JP2008028908A - Gain variable low-noise amplifier - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To keep a noise index satisfactorily and to perform gain variations in multi-stage steps without deteriorating an input third-order intercept point and input power in 1dB gain compression. <P>SOLUTION: On the post-stage of an amplifier circuit 101, a variable attenuation circuit 104 is provided in series. Between the stages of the amplifier circuit 101 and the variable attenuation circuit 104, on the other hand, a first matching circuit 8 is provided and between the stage of these first matching circuit 8 and the variable attenuation circuit 104 and a drain voltage terminal 3 to which a power supply voltage from the outside is applied, a second matching circuit 9 is provided, and the first matching circuit 8 and the second matching circuit 9 are configured to make conjugate output impedance of the amplifier circuit 101 and input impedance of the variable attenuation circuit 104 and to attain matching. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a variable gain low-noise amplifier used in various mobile radio communication devices typified by portable radio terminals, and more particularly to an improvement in noise figure as well as characteristics improvement at the time of large signal input. .

  In recent mobile communications, since the electric field strength of a received signal varies greatly depending on the distance between a base station and a mobile station, a wide dynamic range is required for the receiver. For this reason, the receiver amplifier is required to have a variable gain function as well as a high gain characteristic and a low noise characteristic. However, since it is necessary to suppress the fluctuation of the received signal level with high accuracy, the variable gain of the fixed variable system is required. A circuit is preferred. In addition, when HSDPA (High Speed Downlink Packet Access) technology for increasing the data communication speed is introduced, the gain variable step is changed to, for example, three stages, four stages, etc. in order to vary the modulation method according to the electric field strength of the received signal. An amplifier that can be varied may be desired.

As an example of the variable gain amplifier in which such variable gain is performed in multiple steps and the variable gain in each step is fixed, there is one disclosed in Patent Document 1, for example.
FIG. 5 shows an example of a circuit configuration of such a conventional variable gain amplifier. Hereinafter, such a conventional circuit will be generally described with reference to FIG.
In this variable gain amplifier, an amplifier circuit is configured with a signal amplification field effect transistor (hereinafter referred to as “FET”) 65 as a center, and path switching SPDT switches 62 and 63 are used on the input side for attenuation. An element 64 is provided between the input terminal 61 and the signal amplification FET 65 so as to be selectively insertable. Bias resistors 71 to 74 and bias switches 75 to 78 provided corresponding to the bias resistors 71 to 74 are connected in series between the source of the signal amplification FET 65 and the ground. At the same time, the series parts of the bias resistors 71 to 74 and the bias switches 75 to 78 are provided in parallel with each other.

In such a configuration, by operating the path switching SPDT switches 62 and 63, the input signal is applied to the gate of the signal amplifying FET 65 without being attenuated by the attenuating element 64. Thus, it is possible to select whether the input signal is applied to the gate of the signal amplification FET 65.
Further, by switching on / off of the bypass switches 75 to 78, the amplification gain can be varied in four stages according to the size of the bias resistors 71 to 74.
Therefore, in this variable gain amplifier, gain control in eight stages as a whole is possible by a combination of the presence / absence of insertion of the attenuation element 64 on the input side and the on / off switching of the bypass switches 75-78. .

JP-A-5-315871 (page 2-3, FIGS. 1 to 4)

By the way, in the above-described conventional circuit, since the path switching SPDT switches 62 and 63 are provided in series in two stages via the attenuation element 64 on the input side, the insertion loss corresponding to the two SPDT switches is reduced. And added to the noise figure (hereinafter referred to as “NF”) of the variable gain amplifier. In addition, since the gain is adjusted by varying the current of the amplifier, in a variable gain state where the current decreases, NF, an input third-order intercept point (hereinafter referred to as “IIP3”), and an input at 1 dB gain compression. There is a problem in that characteristics such as power (hereinafter referred to as “P1 dB”) are deteriorated.
The present invention has been made in view of the above circumstances, has a good noise figure, and enables variable gain in multiple steps without deteriorating the input third-order intercept point and 1 dB gain input power during compression. A variable gain low noise amplifier is provided.

In order to achieve the above object of the present invention, a variable gain low noise amplifier according to the present invention comprises:
An amplifying circuit, a bypass circuit connected in parallel between the input and output of the amplifying circuit and diverting a signal input to the amplifying circuit to the output side of the amplifier according to a control signal; and a signal output from the amplifying circuit A variable gain low noise amplifier comprising a variable attenuating circuit for attenuating with respect to
The variable attenuation circuit is provided in series in the subsequent stage of the amplifier circuit, and a first matching circuit is provided between the stage of the amplifier circuit and the variable attenuation circuit, and the first matching circuit and A second matching circuit is provided between the stage with the variable attenuation circuit and a power supply terminal to which an external power supply voltage is applied;
The first matching circuit and the second matching circuit are configured to conjugate and match the output impedance of the amplifier circuit and the input impedance of the variable attenuation circuit.
In such a configuration, the variable attenuating circuit is preferably configured to use a T-type fixed attenuator and to be configured such that the T-type fixed attenuator can be bypassed by a path switching SPDT switch.

  According to the present invention, the variable attenuation circuit is provided in series in the subsequent stage of the amplifier circuit, and the output impedance of the amplifier circuit and the input impedance of the variable attenuation circuit are conjugated. The index is not added to the noise figure of the entire variable gain low noise amplifier. Therefore, it has a good noise figure, and the input third-order intercept point when the gain is variable and the input power when the gain is compressed are 1 dB. It is possible to provide a variable gain low noise amplifier in which deterioration is suppressed.

Hereinafter, embodiments of the present invention will be described with reference to FIGS. 1 to 4.
The members and arrangements described below do not limit the present invention and can be variously modified within the scope of the gist of the present invention.
First, a first configuration example of the variable gain low noise amplifier according to the embodiment of the present invention will be described with reference to FIG.
This variable gain type low noise amplifier includes an amplifier circuit 101 mainly composed of signal amplification field effect transistors (hereinafter referred to as “FETs”) 20 and 21, and supply of a bias to the amplifier circuit 101. A bias circuit 102 that controls the signal, a bypass circuit 103 that bypasses the amplifier circuit 101 between the signal input terminal 1 and the signal output terminal 2, a variable attenuation circuit 104 that is provided at the subsequent stage of the amplifier circuit 101, The second circuit control logic circuit (referred to as “CONT-1” and “CONT-2” in FIG. 1) 10 and 11 is the main component.

The amplifying circuit 101 is configured around stack connection by the first and second signal amplifying FETs 20 and 21.
That is, in the first and second signal amplification FETs 20 and 21, the drain of the first signal amplification FET 20 and the source of the second signal amplification FET 21 are connected to each other, while the first signal amplification FET 20 Are connected to the signal input terminal 1 via the coupling capacitor 44 and the input matching circuit 7. The gate of the first signal amplification FET 20 is connected to the gate of the bias circuit FET 19 constituting the bias circuit 102 via the bias connection resistor 29.
Further, a connection point between the coupling capacitor 44 and the input matching circuit 7 is connected to the source of the bypass circuit FET 22 via a coupling capacitor 46 which is one of components constituting a bypass circuit 103 described later.

  On the other hand, the source of the first signal amplification FET 20 is connected to the ground through the source inductor 51, while the drain of the second signal amplification FET 21 is connected through the first output matching circuit 8 and the capacitor 48. In addition to being connected to an input stage of a variable attenuation circuit 104 described later, it is connected to a bypass circuit 103 described later. Specifically, one end of the capacitor 48 (on the side opposite to the connection end with the first output matching circuit 8) is connected to one end of the input side resistor 37 constituting the variable attenuation circuit 104 as will be described later. ing.

The connection point between the first output matching circuit 8 and the capacitor 48 is connected to the drain voltage terminal 3 via the second output matching circuit 9. A bypass capacitor 50 is connected between the drain voltage terminal 3 and the ground. A predetermined power supply voltage is applied to the drain voltage terminal 3 from the outside.
Further, the drain of the second signal amplifying FET 21 is connected to the drain of the bypass circuit FET 22 via a coupling capacitor 47 which is one component constituting the bypass circuit 103.
The gate of the second signal amplifying FET 21 is connected to the ground via the capacitor 45 and also connected to the first output terminal OUT-1 of the first circuit control logic circuit 10 via the resistor 33. It is connected.

Further, the amplifier circuit 101 is provided with an amplifier OFF FET 23, and its drain is connected to a connection point between the drain of the first signal amplification FET 20 and the source of the second signal amplification FET 21. The source is connected to the ground.
The gate of the amplifier OFF FET 23 is connected to the second output terminal OUT-2 of the first circuit control logic circuit 10 via the resistor 34.

  The bias circuit 102 is configured with a bias circuit FET 19 as the center, and the bias circuit FET 19 is connected to its drain and gate to form a so-called diode-connected state. While being connected to the first output terminal OUT-1 of the first circuit control logic circuit 10 via the device 28, the source is connected to the ground. The gate of the bias circuit FET 19 is connected to the gate of the first signal amplification FET 20 via the bias connection resistor 29 as described above.

The bypass circuit 103 is configured around the bypass circuit FET 22. The drain of the bypass circuit FET 22 is controlled via the resistor 32, and the source is controlled via the resistor 30. The first logic circuit 10 is connected to the first output terminal OUT-1.
Further, as described above, the drain of the bypass circuit FET 22 is connected to the drain of the second signal amplification FET 21 via the coupling capacitor 47, while the source is input matched via the coupling capacitor 46. The circuit 7 and the coupling capacitor 44 are connected to a mutual connection point.
The gate of the bypass circuit FET 22 is connected to the second output terminal OUT-2 of the first circuit control logic circuit 10 via the resistor 31.

The variable attenuation circuit 104 is configured by a T-type bridge variable attenuation circuit with the shunt FET 24, the pass FET 25, the input side resistor 37, and the output side resistor 38 as main components.
Specifically, first, the input side resistor 37 and the output side resistor 38 are connected in series, and the other end of the input side resistor 37 is connected to the capacitor 48 as described above, while the output side resistor 37 The other end of the side resistor 38 is connected to the signal output terminal 2 via a coupling capacitor 49.

The drain of the shunt FET 24 is connected to the connection point between the input-side resistor 37 and the output-side resistor 38, and is connected to the source via the resistor 39, while the source is connected to the ground. .
The gate of the shunt FET 24 is connected to the second output terminal OUT-2 of the second circuit control logic circuit 11 via the resistor 40.

On the other hand, the drain of the pass FET 25 is connected to the connection point between the capacitor 48 and the input side resistor 37, while the source is connected to the connection point between the output side resistor 38 and the coupling capacitor 49.
The gate of the pass FET 25 is connected to the first output terminal OUT-1 of the second circuit control logic circuit 11 via the resistor 36.

The first circuit control logic circuit 10 outputs a signal for controlling the operations of the amplifier circuit 101, the bias circuit 102, and the bypass circuit 103, as will be described later, in accordance with a voltage applied to the first switching voltage terminal 5 from the outside. It is configured to do.
Further, the second circuit control logic circuit 11 is configured to output a signal for controlling the operation of the variable attenuation circuit 104 as will be described later in accordance with a voltage applied from the outside to the second switching voltage terminal 6. It has become a thing.
The first circuit control logic circuit 10 is connected to the second output matching circuit 9 via the resistor 35, and the second circuit control logic circuit 11 is connected to the second output matching circuit 9 via the resistor 41. The drain voltage terminal 3 is supplied with power from the outside via the second output matching circuit 9.

Next, the operation in this configuration will be described.
First, the output impedance of the amplifier circuit 101 is matched by the first and second output matching circuits 8 and 9, but when the output impedance is not 50Ω, the constants of the elements of the variable attenuation circuit 104 are adjusted. By doing so, it is preferable that the input impedance of the variable attenuation circuit 104 is configured to be conjugate with the output impedance of the amplifier circuit 101.
Normally, the input side resistor 37 and the output side resistor 38 of the variable attenuation circuit 104 are both set to 50Ω, but the value of the input side resistor 37 is set according to the output impedance of the amplifier circuit 101.

  Thereby, even when the output impedance of the amplifier circuit 101 does not become 50Ω, the input impedance of the variable attenuation circuit 104 becomes conjugate with the output impedance of the amplifier circuit 101. The mismatched state does not occur, and the impedance viewed from the signal output terminal 2 is matched to 50Ω. Therefore, no mismatch occurs between the stages of the amplifier circuit 101 and the variable attenuation circuit 104 (see the line AA in FIG. 1).

In the variable attenuation circuit 104, when the control voltage is changed linearly, the attenuation amount also changes almost linearly. However, in order to make the variable gain fixed, the control voltage is fixed by the second circuit control logic circuit 11. The voltage is controlled.
Under such a premise, the variable gain operation of the variable gain low noise amplifier according to the embodiment of the present invention will be described with reference to FIG.
In the variable gain low noise amplifier according to the embodiment of the present invention, as described below, the gain is set to “High Gain” by combining the outputs of the first and second circuit control logic circuits 10 and 11. It can be varied in four levels: “State (maximum gain state)”, “Medium Gain State”, “Low Gain State” and “Very Low Gain State” (See FIG. 4).

First, in order to set the gain to the high gain state, a voltage corresponding to the logical value High from the first output terminal OUT-1 of the first circuit control logic circuit 10 is supplied from the second output terminal OUT-2. A predetermined voltage is applied to the first switching voltage terminal 5 so that voltages corresponding to the logical value Low are output.
Similarly, the second circuit control logic circuit 11 has a voltage corresponding to the logical value High from the first output terminal OUT-1 and a voltage corresponding to the logical value Low from the second output terminal OUT-2. , A predetermined voltage is applied to the second switching voltage terminal 6 so as to be output.

As a result, the voltage corresponding to the logical value High from the first output terminal OUT-1 of the first circuit control logic circuit 10 is supplied to the bias circuit FET 19 that is diode-connected via the resistor 28. Therefore, a desired gate voltage is applied to the first signal amplification FET 20.
Here, the voltage corresponding to the logical value High output from the first circuit control logic circuit 10 is set sufficiently larger than the pinch-off voltage of the FET, and such High voltage is used for the first signal amplification. Since it is applied to the gate of the FET 20, the operating current of the amplifier circuit 101 is determined by the gate voltage of the first signal amplifying FET 20, and the amplifier circuit 101 enters a desired operating state.

  In addition, a voltage corresponding to the logic value Low output from the second output terminal OUT-2 of the first circuit control logic circuit 10 is applied to the gate of the bypass circuit FET 22 and also the amplifier OFF FET 23. Since the voltage is applied to the gate, the bypass circuit 103 becomes inoperative. At this time, the amplifier OFF FET 23 becomes OPEN (non-conducting state), and thus does not affect the bias setting and operation of the amplifier circuit 101.

  On the other hand, a voltage corresponding to the logical value High output from the first output terminal OUT-1 of the second circuit control logic circuit 11 is applied to the gate of the pass FET 25 of the variable attenuation circuit 104, and 2 is applied to the gate of the shunt FET 24 of the variable attenuating circuit 104, so that the variable attenuating circuit 104 forms a passage path by the pass FET 25. It will be in a state to be.

  Therefore, the gain of the entire circuit is a value obtained by subtracting the minimum attenuation amount of the variable attenuation circuit 104 from the gain of the amplifier circuit 101, that is, the pass loss of the pass FET 25, in other words, NF (noise figure), IIP3 (input As for the third-order intercept point) and P1 dB (input power at the time of 1 dB gain compression), substantially the same value as the original value of the amplifier circuit 101 is obtained.

In such an operating state, the bypass circuit 103 in the non-operating state becomes a kind of feedback circuit, which affects the gain and NF, but is different from a configuration in which an SPDT switch is provided on the input side of the amplifier circuit 101 as in the conventional example. Thus, the degree of influence on NF is surely small.
Note that adding a feedback circuit to the amplifier circuit 101 is a means for improving distortion characteristics and straight lines, and thus does not adversely affect large signal characteristics.

  Next, in order to change the gain from the high gain state to the medium gain state, the first and second output terminals OUT-1 and OUT-2 of the first circuit control logic circuit 10 are connected to the above-mentioned high gain state. While the same output state as in the gain state is set, the second circuit control logic circuit 11 has a voltage corresponding to the logic value Low from the first output terminal OUT-1 to the second output terminal OUT-. The voltage corresponding to the logical value High from 2 is output (see FIG. 4).

As a result, since the bypass circuit 103, the bias circuit 102, and the amplifier OFF FET 23 are set to the same bias condition as in the previous High Gain State, the amplifier circuit 101 is in an operating state, and the bypass circuit 103 and the amplifier OFF FET 23 are set. Is in a non-operating state.
The voltage corresponding to the logic value Low output from the first output terminal OUT-1 of the second circuit control logic circuit 11 is applied to the gate of the pass FET 25 of the variable attenuation circuit 104, while the first Since the voltage corresponding to the logical value High output from the second output terminal OUT-2 of the second circuit control logic circuit 11 is applied to the gate of the shunt FET 24 of the variable attenuation circuit 104, the variable attenuation circuit 104 Therefore, an attenuation path is formed by the input side resistor 37 and the output side resistor 38 and the shunt FET 24.

Therefore, the gain of the entire circuit is the maximum attenuation of the variable attenuating circuit 104 from the gain of the amplifier circuit 101, that is, the T-type attenuator formed by the input-side resistor 37, the output-side resistor 38, and the shunt FET 24. The value obtained by subtracting the attenuation.
The NF (Ftotal) of the entire circuit becomes a loss by the variable attenuating circuit 104 at the subsequent stage of the amplifier circuit 101 and can be expressed as follows.

  Ftotal = F1 + (F2-1) / G1

  Here, F1 is the noise figure of the amplifier circuit 101, F2 is the noise figure of the variable attenuation circuit 104, and G1 is the gain of the amplifier circuit 101.

From this equation, it can be understood that increasing the amount of attenuation of the variable attenuation circuit 104 does not significantly affect the NF of the entire circuit.
On the other hand, when an attenuator is provided in the previous stage of the amplifier circuit 101 as in the prior art, the attenuation amount is added to NF as it is, so that the NF in the variable gain low noise amplifier according to the above-described embodiment of the present invention. The difference is obvious compared to.
With respect to IIP3 and P1dB, the large signal characteristic of the variable attenuation circuit 104 is superior to that of the amplifier circuit 101. Therefore, IIP3 and P1dB of the entire circuit are determined by the original characteristics of the amplifier circuit 101.

  Next, in order to change from the medium gain state to the low gain state in which the gain is reduced by one step, the voltage corresponding to the logic value Low is applied from the first output terminal OUT-1 of the first circuit control logic circuit 10 to the second value. The voltage corresponding to the logical value High is output from the output terminal OUT-2. The second circuit control logic circuit 11 outputs a voltage corresponding to the logical value High from the first output terminal OUT-1 and outputs a voltage corresponding to the logical value Low from the second output terminal OUT-2. (See FIG. 4).

  In this case, a voltage corresponding to the logic value Low output from the first output terminal OUT-1 of the first circuit control logic circuit 10 is applied as a power supply voltage to the bias circuit FET 19 via the resistor 28. Therefore, the supply of the power supply voltage to the bias circuit 102 is cut off, the gate of the first signal amplification FET 20 is in a zero bias state, and the amplifier circuit 101 is in an inoperative state.

On the other hand, the voltage corresponding to the logical value High output from the second output terminal OUT-2 of the first circuit control logic circuit 10 is the gate of the bypass circuit FET 22 of the bypass circuit 103 and the gate of the amplifier OFF FET 23. Is applied to the bypass circuit 103, and the amplifier OFF FET 23 is turned on.
For this reason, since the drain of the first signal amplification FET 20 is forcibly grounded by the amplifier OFF 23, the gate potential of the first signal amplification FET 20 is prevented from being raised by the input signal of the strong electric field. The Rukoto.

Since the bias condition of the variable attenuation circuit 104 is the same as that in the case of the above-described High Gain State (see FIG. 4), the variable attenuation circuit 104 is in a state in which a passage path is formed by the pass FET 25.
Accordingly, the gain of the entire circuit is the sum of the passage loss of the bypass circuit FET 22 and the minimum attenuation amount of the variable attenuation circuit 104 (pass loss of the pass FET 25). IIP3 and P1dB are determined by the bypass circuit FET 22, but are higher than IIP3 and P1dB when the amplifier circuit 101 is in operation.

Finally, in order to change to the Very Low Gain State in which the gain is reduced by one step from the Low Gain State, a voltage corresponding to the logical value Low is applied from the first output terminal OUT-1 of the first circuit control logic circuit 10 to the first gain. The voltage corresponding to the logical value High is output from each output terminal OUT-2 (see FIG. 4).
The second circuit control logic circuit 11 outputs a voltage corresponding to the logical value Low from the first output terminal OUT-1 and outputs a voltage corresponding to the logical value High from the second output terminal OUT-2. (See FIG. 4).

In this case, the amplifier circuit 101, the bias circuit 102, the bypass circuit 103, and the amplifier OFF FET 23 are set to the same bias condition as in the case of the Low Gain State described above. The bypass circuit 103 and the amplifier OFF FET 23 are in an operating state.
Further, since the bias condition of the variable attenuation circuit 104 is the same as that of the Medium Gain State described above, the variable attenuation circuit 104 includes an attenuation path formed by the input side resistor 37, the output side resistor 38, and the shunt FET 24. Is formed.

  Therefore, the gain of the entire circuit is the transmission loss of the bypass circuit FET 22 and the maximum attenuation of the variable attenuation circuit 104, that is, the T-type attenuator formed by the input-side resistor 37, the output-side resistor 38, and the shunt FET 24. Is the sum of the amount of attenuation.

Further, since IIP3 and P1dB are determined by a T-type attenuator composed of the ON resistance of the input-side resistor 37 and output-side resistor 38 and the shunt FET 24, the values are higher than IIP3 and P1dB when the amplifier circuit 101 is operated. Become.
As described above, in the first configuration example, the NF and the gain at the maximum gain have the low noise characteristic and the high gain characteristic that the amplifier circuit 101 itself has, while having four gain variable steps. In any gain variable state, a variable gain low noise amplifier excellent in large signal characteristics such as IIP3 and P1 dB is realized.

Next, a second configuration example according to the embodiment of the present invention will be described with reference to FIG. The same components as those in the configuration example shown in FIG. 1 are denoted by the same reference numerals, detailed description thereof will be omitted, and different points will be described below.
This second configuration example is different from the first configuration example in that the amplifier circuit 101A is configured by a single gate FET.
That is, the amplifier circuit 101A is configured such that the second signal amplification FET 21 in FIG. 1 is deleted and the first signal amplification FET 20 performs an amplification operation.

The difference in circuit configuration from the case of FIG. 1 is that the source of the first signal amplification FET 20 and the drain of the amplifier OFF FET 23 are connected via a source inductor 51.
The gate of the amplifier OFF FET 23 is connected to the resistor 33, and is connected to the first output terminal OUT-1 of the first circuit control logic circuit 10 via the resistor 33. Yes.

Since the operation of the entire circuit is basically the same as that of the first configuration example shown in FIG. 1, detailed description of the operation will be omitted here.
In the second configuration example, although the gain of the amplifier circuit 101A is lower than that of the first configuration example of the stack configuration, the gain is superior to P1 dB. Therefore, depending on the target characteristics at the maximum gain, the amplification circuit 101A may be more effective than the first configuration example. May also be preferred.

Next, a third configuration example in the embodiment of the present invention will be described with reference to FIG. The same components as those in the configuration example shown in FIG. 1 are denoted by the same reference numerals, detailed description thereof will be omitted, and different points will be described below.
The third configuration example is different from the first configuration example in that the variable attenuation circuit 104A includes two SPDT (Single Pole Double Throw) switches 105 and 106 and a fixed attenuator 107. is there.
Specifically, first, the first SPDT switch (denoted as “SPDT1” in FIG. 3) 105 is configured with the first switch first and second FETs 24A and 25A as main components. It has been made. That is, the first switch first FET 24 </ b> A and the first switch second FET 25 </ b> A are connected to the capacitor 48 as well as to the drain (or source).

The gate of the first switch first FET 24A is connected to the first output terminal OUT-1 of the second circuit control logic circuit 11 via the resistor 36A and the gate of the first switch second FET 25A. Are connected to the second output terminal OUT-2 of the second circuit control logic circuit 11 through the resistor 41, respectively.
The source (or drain) of the first FET for first switch 24A is connected to the drain (or source) of the first FET for second switch 26 constituting the second SPDT switch 106 described later. Between the first FET for the first switch 24A and the first FET for the second switch 26, a path through which the first SPDT switch 105 and the second SPDT switch 106 are directly connected without any other element (see FIG. 3) (hereinafter referred to as “route 1”).
On the other hand, the source (or drain) of the second FET 25A for the first switch is connected to one end of a resistor 38A constituting the fixed attenuator 107 described later.

  On the other hand, the second SPDT switch 106 is configured with the second switch FETs 26 and 27 as main components. In other words, the first FET for second switch 26 and the second FET for second switch 27 are connected to each other at the source (or drain) and to the coupling capacitor 49.

The gate of the second switch first FET 26 is connected to the first output terminal OUT-1 of the second circuit control logic circuit 11 via the resistor 37A. Are connected to the second output terminal OUT-2 of the second circuit control logic circuit 11 through the resistor 42, respectively.
Furthermore, the drain (or source) of the second FET 27 for the second switch is connected to one end of a resistor 39A constituting the fixed attenuator 107 described below.

In the fixed attenuator 107, a T-type attenuator is constituted by three resistors 38A, 39A, and 40A.
That is, each of the resistors 38A, 39A, and 40A is connected to each other. On the other hand, as described above, the other end of the resistor 38A is connected to the source of the first switch first FET 25A, and the other end of the resistor 39A is the drain (or source) of the second switch FET 27. Furthermore, the other end of the resistor 40A is connected to the ground.
The fixed attenuator 107 having such a configuration is a second path (hereinafter referred to as “path 2”) that connects the first SPDT switch 105 and the second SPDT switch 106 (see FIG. 3). .

Next, the operation in this configuration will be described with reference to FIGS.
First, in order to set the gain to the high gain state, a voltage corresponding to the logical value High is applied to the first output terminal OUT-1 of the first circuit control logic circuit 10 to the second output terminal OUT-2. While the voltage corresponding to the logic value Low is output, the second circuit control logic circuit 11 similarly applies the voltage corresponding to the logic value High to the first output terminal OUT-1 to the second output terminal. A voltage corresponding to the logical value Low is output to OUT-2 (see FIG. 4).

In this case, the amplifier circuit 101 is in an operating state while the bypass circuit 103 is in a non-operating state. In the variable attenuation circuit 104A, a path 1 is formed in which the first switch first FET 24A and the second switch first FET 26 in the ON state are directly connected. In other words, the fixed attenuator 107 is bypassed.
Therefore, the gain of the entire circuit is obtained by subtracting the minimum attenuation amount of the variable attenuation circuit 104A from the gain of the amplifier circuit 101A, that is, the passage loss of the first FET for first switch 24A and the first FET for second switch. Subtracted values are obtained, and NF, IIP3, and P1 dB are almost equal to the original values of the amplifier circuit 101.

  Next, in order to change the gain from the high gain state to the medium gain state, the first and second output terminals OUT-1 and OUT-2 of the first circuit control logic circuit 10 are connected to the above-mentioned high gain state. While the same output state as in the gain state is set, the second circuit control logic circuit 11 has a voltage corresponding to the logic value Low from the first output terminal OUT-1 to the second output terminal OUT-. The voltage corresponding to the logical value High from 2 is output (see FIG. 4).

In this case, the amplifier circuit 101 is in an operating state, and the bypass circuit 103 is in a non-operating state. In the variable attenuation circuit 104A, the path 2 is turned on, and an attenuation path including the resistors 38A, 39A, and 40A is formed.
Therefore, the gain of the entire circuit is a value obtained by subtracting the maximum attenuation amount of the variable attenuation circuit 104A, that is, the attenuation amount of the T-type attenuator by the resistors 38A, 39A, and 40A from the gain of the amplifier circuit 101 main body.

  Further, the NF (Ftotal) of the entire circuit is such that a T-type attenuator is formed by resistors 38A, 39A, and 40A in the subsequent stage of the amplifier circuit 101. Therefore, as in the first configuration example, the gain and NF Even if the attenuation amount of the variable attenuation circuit 104A is set large, the influence on the NF of the entire circuit is small.

  Next, in order to change from the medium gain state to the low gain state in which the gain is reduced by one step, the voltage corresponding to the logic value Low is applied from the first output terminal OUT-1 of the first circuit control logic circuit 10 to the second value. The voltage corresponding to the logical value High is output from the output terminal OUT-2. Second, a voltage corresponding to the logical value High is output from the first output terminal OUT-1 of the circuit control logic circuit 11, and a voltage corresponding to the logical value Low is output from the second output terminal OUT-2. (See FIG. 4).

  In this case, the amplifier circuit 101 is in the non-operating state, the bypass circuit 103 is in the operating state, and the variable attenuation circuit 104A is in the path 1 ON state, that is, the first switch first FET 24A and the second switch first switch. A passage path is formed by the ON state of the FET 26. Accordingly, the gain of the entire circuit is the sum of the passage loss of the bypass circuit FET 22 and the minimum attenuation amount of the variable attenuation circuit 104A (the passage loss of the first FET for the first switch 24A and the first FET for the second switch 26). It becomes. IIP3 and P1dB are determined by the bypass circuit FET 22, but are higher than IIP3 and P1dB of the amplifier circuit 101.

Finally, in order to change to the Very Low Gain State in which the gain is reduced by one step from the Low Gain State, a voltage corresponding to the logical value Low is applied from the first output terminal OUT-1 of the first circuit control logic circuit 10 to the first gain. The voltage corresponding to the logical value High is output from each output terminal OUT-2 (see FIG. 4).
In this case, the amplifier circuit 101 is in the non-operating state, the bypass circuit 103 is in the operating state, and the variable attenuating circuit 104A is formed with a T-type attenuator passing path composed of the resistors 38A, 39A, and 40A. .

Therefore, the gain of the entire circuit is the sum of the passage loss of the bypass circuit FET 22 and the maximum attenuation of the variable attenuation circuit 104A, that is, the attenuation of the T-type attenuator by the resistors 38A, 39A, and 40A.
Since IIP3 and P1dB are determined by the T-type attenuator including the resistors 38A, 39A, and 40A, the values are higher than IIP3 and P1dB of the amplifier circuit 101.

  As described above, the operation in the third configuration example is the same as that in the first configuration example. Note that, from the viewpoint of facilitating understanding, in the third configuration example, similarly to the first configuration example, the gain variable step is an example of four stages, but an SPnT switch is used instead of the SPDT switch. Correspondingly, a variable gain low-noise amplifier having 2 × n variable gain steps can be easily realized by providing a configuration in which n−1 fixed attenuators having different attenuation amounts are provided. Can do.

1 is a circuit diagram illustrating a first configuration example of a variable gain low noise amplifier according to an embodiment of the present invention. FIG. It is a circuit diagram which shows the 2nd structural example of the variable gain type low noise amplifier in embodiment of this invention. It is a circuit diagram which shows the 3rd structural example of the variable gain low noise amplifier in embodiment of this invention. It is explanatory drawing explaining the output state of the 1st and 2nd circuit control logic circuit in each gain state of the variable gain low noise amplifier in embodiment of this invention. It is a circuit diagram which shows the structural example of a conventional circuit.

Explanation of symbols

DESCRIPTION OF SYMBOLS 8 ... 1st output matching circuit 9 ... 2nd output matching circuit 10 ... 1st circuit control logic circuit 11 ... 2nd circuit control logic circuit 101 ... Amplifying circuit 102 ... Bias circuit 103 ... Bypass circuit 104 ... Variable attenuation circuit 105 ... first SPDT switch 106 ... second SPDT switch 107 ... fixed attenuator

Claims (2)

An amplifying circuit, a bypass circuit connected in parallel between the input and output of the amplifying circuit and diverting a signal input to the amplifying circuit to the output side of the amplifier according to a control signal; and a signal output from the amplifying circuit A variable gain low noise amplifier comprising a variable attenuating circuit for attenuating with respect to
The variable attenuation circuit is provided in series in the subsequent stage of the amplifier circuit, and a first matching circuit is provided between the stage of the amplifier circuit and the variable attenuation circuit, and the first matching circuit and A second matching circuit is provided between the stage with the variable attenuation circuit and a power supply terminal to which an external power supply voltage is applied;
The first matching circuit and the second matching circuit are configured to conjugate the output impedance of the amplifier circuit and the input impedance of the variable attenuating circuit and to achieve matching. Noise amplifier.   The variable attenuating circuit according to claim 1, wherein the variable attenuating circuit uses a T-type fixed attenuator and is configured to be able to bypass the T-type fixed attenuator by a path switching SPDT switch. Noise amplifier.

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