JP2007235807A - Switching circuit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To aim to eliminate variation in off-capacity in a switching circuit that uses a photo MOS relay. <P>SOLUTION: In a switching circuit in which one end of a terminal for turing on/off the first photo MOS relay is connected to a signal transmission line, and the other end of the terminal for turing on/off the first photo MOS relay is connected to the ground via terminating resistance, the switching circuit is equipped with a voltage follower for outputting by receiving voltage at one end side connected to the signal line of the first photo MOS relay, and a second photo MOS relay for turning on/off the connection to the other end side of the first photo MOS relay by receiving the output of the voltage follower. By turing on the second photo MOS relay, when the first photo MOS relay is turned off, signal waveforms between off-terminals of the first photo MOS relay are made identical. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a switching circuit using a photomoss relay.

Conventionally, a mechanical relay is used as a switching part of an analog signal switching circuit.
In addition, mechanical relays have a limited life and are known to have a short life compared to semiconductor relays.
Therefore, in order to extend the life of the relay, a photo moss relay is used as a semiconductor relay.
However, as shown in FIG. 2, the photoMOS relay has an off-capacitance Coff between the on / off terminals, and the off-capacitance Coff varies depending on the voltage V between the terminals as shown in FIG.
Accordingly, when an arbitrary analog signal is input by connecting the photoMOS relay to the path through which the analog signal passes, a potential difference V is generated between the terminals of the photoMOS relay, as shown in FIGS.
In addition, since the voltage of the input analog signal continuously changes with time, the voltage V between terminals continuously fluctuates (ΔV).
As a result, as shown in FIG. 4, when an analog waveform is input, the off-capacitance Coff of the photo MOS relay also changes.
In general, the transmission waveform quality of an analog signal is expressed as distortion, and there has been a problem that the change in the off-capacitance Coff (ΔCoff) deteriorates the transmission waveform quality.

A specific circuit example in which a change in the off-capacitance Coff of the photo MOS relay is a problem will be described below with reference to FIGS.
FIG. 12 shows a switching circuit that turns on / off the connection between the signal transmission line and the terminating resistor R1 by the photo-moss relay K1.
In the switching circuit of FIG. 12, a signal having an arbitrary waveform is input, and the signal is output as terminated or opened by the resistor R1.
FIG. 13 shows a switching circuit that receives and outputs a signal on a signal transmission line by a resistor R1, and outputs a signal by turning on / off the connection to the resistor R2 connected to the ground via the photoMOS relay K1.
In the switching circuit of FIG. 13, a signal having an arbitrary waveform is input, and the attenuation is varied and output.
In FIG. 14, the input signal is amplified and output by the resistance ratio between the resistor R1 and the resistor R2 via the operational amplifier AMP, and the resistor R3 is turned on / off in parallel with the resistor R1 via the photoMOS relay K1. This is a switching circuit that varies the degree of amplification.
In the switching circuit of FIG. 14, a signal having an arbitrary waveform is input, and the signal is variably amplified and output.
FIG. 15 is a circuit in which a resistor R2 connected in parallel with the resistor R1 is turned on / off by a photo-moss relay K1 in a circuit terminated with a resistor R1 on the signal transmission line.
Then, in the switching circuit of FIG. 15, a signal having an arbitrary waveform is input, and the terminal resistance value of the signal line is varied to output a signal.
FIG. 16 is a switching circuit that outputs the analog conversion output of the D / A converter D / A1 via the photomoss relay K1, and outputs the analog output of the D / A converter D / A2 as an interrupt via the photomoss relay K2. is there.
In the switching circuit of FIG. 16, for example, one is signaled and the other is offset and output as an interrupt.
In FIG. 17, the analog conversion output of the D / A converter D / A is received by the filter F, and the filter F output is output via the photoMOS relay K1, or the analog conversion output of the D / A converter D / A is 2 This is a switching circuit that outputs via two photomoss relays K2 and K3 connected in series.
Then, in the switching circuit of FIG. 17, the through output of the analog conversion signal and the output filtered by the filter F are switched and output.
Patent Publication 2004-289410

  The problem to be solved is to prevent the deterioration of the waveform quality of the output signal by avoiding the influence of the change in the capacitance between the terminals when the photo mos relay is used as the switching part of the switching circuit. .

The first of the present invention is
A switching circuit in which one end of a terminal for turning on / off the first photoMOS relay is connected to a signal transmission line, and the other end of the terminal for turning on / off of the first photomoss relay is grounded via a terminating resistor In
A voltage follower that receives and outputs a voltage at one end connected to the signal line of the first photoMOS relay;
A second photo MOS relay that receives and outputs the output of the voltage follower and turns on / off the connection with the other end of the first photo MOS relay;
A switching circuit characterized in that when the first photoMOS relay is turned off, the second photomoss relay is turned on so that the signal waveforms between the off terminals of the first photomoss relay are the same. .

The second of the present invention is
Receive the input signal at the first resistor and output the signal,
In the switching circuit in which one end of the first photoMOS relay that is turned on / off is connected to the output side of the first resistor and the other end is connected to the ground via the second resistor.
A voltage follower that receives and outputs a voltage at one end of the first photoMOS relay;
A second photo MOS relay that receives and outputs the output of the voltage follower and turns on / off the connection with the other end of the first photo MOS relay;
Switching in which the second photoMOS relay is turned on when the first photomoss relay is turned off so that the signal waveforms between the off terminals of the first photomoss relay are the same. circuit.

The third aspect of the present invention is
The input signal is amplified and output by an operational amplifier based on the resistance ratio between the first resistor and the second resistor.
In the switching circuit for changing the amplification factor by connecting the third resistor, which is connected in parallel with the first resistor, on / off via the first photoMOS relay K1,
A voltage follower that receives and outputs a voltage at one end of the first photoMOS relay;
A second photo MOS relay that receives and outputs the output of the voltage follower and turns on / off the connection with the other end of the first photo MOS relay;
Switching in which the second photoMOS relay is turned on when the first photomoss relay is turned off so that the signal waveforms between the off terminals of the first photomoss relay are the same. circuit.

The fourth aspect of the present invention is
Terminate and connect the signal transmission line and ground with a first resistor,
In a switching circuit in which one end of a terminal for turning on / off the first photoMOS relay is connected to the signal transmission line, and the other end is connected to the ground via a second resistor.
A voltage follower that receives and outputs a voltage at one end connected to the signal line of the first photoMOS relay;
A second photo MOS relay that receives the output of the voltage follower and is connected to the other end of the first photo MOS relay.
A switching circuit characterized in that when the first photoMOS relay is turned off, the second photomoss relay is turned on so that the signal waveforms between the off terminals of the first photomoss relay are the same. .

The fifth aspect of the present invention is
In response to the analog conversion output of the first D / A converter, ON / OFF terminals of the first photoMOS relay and the second photoMOS relay are connected in series to output a signal,
In the switching circuit that receives the analog conversion output of the second D / A converter and connects it to the signal output via the third photo-moss relay,
A voltage follower that receives and outputs an analog conversion output of the second D / A converter;
A fourth photomoss relay that receives the output of the voltage follower and is on / off connected to a connection point between the first photomoss relay and the second photomoss relay;
When the first photomoss relay and the second photomoss relay are turned off, the third photomoss relay and the fourth photomoss relay are turned on, and between the off terminals of the second photomoss relay A switching circuit characterized by having the same signal waveform.

The sixth of the present invention is
A D / A converter that converts a digital signal into an analog signal;
A filter that receives the output of the D / A converter and outputs the filtered signal;
A first photo-mos relay that receives the filtered output and outputs on / off of the filter;
A second photomoss relay that receives the first photomoss relay output and outputs on / off;
A third photo MOS relay that receives an analog conversion output of the D / A converter and outputs on / off;
A fourth photomoss relay that receives the output of the third photomoss relay and is on / off connected to the output terminal of the second photomoss relay;
A voltage follower that receives and outputs the output of the second photoMOS relay;
A fifth photomoss relay that receives the output of the voltage follower and is on / off connected to a connection point between the first photomoss relay and the second photomoss relay;
When the first photoMOS relay and the second photomoss relay are turned off, the third photomoss relay, the fourth photomoss relay, and the fifth photomoss relay are turned on, and the second photomoss relay is turned on. A switching circuit characterized in that the signal waveform between the off terminals of the MOS relay is the same.

The seventh of the present invention is
A first arbitrary signal generator for generating an arbitrary waveform signal and outputting the signal transmission line;
In a switching circuit in which one end of a terminal for turning on / off the first photoMOS relay is connected to the signal transmission line, and the other end is connected to the ground via a termination resistor.
A second arbitrary signal generator for generating a signal having the same arbitrary waveform in synchronization with the first arbitrary signal generator;
A second photoMOS relay that receives the output of the second arbitrary signal generator and is on / off connected to the other end of the first photomoss relay;
A switching circuit characterized in that when the first photoMOS relay is turned off, the second photomoss relay is turned on so that the signal waveforms between the off terminals of the first photomoss relay are the same. .

  The switching circuit of the present invention has an advantage that the OFF-capacitance variation of the photo MOS relay is 0 V because the potential difference between the terminals at the time of OFF is 0 V, and the transmission waveform quality is not deteriorated.

  The switching circuit of the present invention is realized by setting the terminal potential difference to 0 V so that the one terminal potential is the same as the other terminal potential when the photo MOS relay is turned off by the high impedance input voltage follower.

FIG. 1 shows an embodiment in which the present invention is applied to the switching circuit of FIG.
In FIG. 1, a voltage follower BF is constituted by an operational amplifier, and a potential at point A is applied to point B via a photoMOS relay K2.
In this case, control is performed so that the photo mos relay K2 is turned on when the photo mos relay K1 is off, and the photo mos relay K2 is turned off when the photo mos relay K1 is on.
Accordingly, when the photo MOS relay K1 is off, the photo MOS relay K2 is turned on, and the same waveform as the input waveform is observed at the observation points A and B.
Since the point A and the point B have the same waveform, the fluctuation ΔV = 0V of the voltage across the terminals of the photo MOS relay K1.
Further, since the change ΔV = 0V in the voltage across the terminals of the photoMOS relay K1, the change ΔCoff in the OFF capacitance Coff of the photoMOS relay K1 is constant.
Similarly, when the photoMOS relay K1 is ON and the photoMOS relay K2 is OFF, the output point of the voltage follower BF and the point B have the same waveform, so that the fluctuation ΔV = 0V between the terminals of the photoMOS relay K2 Therefore, the change ΔCoff of the off-capacitance Coff of the photo MOS relay K2 becomes zero.
1 can input a signal having an arbitrary waveform and transmit and output a signal waveform with less distortion.

FIG. 5 shows an embodiment in which the present invention is applied to the switching circuit of FIG.
In FIG. 5, the voltage follower BF applies a potential on the output side of the resistor R1 to the point B via the photo MOS relay K2.
In this case, control is performed so that the photo mos relay K2 is turned on when the photo mos relay K1 is off, and the photo mos relay K2 is turned off when the photo mos relay K1 is on.
Therefore, when the photo MOS relay K1 is off, the photo MOS relay K2 is turned on, and the same waveform is observed at the points A and B.
Since the terminals of the photoMOS relay K1 have the same waveform, the fluctuation ΔV = 0V of the terminal voltage of the photoMOS relay K1.
Further, since the change ΔV = 0V in the voltage across the terminals of the photoMOS relay K1, the change ΔCoff in the OFF capacitance Coff of the photoMOS relay K1 is constant.
Similarly, when the photo MOS relay K1 is on and the photo MOS relay K2 is off, the point A and the point B have the same waveform, so the fluctuation of the voltage across the terminals of the photo MOS relay K2 becomes ΔV = 0V, and the photo MOS relay The change ΔCoff of the off-capacitance Coff of the relay K2 becomes zero.
As described above, in the switching circuit of FIG. 5, a signal having an arbitrary waveform can be input and an attenuation signal with less distortion can be output.

FIG. 6 shows an embodiment in which the present invention is applied to the switching circuit of FIG.
In FIG. 6, the voltage follower BF applies a potential at the point A to the point B via the photo MOS relay K2.
In this case, control is performed so that the photo mos relay K2 is turned on when the photo mos relay K1 is off, and the photo mos relay K2 is turned off when the photo mos relay K1 is on.
Therefore, when the photo MOS relay K1 is off, the photo MOS relay K2 is turned on, and the same waveform is observed at the points A and B.
Since the terminals of the photoMOS relay K1 have the same waveform, the fluctuation ΔV = 0V of the terminal voltage of the photoMOS relay K1.
Further, since the change ΔV = 0V in the voltage across the terminals of the photoMOS relay K1, the change ΔCoff in the OFF capacitance Coff of the photoMOS relay K1 is constant.
Similarly, when the photo MOS relay K1 is on and the photo MOS relay K2 is off, the point A and the point B have the same waveform, so the fluctuation of the voltage across the terminals of the photo MOS relay K2 becomes ΔV = 0V, and the photo MOS relay The change ΔCoff of the off-capacitance Coff of the relay K2 becomes zero.
As described above, in the switching circuit of FIG. 6, a signal having an arbitrary waveform can be input and an amplified signal with less distortion can be variably output.
Further, since the input of the operational amplifier AMP has the same potential on the plus side and the minus side, the potential on the minus side may be used as the input signal of the voltage follower BF as shown in FIG.

FIG. 8 shows an embodiment in which the present invention is applied to the switching circuit of FIG.
In FIG. 8, a voltage follower BF applies a potential at a point A to a point B via a photo MOS relay K2.
In this case, control is performed so that the photo mos relay K2 is turned on when the photo mos relay K1 is off, and the photo mos relay K2 is turned off when the photo mos relay K1 is on.
Accordingly, when the photo MOS relay K1 is off, the photo MOS relay K2 is turned on, and the same waveform as the input waveform is observed at the observation points A and B.
Since the point A and the point B have the same waveform, the fluctuation ΔV = 0V of the voltage across the terminals of the photo MOS relay K1.
Further, since the change ΔV = 0V in the voltage across the terminals of the photoMOS relay K1, the change ΔCoff in the OFF capacitance Coff of the photoMOS relay K1 is constant.
Similarly, when the photoMOS relay K1 is ON and the photoMOS relay K2 is OFF, the output point of the voltage follower BF and the point B have the same waveform, so that the fluctuation ΔV = 0V between the terminals of the photoMOS relay K2 Therefore, the change ΔCoff of the off-capacitance Coff of the photo MOS relay K2 becomes zero.
As described above, in the switching circuit of FIG. 8, a signal having an arbitrary waveform can be input, and the terminal resistance value of the signal line can be varied to output a signal with less distortion.

FIG. 9 shows an embodiment in which the present invention is applied to the switching circuit of FIG.
In FIG. 9, the voltage follower BF applies a potential at the point A to the point B via the photo MOS relay K2.
In this case, when the photo mos relay K1 and the photo mos relay K2 are off, the photo mos relay K3 and the photo mos relay K4 are turned on. When the photo mos relay K1 and the photo mos relay K2 are on, the photo mos relay K3 and the photo mos relay K4 are turned on. Is controlled to turn off.
Therefore, when the photo MOS relay K1 and the photo MOS relay K2 are OFF, the photo MOS relay K3 and the photo MOS relay K4 are ON, and the same waveform is observed at the points A and B.
Since the terminals of the photoMOS relay K2 have the same waveform, the fluctuation ΔV = 0V of the terminal voltage of the photoMOS relay K2.
Further, since the change ΔV = 0V in the voltage across the terminals of the photoMOS relay K2, the change ΔCoff in the off-capacitance Coff of the photoMOS relay K2 is constant.
Similarly, when the photoMOS relay K1 and the photomoss relay K2 are on, the photomoss relay K3 and the photomoss relay K4 are off, the point A and the point B have the same waveform, so the voltage across the terminals of the photomoss relay K4. Variation ΔV = 0V, and the change ΔCoff in the off-capacitance Coff of the photo-moss relay K4 becomes zero.
As described above, in the switching circuit of FIG. 6, a digital signal can be input and an analog signal with less interruption distortion can be output as the offset signal of the digital signal.

FIG. 10 shows an embodiment in which the present invention is applied to the switching circuit of FIG.
In FIG. 10, a voltage follower BF applies a potential at a point A to a point B via a photo MOS relay K5.
In this case, when the photo mos relay K1 and photo mos relay K2 are off, the photo mos relay K3, photo mos relay K4 and photo mos relay K5 are on, and when the photo mos relay K1 and photo mos relay K2 are on, the photo mos relay K3, Photo MOS relay K4 and photo MOS relay K5 are controlled to be turned off.
Therefore, the same waveform is observed at the points A and B when the photo moss relay K1 and photo moss relay K2 are off and the photo moss relay K3, photo moss relay K4 and photo moss relay K5 are on.
Since the terminals of the photoMOS relay K2 have the same waveform, the fluctuation ΔV = 0V of the terminal voltage of the photoMOS relay K2.
Further, since the change ΔV = 0V in the voltage across the terminals of the photoMOS relay K2, the change ΔCoff in the off-capacitance Coff of the photoMOS relay K2 is constant.
Similarly, when the photo MOS relay K1 and the photo MOS relay K2 are on, the photo MOS relay K3, the photo MOS relay K4 and the photo MOS relay K5 are off, the point A and the point B have the same waveform, so the photo MOS relay The fluctuation ΔV = 0 of the terminal voltage of K5 becomes 0V, and the change ΔCoff of the off-capacitance Coff of the photoMOS relay K5 becomes zero.
As described above, a signal waveform with less distortion can be output in the switching circuit of FIG.

FIG. 11 shows a switching circuit for turning on / off the connection to the terminating resistor R by the photoMOS relay K1 at the point A of the signal transmission line.
11 is an application example of the present invention in which a signal having an arbitrary waveform is input from an arbitrary signal generator AWG1 and a signal waveform is transmitted and output in the circuit of FIG.
In FIG. 11, in synchronization with the arbitrary signal generator AWG1, the same signal as the input signal at the point A is applied from the arbitrary signal generator AWG2 to the point B via the photoMOS relay K2.
In this case, control is performed so that the photo mos relay K2 is turned on when the photo mos relay K1 is off, and the photo mos relay K2 is turned off when the photo mos relay K1 is on.
Accordingly, when the photo MOS relay K1 is off, the photo MOS relay K2 is turned on, and the same waveform as the input waveform is observed at the observation points A and B.
Since the point A and the point B have the same waveform, the fluctuation ΔV = 0V of the voltage across the terminals of the photo MOS relay K1.
Further, since the change ΔV = 0V in the voltage across the terminals of the photoMOS relay K1, the change ΔCoff in the OFF capacitance Coff of the photoMOS relay K1 is constant.
Similarly, when the photoMOS relay K1 is ON and the photoMOS relay K2 is OFF, the output point of the arbitrary signal generator AWG2 and the point B have the same waveform, so that the fluctuation ΔV = between the terminals of the photoMOS relay K2 The change ΔCoff of the off-capacitance Coff of the photo MOS relay K2 becomes 0.
As described above, in the switching circuit of FIG. 11, a signal having an arbitrary waveform can be input and a signal waveform with less distortion can be transmitted and output.

  Since the switching circuit of the present invention is configured such that the change in the off-capacitance of the photo-moss relay becomes zero, it can be similarly implemented in circuits other than the above-described embodiments.

It is an example of a basic circuit diagram of the present invention. It is an example of an off capacity figure of a photo moss relay. It is an example of a relation figure of off capacity and voltage between terminals. It is an example of a relation figure of an input signal and off capacity of the present invention. It is an example of an attenuation circuit diagram of the present invention. It is an example of an amplifier circuit diagram of the present invention. It is an example of an amplifier circuit diagram of the present invention. It is an example of a resistance value conversion circuit diagram of the present invention. It is an example of an interrupt circuit diagram of the present invention. It is an example of a filter circuit diagram of the present invention. It is an example of an applied circuit diagram of the present invention. It is a conventional basic circuit diagram example. It is a conventional attenuation circuit diagram example. It is a conventional amplifier circuit diagram example. It is a conventional resistance value conversion circuit diagram example. It is a conventional interrupt circuit diagram example. It is a conventional filter circuit diagram example.

Explanation of symbols

R Terminating resistance R1, R2, R3 resistance
K1, K2, K3 Photo MOS relay Coff Photo MOS relay off capacity
V PhotoMOS relay terminal voltage
D / A, D / A1, D / A2 D / A converters AWG1, AWG2 Arbitrary signal generator

Claims (7)

A switching circuit in which one end of a terminal for turning on / off the first photoMOS relay is connected to a signal transmission line, and the other end of the terminal for turning on / off of the first photomoss relay is grounded via a terminating resistor In
A voltage follower that receives and outputs a voltage at one end connected to the signal line of the first photoMOS relay;
A second photo MOS relay that receives and outputs the output of the voltage follower and turns on / off the connection with the other end of the first photo MOS relay;
A switching circuit characterized in that when the first photoMOS relay is turned off, the second photomoss relay is turned on so that the signal waveforms between the off terminals of the first photomoss relay are the same. . Receive the input signal at the first resistor and output the signal,
In the switching circuit in which one end of the first photoMOS relay that is turned on / off is connected to the output side of the first resistor and the other end is connected to the ground via the second resistor.
A voltage follower that receives and outputs a voltage at one end of the first photoMOS relay;
A second photo MOS relay that receives and outputs the output of the voltage follower and turns on / off the connection with the other end of the first photo MOS relay;
Switching in which the second photoMOS relay is turned on when the first photomoss relay is turned off so that the signal waveforms between the off terminals of the first photomoss relay are the same. circuit. The input signal is amplified and output by an operational amplifier based on the resistance ratio between the first resistor and the second resistor.
In the switching circuit for changing the amplification factor by connecting the third resistor, which is connected in parallel with the first resistor, on / off via the first photoMOS relay K1,
A voltage follower that receives and outputs a voltage at one end of the first photoMOS relay;
A second photo MOS relay that receives and outputs the output of the voltage follower and turns on / off the connection with the other end of the first photo MOS relay;
Switching in which the second photoMOS relay is turned on when the first photomoss relay is turned off so that the signal waveforms between the off terminals of the first photomoss relay are the same. circuit. Terminate and connect the signal transmission line and ground with a first resistor,
In a switching circuit in which one end of a terminal for turning on / off the first photoMOS relay is connected to the signal transmission line, and the other end is connected to the ground via a second resistor.
A voltage follower that receives and outputs a voltage at one end connected to the signal line of the first photoMOS relay;
A second photo MOS relay that receives the output of the voltage follower and is connected to the other end of the first photo MOS relay.
A switching circuit characterized in that when the first photoMOS relay is turned off, the second photomoss relay is turned on so that the signal waveforms between the off terminals of the first photomoss relay are the same. . In response to the analog conversion output of the first D / A converter, ON / OFF terminals of the first photoMOS relay and the second photoMOS relay are connected in series to output a signal,
In the switching circuit that receives the analog conversion output of the second D / A converter and connects it to the signal output via the third photo-moss relay,
A voltage follower that receives and outputs an analog conversion output of the second D / A converter;
A fourth photomoss relay that receives the output of the voltage follower and is on / off connected to a connection point between the first photomoss relay and the second photomoss relay;
When the first photomoss relay and the second photomoss relay are turned off, the third photomoss relay and the fourth photomoss relay are turned on, and between the off terminals of the second photomoss relay A switching circuit characterized by having the same signal waveform. A D / A converter that converts a digital signal into an analog signal;
A filter that receives the output of the D / A converter and outputs the filtered signal;
A first photo-mos relay that receives the filtered output and outputs on / off of the filter;
A second photomoss relay that receives the first photomoss relay output and outputs on / off;
A third photo MOS relay that receives an analog conversion output of the D / A converter and outputs on / off;
A fourth photomoss relay that receives the output of the third photomoss relay and is on / off connected to the output terminal of the second photomoss relay;
A voltage follower that receives and outputs the output of the second photoMOS relay;
A fifth photomoss relay that receives the output of the voltage follower and is on / off connected to a connection point between the first photomoss relay and the second photomoss relay;
When the first photoMOS relay and the second photomoss relay are turned off, the third photomoss relay, the fourth photomoss relay, and the fifth photomoss relay are turned on, and the second photomoss relay is turned on. A switching circuit characterized in that the signal waveform between the off terminals of the MOS relay is the same. A first arbitrary signal generator for generating an arbitrary waveform signal and outputting the signal transmission line;
In a switching circuit in which one end of a terminal for turning on / off the first photoMOS relay is connected to the signal transmission line, and the other end is connected to the ground via a termination resistor.
A second arbitrary signal generator for generating a signal having the same arbitrary waveform in synchronization with the first arbitrary signal generator;
A second photoMOS relay that receives the output of the second arbitrary signal generator and is on / off connected to the other end of the first photomoss relay;
A switching circuit characterized in that when the first photoMOS relay is turned off, the second photomoss relay is turned on so that the signal waveforms between the off terminals of the first photomoss relay are the same. .

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