstacle to subsequent processing, for example digital.

Other applications are in measuring exchanges, data acquisition devices and the like. The gain in each channel can also be controlled by the computer output voltages that are applied between the control input terminals 180, 161, 162, / 163 of the feedback member 250 and the zero bus 50. The computer has the ability to adjust the input signal levels to improve , the signal-to-noise ratio and reduced the non-linear distortion typical of small signals.

Claims (1)

' ^Λ Subject Connection of an analog voltage switch comprising at least one switching member. with analog and control inputs, decoupling resistor and switching and auxiliary uni-polar transistor, from amplifier section with resistor and capacitor op amp, zero bus separated from the wiring of parallel capacitor and resistor combinations, the outputs consisting of emitters of switching unipolar switching transistors are connected to an inverting input of an operational amplifier by amplifier parts, characterized in that the first control inputs (120, 121, 122) of the switching members (301, 302, 303) of the invention are connected through a series combination of a decoupling diode (40, 41, 42) and a decoupling resistor (45, 46, 47) to a cross-field (210), where the anode of the diode ^t (40, 41, 42) are connected based on feedback transistors (70, 71, 72, 73) whose collectors are via collector resistors (80 , 81, 82, 83) connected to the node of the first and second resistors (2, 3) of the amplification part (13) and the emitters are of interest are connected to the ground portion (50) and further to the computer control inputs (160, 161, 162, 163), the output of which is formed by the output of the operational amplifier (11) of the amplifying portion (13).