JP6595217B2 - Signal amplification device - Google Patents

Description

  Embodiments described herein relate generally to a signal amplifying apparatus.

  Conventionally, an amplifier unit that amplifies a high-frequency signal by connecting a plurality of amplifiers in series is known. A gate power source and a drain power source are connected to the amplifier unit to drive the amplifier. Here, in order to simplify the circuit, a common gate power source and drain power source are connected to a plurality of amplifiers for each amplifier unit. However, if the gate power supply is shared by each amplifier unit, the level of the high-frequency signal that is fed back to the amplifier through a line connecting the plurality of amplifiers and the gate power supply increases. Oscillation occurs as the gain of the high-frequency signal fed back to the amplifier increases, and the fluctuation of the gate bias voltage supplied to the amplifier increases, and the operation of the amplifier unit may become unstable.

JP 2005-12560 A JP-A-8-335835

  The problem to be solved by the present invention is to provide a signal amplifying device capable of operating an amplifier more stably.

The signal amplifying device of the embodiment has a first amplifier unit, a second amplifier unit, and an attenuating unit. The first amplifier unit and the second amplifier unit include two or more amplifiers connected in series, and are connected to each other in series. The attenuating unit is provided between the first amplifier unit and the second amplifier unit. In the signal amplifying device of the embodiment, a gate power supply is shared between at least one amplifier of the amplifiers included in the first amplifier unit and at least one amplifier of the amplifiers included in the second amplifier unit. ing. The same gate bias voltage is applied to the first amplifier and the third amplifier.
The same gate bias voltage is applied to the second amplifier and the fourth amplifier. The same drain bias voltage is applied to the first amplifier and the second amplifier. The same drain bias voltage is applied to the third amplifier and the fourth amplifier.

1 is a configuration diagram of a signal amplification device 1 according to an embodiment. The figure explaining the feedback loop La which generate | occur | produces in the 1st gate power supply connection part 30-1 in the signal amplification apparatus 1 of embodiment. The figure explaining the feedback loop Lb which generate | occur | produces in the 2nd gate power supply connection part 30-2 in the signal amplification apparatus 1 of embodiment. The other block diagram of the signal amplification apparatus 1 of embodiment. The block diagram of 1 A of signal amplification apparatuses which concern on other embodiment. The block diagram of signal amplification apparatus 1Aa which concerns on the modification of signal amplification apparatus 1A. The block diagram of the signal amplification apparatus 1B which concerns on other embodiment.

  Hereinafter, a signal amplification device according to an embodiment will be described with reference to the drawings.

  FIG. 1 is a configuration diagram of a signal amplification device 1 according to the embodiment. The signal amplifying device 1 is, for example, a device that amplifies a high-frequency signal generated in response to reception of electromagnetic waves by an antenna element (not shown) or a high-frequency signal for transmitting electromagnetic waves by an antenna element.

  The signal amplifying apparatus 1 includes, for example, a first amplifier unit 10-1, a second amplifier unit 10-2, a first drain power supply connection unit 20-1, and a second drain power supply connection unit 20-2. A first gate power supply connection unit 30-1, a second gate power supply connection unit 30-2, and an attenuation unit 40. The signal amplifying device 1 is configured, for example, as a monolithic microwave integrated circuit (MMIC (Monolithic Microwave Integrated Circuit) that forms each part on a single substrate. In the following, the signal amplifying device 1 is a first amplifier unit. Although described as having two amplifier units 10-1 and 10-2, the signal amplifying apparatus 1 may include three or more amplifier units.

  The first amplifier unit 10-1 and the second amplifier unit 10-2 are connected in series with the signal input terminal 1a and the signal output terminal 1b as both ends with the attenuator 40 interposed therebetween. The first amplifier unit 10-1 amplifies the high frequency signal supplied via the signal input terminal 1a and outputs the amplified signal to the second amplifier unit 10-2 side. The second amplifier unit 10-2 amplifies the high frequency signal supplied from the first amplifier unit 10-1 side and outputs the amplified signal to the signal output terminal 1b.

  Each of the first amplifier unit 10-1 and the second amplifier unit 10-2 includes two or more amplifiers connected in series, and the two or more amplifiers are sealed in a package with a sealing material such as resin. ing. In the embodiment, each of the first amplifier unit 10-1 and the second amplifier unit 10-2 includes two amplifiers 10a and 10b connected in series. The amplifiers 10a and 10b are amplifiers that operate in a state in which a drain bias voltage and a gate bias voltage are applied to amplify a high-frequency signal. The amplifiers 10a and 10b are amplifiers having, for example, field effect transistors. When a high frequency signal is supplied to the gates with the gate bias voltage and the drain bias voltage applied, the amplifiers 10a and 10b output the amplified high frequency signal from the drain. In the following description, a configuration example in which the first amplifier unit 10-1 and the second amplifier unit 10-2 include two amplifiers 10a and 10b will be described. However, each amplifier unit includes three or more amplifier units. An amplifier may be provided.

  The amplifier 10a of the first amplifier unit 10-1 amplifies the high frequency signal supplied through the signal input terminal 1a and outputs the amplified signal to the amplifier 10b. The amplifier 10b of the first amplifier unit 10-1 amplifies the high-frequency signal output from the amplifier 10a and outputs the amplified signal to the second amplifier unit 10-2 side. The amplifier 10a of the second amplifier unit 10-2 amplifies the high frequency signal supplied from the first amplifier unit 10-1 side and outputs the amplified signal to the amplifier 10b. The amplifier 10b of the second amplifier unit 10-2 amplifies the high frequency signal output by the amplifier 10a and outputs the amplified signal to the signal output terminal 1b.

  In the signal amplifying device 1 of the embodiment, the set of the amplifiers 10a and 10b of the first amplifier unit 10-1 is an amplifier that operates by applying the same drain bias voltage. The pair of amplifiers 10a and 10b of the second amplifier unit 10-2 is an amplifier that operates in a state where the same drain bias voltage is applied. Further, the set of the amplifier 10a of the first amplifier unit 10-1 and the amplifier 10a of the second amplifier unit 10-2 is a type of amplifier that operates with the same gate bias voltage applied. Further, the set of the amplifier 10b of the first amplifier unit 10-1 and 10b of the second amplifier unit 10-2 is a type of amplifier that operates in the state where the same gate bias voltage is applied.

  The first drain power supply connection unit 20-1 is connected between the two amplifiers 10a and 10b in the first amplifier unit 10-1 and the drain power supply (1). The first drain power supply connection unit 20-1 includes a drain power supply terminal 20a, a first drain power supply line 22a, and a second drain power supply line 22b. The first drain power supply line 22a and the second drain power supply line 22b are lines branched from the drain power supply terminal 20a.

  The first drain power supply line 22a has one end connected to the drain power supply terminal 20a and the other end connected to the amplifier 10a of the first amplifier unit 10-1. A decoupling capacitor 24a for absorbing high frequency noise may be connected to the first drain power supply line 22a. One end of the decoupling capacitor 24a is connected to the first drain power supply line 22a, and the other end of the decoupling capacitor 24a is connected to the ground terminal 26a.

  The second drain power supply line 22b has one end connected to the drain power supply terminal 20a and the other end connected to the amplifier 10b of the first amplifier unit 10-1. A decoupling capacitor 24b for absorbing high frequency noise may be connected to the second drain power supply line 22b. One end of the decoupling capacitor 24b is connected to the second drain power supply line 22b, and the other end of the decoupling capacitor 24b is connected to the ground terminal 26b.

  As described above, the signal amplifying apparatus 1 includes the first drain power supply connection unit 20-1 to share the drain power supply (1) between the amplifiers 10a and 10b of the first amplifier unit 10-1. .

  The second drain power supply connection unit 20-2 is connected between the two amplifiers 10a and 10b in the second amplifier unit 10-2 and the drain power supply (2). Similarly to the first drain power supply connection unit 20-1, the second drain power supply connection unit 20-2 includes a drain power supply terminal 20a, a first drain power supply line 22a, and a second drain power supply line 22b. Prepare. Thereby, the second drain power supply connection unit 20-2 shares the drain power supply (2) between the amplifiers 10a and 10b of the second amplifier unit 10-2.

  The first gate power connection 30-1 connects the amplifier 10a in the first amplifier unit 10-1 and the amplifier 10a in the second amplifier unit 10-2 to the gate power supply (1). The first gate power connection 30-1 includes a gate power terminal 30a, a first gate power line 32a, and a second gate power line 32b. The first gate power supply line 32a and the second gate power supply line 32b are lines branched from the gate power supply terminal 30a.

  The first gate power supply line 32a has one end connected to the gate power supply terminal 30a and the other end connected to the amplifier 10a of the first amplifier unit 10-1. A decoupling capacitor 34a for absorbing high frequency noise may be connected to the first gate power supply line 32a. One end of the decoupling capacitor 34a is connected to the first gate power supply line 32a, and the other end of the decoupling capacitor 34a is connected to the ground terminal 36a.

  The second gate power supply line 32b has one end connected to the gate power supply terminal 30a and the other end connected to the amplifier 10a of the second amplifier unit 10-2. A decoupling capacitor 34b for absorbing high frequency noise may be connected to the second gate power supply line 32b. One end of the decoupling capacitor 34b is connected to the second gate power supply line 32b, and the other end of the decoupling capacitor 34b is connected to the ground terminal 36b.

  As described above, the signal amplifying apparatus 1 includes the first gate power supply connection unit 30-1 so that the amplifier 10a of the first amplifier unit 10-1 and the amplifier 10a of the second amplifier unit 10-2 are connected. The gate power supply (1) is shared.

  The second gate power supply connection unit 30-2 is connected between the amplifier 10b in the first amplifier unit 10-1 and the amplifier 10b in the second amplifier unit 10-2, and the gate power supply (2). Similarly to the first gate power supply connection unit 30-1, the second gate power supply connection unit 30-2 includes a gate power supply terminal 30a, a first gate power supply line 32a, and a second gate power supply line 32b. Prepare. The first gate power supply line 32a of the second gate power supply connection unit 30-2 connects the gate power supply terminal 30a and the amplifier 10b of the first amplifier unit 10-1. The second gate power supply line 32b of the second gate power supply connection unit 30-2 connects the gate power supply terminal 30a and the amplifier 10b of the second amplifier unit 10-2. Thereby, the second gate power supply connection unit 30-2 shares the gate power supply (2) between the amplifier 10b of the first amplifier unit 10-1 and the amplifier 10b of the second amplifier unit 10-2.

  The attenuator 40 includes an attenuator that attenuates the level of the signal output by the first amplifier unit 10-1 to a predetermined level. It is desirable that the attenuator 40 attenuates the level of signal components other than the signal component amplified by its own device. The attenuation unit 40 is, for example, a π-type attenuator that includes a first resistor 42, a second resistor 44, and a third resistor 46. The first resistor 42 has one end connected to the signal output end of the first amplifier unit 10-1, and the other end connected to the signal input end of the second amplifier unit 10-2. The second resistor 44 has one end connected to the input side of the first resistor 42 and the other end connected to the ground terminal 44a. The third resistor 46 has one end connected to the output side of the first resistor 42 and the other end connected to the ground terminal 46a. It is desirable that the resistance values of the first resistor 42, the second resistor 44, and the third resistor 46 are set so as to adjust the attenuation amount of the signal level. Note that the attenuation unit 40 may have a configuration including not only reactance but also an inductor and a capacitor.

FIG. 2 is a diagram illustrating a feedback loop La generated in the first gate power supply connection unit 30-1 in the signal amplifying device 1 according to the embodiment. FIG. 3 is a diagram illustrating a feedback loop Lb generated in the second gate power supply connection unit 30-2 in the signal amplifying device 1 of the embodiment.
When the signal amplifier 1 amplifies the high frequency signal by the first amplifier unit 10-1 and the second amplifier unit 10-2, the first amplifier unit 10-1 and the second amplifier unit 10-2 are used. Thus, a feedback loop is formed in which the high-frequency signal output by the signal is fed back to the gate bias voltage supply lines of the first amplifier unit 10-1 and the second amplifier unit 10-2. As shown in FIG. 2, the feedback loop La includes the second gate power source of the first gate power source connection unit 30-1 from the amplifiers 10a of the first amplifier unit 10-1 and the second amplifier unit 10-2. The signal is supplied to the attenuation unit 40 through the line 32b and the first gate power supply line 32a. Further, as shown in FIG. 3, the feedback loop Lb includes the second amplifier of the second gate power supply connection unit 30-2 from the amplifier 10a of the first amplifier unit 10-1 and the second amplifier unit 10-2. The signal is supplied to the attenuation unit 40 through the gate power supply line 32b and the first gate power supply line 32a. The signal flowing through the feedback loops La and Lb is attenuated by passing through the attenuation unit 40. Thereby, the signal amplifying apparatus 1 can attenuate the level of the signal forming the feedback loops La and Lb.

As described above, according to the signal amplifying device 1 of the embodiment, the attenuation unit 40 is provided between the first amplifier unit 10-1 and the second amplifier unit 10-2, and the first amplifier unit 10 is provided. -1 amplifier and the amplifier of the second amplifier unit 10-2 share a gate power source. Specifically, in the signal amplifying apparatus 1 of the embodiment, the amplifier of the first amplifier unit 10-1, the amplifier of the second amplifier unit 10-2, and the gate power supply are connected to the first gate power supply line 32a and the second amplifier. The attenuator 40 is connected between the signal output side of the first amplifier unit 10-1 and the signal input side of the second amplifier unit 10-2. Thereby, in the signal amplifying device 1 of the embodiment, the high-frequency signals amplified by the first amplifier unit 10-1 and the second amplifier unit 10-2 are the first gate power line 32a and the second gate power line. Even if the feedback loops La and Lb are formed by flowing to 32b, the level of the signal forming the feedback loops La and Lb can be suppressed by the attenuation unit 40. As a result, according to the signal amplifying apparatus 1 of the embodiment, it is possible to suppress the fluctuation of the gate bias voltage supplied to the amplifier unit from increasing, and the amplifier unit can be operated more stably.
Further, according to the signal amplifying apparatus 1 of the embodiment, it is not necessary to provide the attenuating unit 40 in the packaged first amplifier unit 10-1 or the second amplifier unit 10-2. It is possible to suppress an increase in fluctuation of the gate bias voltage supplied to the unit.

  FIG. 4 is another configuration diagram of the signal amplifying apparatus 1 according to the embodiment. In the signal amplifying apparatus 1 of the above-described embodiment, the attenuation unit 40 may include a resistor 400 instead of the attenuator. The resistor 400 is preferably set to a resistance value that can reduce the signal level so as to suppress the gain of the high-frequency signal forming the feedback loop. According to the signal amplifying apparatus 1 of the embodiment, the level of the signal forming the feedback loop can be attenuated by the resistor 400.

  FIG. 5 is a configuration diagram of a signal amplifying apparatus 1A according to another embodiment. FIG. 5 shows an example in which there are three amplifier units as a configuration of another embodiment, but it is needless to say that the configuration includes two or more amplifier units. In the signal amplifying apparatus 1A, three amplifier units 10-1, 10-2, and 10-3 each including two amplifiers 10a and 10b are connected in series. In the signal amplifying apparatus 1A, the attenuator 40-1 is connected between the first amplifier unit 10-1 and the second amplifier unit 10-2, and the second amplifier unit 10-2 and the third amplifier unit 10-2 are connected to each other. An attenuation unit 40-2 is connected to the amplifier unit 10-3.

  The signal amplifying apparatus 1A shares the drain power source (1) between the two amplifiers 10a and 10b of the first amplifier unit 10-1. In addition, the signal amplifying apparatus 1A shares the drain power supply (2) between the two amplifiers 10a and 10b of the second amplifier unit 10-2. Furthermore, the signal amplifying apparatus 1A shares the drain power supply (3) between the two amplifiers 10a and 10b of the third amplifier unit 10-3.

  The signal amplifying apparatus 1A connects the first gate power supply line 32a and the second gate power supply line 32b branched from the gate power supplies (1), (2), and (3) to amplifiers of different amplifier units. In the signal amplifying apparatus 1A, the first gate power supply line 32a connected to the gate power supply (1) is connected to the amplifier 10a of the first amplifier unit 10-1, and the second gate power supply line 32b is connected to the third amplifier. Connected to the amplifier 10a of the unit 10-3. Thus, the signal amplifying apparatus 1A shares the gate power supply (1) between the amplifier 10a of the first amplifier unit 10-1 and the amplifier 10a of the third amplifier unit 10-3. Further, the signal amplifying apparatus 1A connects the first gate power supply line 32a connected to the gate power supply (2) to the amplifier 10b of the first amplifier unit 10-1, and the second gate power supply line 32b to the second power supply. To the amplifier 10b of the amplifier unit 10-2. As a result, the signal amplifying apparatus 1A shares the gate power supply (2) between the amplifier 10b of the first amplifier unit 10-1 and the amplifier 10b of the second amplifier unit 10-2. Furthermore, the signal amplifying apparatus 1A connects the first gate power supply line 32a connected to the gate power supply (3) to the amplifier 10a of the second amplifier unit 10-2, and connects the second gate power supply line 32b to the third power supply. To the amplifier 10b of the amplifier unit 10-3. Accordingly, the signal amplifying apparatus 1A shares the gate power supply (3) between the amplifier 10a of the second amplifier unit 10-2 and the amplifier 10b of the third amplifier unit 10-3.

  According to this signal amplifying apparatus 1A, the signals flowing in the feedback loop including the amplifier 10a of the first amplifier unit 10-1 and the amplifier 10a of the third amplifier unit 10-3 are transmitted by the attenuating units 40-1 and 40-2. Can be attenuated. Further, according to the signal amplifying apparatus 1A, the signal flowing through the feedback loop including the amplifier 10b of the first amplifier unit 10-1 and the amplifier 10b of the second amplifier unit 10-2 is attenuated by the attenuation unit 40-1. Can do. Furthermore, according to the signal amplifying apparatus 1A, the signal flowing in the feedback loop including the amplifier 10a of the first amplifier unit 10-1 and the amplifier 10b of the third amplifier unit 10-3 is attenuated by the attenuation unit 40-2. Can do. Therefore, according to the signal amplifying device 1A, similarly to the signal amplifying device 1 described above, it is possible to suppress the fluctuation of the high-frequency signal supplied to the amplifier unit, and to operate the amplifier unit more stably. Can be made.

  In the configuration in which three amplifier units 10-1, 10-2, and 10-3 shown in FIG. 5 are connected in series, the first gate connected to the gate power supplies (1), (2), and (3) The power supply line 32a and the second gate power supply line 32b may be changed as shown in FIG. FIG. 6 is a configuration diagram of a signal amplifying device 1Aa according to a modification of the signal amplifying device 1A. The signal amplifying apparatus 1Aa connects the gate power supply (1) to the amplifier 10a of the first amplifier unit 10-1 and the amplifier 10b of the third amplifier unit 10-3, and the first amplifier unit 10-1 The gate power supply (1) is shared with the third amplifier unit 10-3. The signal amplifying apparatus 1Aa connects the gate power supply (2) and the amplifier 10b of the first amplifier unit 10-1 and the amplifier 10a of the second amplifier unit 10-2 to connect the first amplifier unit 10-1 with the first amplifier unit 10-1. The gate power supply (2) is shared with the second amplifier unit 10-2. The signal amplifying apparatus 1Aa connects the gate power supply (3) to the amplifier 10b of the second amplifier unit 10-2 and the amplifier 10a of the third amplifier unit 10-3, and The gate power supply (3) is shared with the third amplifier unit 10-3.

  FIG. 7 is a configuration diagram of a signal amplifying device 1B according to another embodiment. The signal amplifying apparatus 1B according to the modified example shares the drain power supplies (1) and (2) between the amplifier of the first amplifier unit 10-1 and the amplifier of the second amplifier unit 10-2.

  The signal amplifying apparatus 1B connects the first drain power supply line 22a branched from the drain power supply terminal 20a connected to the drain power supply (1) to the amplifier 10a of the first amplifier unit 10-1. Further, the signal amplifying apparatus 1B connects the second drain power supply line 22b branched from the drain power supply terminal 20a connected to the drain power supply (1) to the amplifier 10a of the second amplifier unit 10-2. Accordingly, the signal amplifying apparatus 1A can attenuate the signal flowing in the feedback loop including the amplifier 10a of the first amplifier unit 10-1 and the amplifier 10a of the second amplifier unit 10-2 by the attenuation unit 40.

  The signal amplifying apparatus 1B connects the first drain power supply line 22a branched from the drain power supply terminal 20a connected to the drain power supply (2) to the amplifier 10b of the first amplifier unit 10-1. The signal amplifying apparatus 1A connects the second drain power supply line 22b branched from the drain power supply terminal 20a connected to the drain power supply (2) to the amplifier 10b of the second amplifier unit 10-2. Accordingly, the signal amplifying apparatus 1A can attenuate the signal flowing in the feedback loop including the amplifier 10b of the first amplifier unit 10-1 and the amplifier 10b of the second amplifier unit 10-2 by the attenuation unit 40.

  According to this signal amplifying apparatus 1B, the effects of the above-described embodiment can be obtained, and the high-frequency signal amplified by the first amplifier unit 10-1 and the second amplifier unit 10-2 can be converted into the first drain power supply line 22a. Even when a feedback loop is formed by flowing through the second drain power supply line 22b, the signal fed back to the drain of the amplifier is suppressed by the attenuator 40, and the high-frequency signal output from the amplifier is prevented from fluctuating. And the amplifier can be operated more stably.

  According to at least one embodiment described above, two or more amplifiers 10a and 10b connected in series, and a plurality of first amplifier units 10-1 and second amplifier units 10 connected in series with each other. -2 and an attenuator 40 provided between the first amplifier unit 10-1 and the second amplifier unit 10-2, and at least of the amplifiers included in the first amplifier unit 10-1 Since the gate power supply is shared between one amplifier and at least one of the amplifiers included in the second amplifier unit 10-2, the signal fed back to the amplifiers 10a and 10b is attenuated by the attenuation unit 40. Can be made. As a result, according to the signal amplifying apparatus 1 of the embodiment, the fluctuation of the gate bias voltage supplied to the amplifiers 10a and 10b can be suppressed, and the amplifier unit can be operated more stably.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 1, 1A ... Signal amplifier, 10-1 ... 1st amplifier unit, 10-2 ... 2nd amplifier unit, 10a ... Amplifier, 10b ... Amplifier, 20-1 ... 1st drain power supply connection part, 20- 2 ... 2nd drain power supply connection part, 20a ... Drain power supply terminal, 22a ... 1st drain power supply line, 22b ... 2nd drain power supply line, 30-1 ... 1st gate power supply connection part, 30-2 ... 2nd gate power supply connection part, 30a ... gate power supply terminal, 32a ... 1st gate power supply line, 32b ... 2nd gate power supply line, 40 ... attenuation part, 42 ... 1st resistance, 44 ... 2nd resistance 46 ... third resistor, 400 ... resistor

Claims (6)

A first amplifier unit including a first amplifier and a second amplifier connected in series, wherein the first amplifier and the second amplifier are connected to a common first drain power supply;
A second amplifier unit comprising a third amplifier and a fourth amplifier connected in series, wherein the third amplifier and the fourth amplifier are connected to a common second drain power supply;
An attenuator connected between the first amplifier unit and the second amplifier unit;
A first gate power supply is shared between the first amplifier and the third amplifier, and a second gate power supply is shared between the second amplifier and the fourth amplifier. And
The same gate bias voltage is applied to the first amplifier and the third amplifier,
The same gate bias voltage is applied to the second amplifier and the fourth amplifier,
The same drain bias voltage is applied to the first amplifier and the second amplifier,
The same drain bias voltage is applied to the third amplifier and the fourth amplifier.
Signal amplification device. The first amplifier unit seals the first amplifier and the second amplifier in a first package;
The second amplifier unit seals the third amplifier and the fourth amplifier in a second package.
The signal amplification device according to claim 1. The first amplifier, the second amplifier, the attenuator, the third amplifier, and the fourth amplifier are connected in series in this order.
The signal amplification device according to claim 1 or 2. A plurality of amplifier units connected in series;
An attenuator connected between each of the plurality of amplifier units,
Each of the plurality of amplifier units includes first and second amplifiers connected in series, and in each of the plurality of amplifier units, the first amplifier is disposed on one end side of the signal amplifying device. Is provided on the other end side of the signal amplification device,
The first amplifier in each of the plurality of amplifier units has a common gate power supply with the second amplifier of the other amplifier units,
The same gate bias voltage is applied to a set of amplifiers that share the gate power supply,
The same drain bias voltage is applied to the first amplifier and the second amplifier.
Signal amplification device. The attenuation unit includes an attenuator that attenuates a signal level to a predetermined level.
The signal amplifying device according to claim 1. The attenuation unit includes a resistor,
The signal amplifying device according to claim 1.

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