JP4693706B2 - Amplifier with standby function - Google Patents

Description

  The present invention relates to a high-frequency signal amplifier used in various wireless communication devices including a mobile communication device, and in particular, simplification of the configuration of an amplifier having a standby function and power saving. About.

Conventionally, in amplifiers used in wireless communication devices and devices such as mobile communication devices, the power supply voltage supplied to the amplifier is cut off to extend the battery life when there is no need to operate the amplifier when waiting for communication. Then, the amplifier has been set to a standby state (standby state).
In such a case, in order to realize a standby state in an amplifier that does not have a standby function, a separate switch circuit for cutting off the power supply voltage is prepared outside the amplifier, and the switch circuit cuts off the power supply voltage to the amplifier. It is common that However, in this case, since a separate switch circuit is required, problems such as an increase in cost due to an increase in the number of components and an increase in the component mounting area are caused.

  On the other hand, in the case of an amplifier having a standby function, the operation state of the amplifier can be switched by a control voltage supplied to the amplifier. Therefore, it is necessary to add a switch circuit in the amplifier without the standby function described above. Therefore, problems such as an increase in cost and an increase in component mounting area are solved.

As such an amplifier with a standby function, for example, there is one disclosed in Patent Document 1 or the like.
FIG. 3 shows an example of the circuit configuration of such a conventional amplifier. Hereinafter, this conventional circuit will be described with reference to FIG.
This amplifier is of a variable gain type, and has a dual gate signal amplification field effect transistor (hereinafter referred to as “FET”) Q1 and a bias for controlling the supply of bias to this signal amplification FET Q1. The SW FET Q2 and a bypass FET Q3 for bypassing the signal amplification FET Q1 between the high-frequency signal input terminal 18A and the high-frequency signal output terminal 19A are mainly configured.

  That is, a high-frequency signal is input from the high-frequency signal input terminal 18A to the gate G1 of the signal amplification FET Q1 via the input-side DC cut capacitor 4A and the input matching circuit 15A. The signal is output from the drain to the high frequency signal output terminal 19 through the output impedance matching circuit 16A and the output side DC cut capacitor 17A.

In addition, a bias SW FET Q2 is connected in series to the ground of the signal amplifying FET Q1 via a source inductor 6A via a source inductor 6A. By the SW control voltage applied to the gate of the bias SW FET Q2, The signal amplifying field effect transistor Q1 is configured to be in a standby state.

  In such a configuration, when the amplifier is in a normal operation state (a state in which the gain is not varied), a power supply voltage is applied to the power supply voltage application terminal 21A so that the signal amplification FET Q1 is in an operation state, and SW A bias that turns on the bias SW FET Q2 is applied to the control voltage application terminal 35A, while a control voltage that satisfies V (CONT36A) >> − Vp (Q3) is applied to the bypass control voltage application terminal 36A. Will be applied. Here, V (CONT36A) is a control voltage applied to the bias control voltage application terminal 36A, and Vp (Q3) is a pinch-off voltage of the bypass FET Q3.

  By this voltage application, the signal amplification FET Q1 is in an operating state, while the bypass FET Q3 is in an OFF state, and the high frequency signal input from the high frequency signal input terminal 18A is not attenuated by the bypass FET Q3, The signal is amplified by the FET Q1 and output to the high frequency signal output terminal 19A. Therefore, in this case, the maximum gain of the amplifier can be obtained.

On the other hand, when the gain is varied, a bias is applied to the SW control voltage application terminal 35A so that the bias SW FET Q2 is turned off, while V (CONT36A) <<-Vp (Q3) is applied to the bypass control voltage application terminal 36A. ) Will be applied.
As a result, the signal amplifying FET Q1 is turned off, while the bypass FET Q3 is turned on, and the high frequency signal applied to the high frequency signal input terminal 18A is not amplified by the signal amplifying FET Q1 and is bypassed. Is output to the high-frequency signal output terminal 19A.

  In such a variable gain state, a bias voltage is applied to the SW control voltage application terminal 35A so that the bias SW FET Q2 is in an OFF state, thereby setting the signal amplification FET Q1 in an OFF state. The consumption current as an amplifier is almost zero. That is, this conventional variable gain amplifier can be regarded as a variable gain state in a standby state.

  Incidentally, in the conventional circuit described above, the control voltage applied to the SW control voltage application terminal 35A and the current (operating current) flowing through the signal amplification FET Q1 have a correlation as shown in FIG. That is, according to the figure, when performing variable gain, that is, to set the amplifier to the standby state, a control voltage satisfying V (CONT35A) << Vp (Q2) is applied to the SW control voltage application terminal 35A. I understand that I need to do that. Here, V (CONT35A) is a control voltage applied to the SW control voltage application terminal 35A, and Vp (Q2) is a pinch-off voltage of the bias SW FET Q2.

  The voltage range represented by the above inequality depends on the pinch-off voltage Vp (Q2) of the bias SW FET Q2, and the voltage range becomes extremely narrow depending on the magnitude of the pinch-off voltage Vp (Q2), but V (CONT35A ) ≧ Vp (Q2) is applied to the SW control voltage application terminal 35A, the bias SW FET Q2 is not in the OFF state, the operating current increases as the control voltage increases, and the gain is variable, that is, in standby mode. The state cannot be maintained.

In the case of the characteristics shown in FIG. 4, when the control voltage applied to the SW control voltage application terminal 35A varies even slightly, it becomes impossible to set a desired operation state as a variable gain amplifier. For this reason, the standard value of the applied control voltage must be narrowed to a very narrow range.
Usually, as a countermeasure, a method is adopted in which a logic circuit is separately prepared and the output voltage of the logic circuit is supplied to the SW control voltage application terminal 35A in order to adjust the application voltage of the SW control voltage application terminal 35A. There are many cases.

FIG. 5 shows a circuit configuration example of a variable gain amplifier provided with such a logic circuit. The variable gain amplifier will be described below with reference to FIG.
This conventional circuit has a configuration in which a logic circuit 101 is added to the variable gain amplifier having the configuration shown in FIG. The same constituent elements as those shown in FIG. 3 are denoted by the same reference numerals, detailed description thereof will be omitted, and different points will be mainly described below.

  The logic circuit 101 is formed by connecting FETs Q4 and Q5 in two stages to form a level shift circuit, and its output terminal, that is, the drain of the FET Q5 is connected to the SW control voltage application terminal 35A. A voltage varied according to the voltage applied to the control voltage application terminal 39A is applied to the SW control voltage application terminal 35A and the bypass control voltage application terminal 36A. The power supply voltage of the logic circuit 101 is applied to the logic circuit power supply voltage application terminal 38A.

  In such a configuration, the change in the operation current of the signal amplification FET Q1 with respect to the control voltage of the logic control voltage application terminal 39A is as shown in FIG. 6, and the operation current in the signal amplification FET Q1 with a certain control voltage as a boundary. It becomes possible to control the presence or absence of. Therefore, compared with the configuration shown in FIG. 3, the voltage range for setting the amplifier to the standby state and the amplifier for setting the operating state even when the control voltage fluctuates. A wide voltage range can be secured, and the operational state of the amplifier can be maintained easily in a desired state.

JP 2004-274108 A (page 6-8, FIG. 1 to FIG. 2)

  However, separately providing a logic circuit for adjusting the control voltage as described above causes an increase in circuit area and an increase in cost. In addition, the use of the logic circuit increases the current consumption in the logic circuit and increases the current consumption of the entire amplifier. As a result, the power consumption is hindered to extend the battery life. There is a problem.

  In the conventional circuit having the configuration described with reference to FIGS. 3 and 5, the bias SW FET Q2 is connected to the source of the signal amplifying FET Q1, so that the impedance at the source is grounded in a high frequency manner. A bypass capacitor Cs (see FIGS. 3 and 5) is required. Usually, in order to obtain good characteristics of an amplifier, the above-mentioned bypass capacitor needs to be increased in capacity, but this causes a problem of increasing the circuit area and cost.

The present invention has been made in view of the above circumstances, and without using a conventional logic circuit for adjusting a control voltage for a transistor for controlling the operation of an amplifier, and for grounding the source of an amplifying transistor. It is an object of the present invention to provide an amplifier with a standby function that can realize a standby function with a simple configuration without using a bypass capacitor and that can reduce the consumption current of the amplifier in a standby state to zero.
Another object of the present invention is to provide an amplifier with a standby function capable of ensuring a wider control voltage range for setting the amplifier in a standby state and a control voltage range for setting the amplifier in an operating state than in the prior art. It is to provide.

In order to achieve the above object of the present invention, an amplifier with a standby function according to the present invention comprises:
Two signal amplifying field effect transistors are provided in cascade to perform an amplifying operation, and a bias switching SW field effect transistor for placing the two signal amplifying field effect transistors in a standby state is provided. An amplifier with a standby function,
A gate bias applying bias circuit is connected to each gate of the two signal amplification field effect transistors,
The bias switching SW field effect transistor is provided such that its source voltage is changed in accordance with an external control voltage, and the source voltage is supplied to the two signals via the respective gate bias applying bias circuits. These are applied to the gates of the amplifying field effect transistors, respectively, so that the amplifier can be switched between a standby state and an amplifying operation.
In this configuration, in the two signal amplification field effect transistors, the drain of the first signal amplification field effect transistor and the source of the second signal amplification field effect transistor are connected to each other, and the first signal amplification field effect transistor is connected to the first signal amplification field effect transistor. The source of the signal amplifying transistor is connected to the ground via the source inductor to form a cascade connection,
An amplified signal can be applied to the gate of the first signal amplifying field effect transistor, while an amplified signal can be output to the drain of the second signal amplifying transistor,
The control voltage can be applied to the gate of the bias switching SW field effect transistor, while a power supply voltage is applied to the drain and the drain of the second signal amplification field effect transistor via a choke inductor. Is possible,
The source of the field effect transistor for bias switching SW is preferably connected to the ground via a resistor and a diode provided in the forward direction on the ground side.
It is also preferable to use a dual gate field effect transistor instead of the two signal amplification field effect transistors.

According to the present invention, the standby state can be realized by changing the bias voltage of the field effect transistor performing the amplification operation by the field effect transistor for bias switching SW whose operation state is changed by the control voltage applied from the outside. Therefore, unlike the conventional case, the standby function can be realized with a simple configuration without separately providing a logic circuit for converting the change in the control voltage, and the consumption current of the amplifier in the standby state is reduced to zero. Can be.
In addition, since the control voltage range for setting the standby state can be easily expanded as compared with the conventional circuit, the control voltage for determining the operational state of the amplifier is changed. However, there is an effect that it is possible to maintain the set desired operation state.

Hereinafter, embodiments of the present invention will be described with reference to FIGS. 1 and 2.
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 configuration example of an amplifier with a standby function in the embodiment of the present invention will be described with reference to FIG.
The amplifier with a standby function in the embodiment of the present invention includes first and second signal amplification field effect transistors (hereinafter referred to as “FET”) 1 and 2, and a bias switching SW FET 3. And are configured as main components. In general, such an amplifier with a standby function is configured such that the operation state of the bias switching SW FET 3 is varied by the bias applied to the control voltage application terminal 20, so that the operation state of the amplifier is selected. It is configured to be possible.

Hereinafter, the circuit connection will be specifically described.
The gate of the first signal amplifying FET 1 is connected to the high-frequency signal input terminal 18 via the input side DC cut capacitor 4 and the input impedance matching circuit 15, and via the first gate bias applying bias circuit 12. It is connected to the source of the FET 3 for bias switching SW.
The gate of the second signal amplifying FET 2 is connected to the source of the bias switching SW FET 3 via the second gate bias applying bias circuit 13 and to the ground via the bypass capacitor 5.

The source of the first signal amplification FET 1 is connected to the ground through the source inductor 6, while the drain is connected to the source of the second signal amplification FET 2.
The drain of the second signal amplifying FET 2 is connected to the high frequency signal output terminal 19 via the output impedance matching circuit 16 and the output side DC cut capacitor 17, and the first and second signal amplifying FETs 1, 2 is connected in cascade.

Further, the drain of the second signal amplification FET 2 is connected to the power supply voltage application terminal 21 via the choke inductor 14 and is connected to the drain of the bias switching SW FET 3 via the drain resistor 11.
On the other hand, the gate of the bias switching SW FET 3 is connected to the ground via the gate grounding resistor 8 and is connected to the control voltage application terminal 20 via the gate input resistor 7.

The source of the bias switching SW FET 3 is connected to the ground via the source resistor 9 and the diode 10. The diode 10 is provided so that its anode is connected to the source resistor 9 and its cathode is connected to the ground so that it is in the forward direction with respect to the ground.
In the embodiment of the present invention, the first and second signal amplification FETs 1 and 2 and the bias switching SW FET 3 are enhancement mode FETs.

Next, the operation in this configuration will be described.
First, in the case of normal amplification operation, a power supply voltage for operating the first and second signal amplification FETs 1 and 2 is applied to the power supply voltage application terminal 21, while the control voltage application terminal 20 is applied to the control voltage application terminal 20. Then, a bias is applied so that the bias switching SW FET 3 is turned on.
Since the power supply voltage from the power supply voltage application terminal 21 is applied to the drain of the bias switching SW FET 3 via the drain resistor 11 and the choke inductor 14, when the bias switching SW FET 3 is turned on, A predetermined voltage is generated at the source.

  The voltage generated at the source of the bias switching SW FET 3 is the gate width of the bias switching SW FET 3, the source resistor 9 and the diode 10, and the first and second gate bias applying bias circuits 12 and 13. By optimizing the constant, a desired voltage value is set.

As described above, when a desired voltage is generated at the source of the bias switching SW FET 3, the first and second signal amplifying signals are supplied via the first and second gate bias applying bias circuits 12 and 13. Bias is applied to the gates of the FETs 1 and 2 respectively.
The first and second gate bias application bias circuits 12 and 13 are, for example, as the simplest configuration, for example, the source of the bias switching SW FET 3 and the first and second gate bias application. This can be realized by a configuration in which a resistor is provided in series between the gates of the bias circuits 12 and 13, respectively.

  Since the circuit constants of the first and second bias bias applying bias circuits 12 and 13 are optimized so as to obtain a desired operating current as an amplifier, the source voltage of the bias switching SW FET 3 as described above. Is applied, the first and second signal amplification FETs 1 and 2 operate at a desired bias point.

  Therefore, in this state, the high frequency signal applied to the high frequency signal input terminal 18 is input to the gate of the first signal amplifying FET 1 via the input impedance matching circuit 15 and the input side DC cut capacitor 4, and The signals are amplified by the first and second signal amplification FETs 1 and 2 and amplified from the drain of the second signal amplification FET 2. The high-frequency signal output from the drain of the second signal amplification FET 2 is output to the high-frequency signal output terminal 19 via the output impedance matching circuit 16 and the output-side DC cut capacitor 17, so that normal amplification Operation is to be performed.

On the other hand, in order to put the amplifier in a standby state, a bias is applied to the control voltage application terminal 20 so that the bias switching SW FET 3 is turned off. On the other hand, a power supply voltage is applied to the power supply voltage terminal 21 so that the first and second signal amplification FETs 1 and 2 operate in the same manner as described above. The voltage is applied to the drain of the bias switching SW FET 3 via the resistor 11.
However, as described above, since the bias switching SW FET 3 is in the OFF state, no voltage is generated at the source unlike the case of the normal operation.

Therefore, no bias is applied to the first and second gate bias applying bias circuits 12 and 13, and as a result, no bias is applied to the gates of the first and second signal amplification FETs 1 and 2. It will be. Accordingly, the first and second signal amplification FETs 1 and 2 are turned off, and the operating current is zero.
In such a state, no current is consumed in any element in the circuit, so that the operating current of the entire amplifier becomes zero.

  As described above, the amplifier with a standby function according to the embodiment of the present invention includes the gate input resistor 7, the gate grounding resistor 8, the source resistor 9, the constant of each element of the diode 10, and the gate of the bias switching SW FET 3. By optimizing the width, the range of the control voltage for setting the standby state can be easily expanded as compared with the conventional circuit.

FIG. 2 shows characteristic lines showing changes in operating currents flowing through the first and second signal amplification FETs 1 and 2 with respect to the control voltage of the amplifier with standby function in the embodiment of the present invention. The figure will be described.
According to the figure, the control for setting the operating current of the amplifier to zero, in other words, setting the currents of the first and second signal amplification FETs 1 and 2 to zero, that is, setting to the standby state. It can be confirmed that the voltage range is 0 to 0.8V. This is because the similar control voltage range in the conventional circuit described in the “Background Art” column is 0 to 0.1 V (see FIG. 4). The range of the control voltage is enlarged by 0.7 V, and it can be confirmed that a clear characteristic improvement has been made.

  Further, the above-described amplifier with a standby function according to the embodiment of the present invention does not require a logic circuit in the conventional circuit as shown in FIG. 5 and can prevent an increase in circuit area and cost. It has become. Furthermore, as described above, in the standby state, unlike the conventional case, not only the current flowing through the signal amplification FET, but also the current consumption of the entire amplifier becomes zero. Can be made.

  In the configuration example described above, the first and second signal amplification FETs 1 and 2 are cascaded by mutual connection of the drain of the first signal amplification FET 1 and the source of the second signal amplification FET 2. However, the present invention is not limited to such a configuration. For example, instead of this configuration, a dual gate FET may be used.

It is a circuit diagram which shows the structural example of the amplifier with a standby function in embodiment of this invention. It is a characteristic diagram which shows the change of the operating current which flows through the 1st and 2nd signal amplification FET with respect to the control voltage of the amplifier with a standby function in embodiment of this invention. It is a circuit diagram which shows the 1st circuit structural example of a conventional circuit. FIG. 4 is a characteristic diagram showing a change in operating current flowing through the signal amplification FET with respect to the control voltage of the conventional circuit shown in FIG. 3. It is a circuit diagram which shows the 2nd circuit structural example of a conventional circuit. FIG. 6 is a characteristic diagram showing a change in operating current flowing through the signal amplification FET with respect to the control voltage of the conventional circuit shown in FIG. 5.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... 1st signal amplification field effect transistor 2 ... 2nd signal amplification field effect transistor 3 ... Bias switching SW field effect transistor 12 ... 1st gate bias application bias circuit 13 ... 2nd gate bias application Bias circuit 18 ... high frequency signal input terminal 19 ... high frequency signal output terminal 20 ... control voltage application terminal

Claims (3)

Two signal amplifying field effect transistors are provided in cascade to perform an amplifying operation, and a bias switching SW field effect transistor for placing the two signal amplifying field effect transistors in a standby state is provided. An amplifier with a standby function,
A gate bias applying bias circuit is connected to each gate of the two signal amplification field effect transistors,
The bias switching SW field effect transistor is provided such that its source voltage is changed in accordance with an external control voltage, and the source voltage is supplied to the two signals via the respective gate bias applying bias circuits. An amplifier with a standby function, wherein the amplifier is applied to the gates of the amplifying field effect transistors, respectively, and the amplifier can be switched between a standby state and an amplifying operation. In the two signal amplification field effect transistors, the drain of the first signal amplification field effect transistor and the source of the second signal amplification field effect transistor are connected to each other, and the first signal amplification transistor Source is connected to the ground through the source inductor and is connected in cascade,
An amplified signal can be applied to the gate of the first signal amplifying field effect transistor, while an amplified signal can be output to the drain of the second signal amplifying transistor,
The control voltage can be applied to the gate of the bias switching SW field effect transistor, while a power supply voltage is applied to the drain and the drain of the second signal amplification field effect transistor via a choke inductor. Is possible,
An amplifier with a standby function, characterized in that the source of the field effect transistor for bias switching SW is connected to the ground through a resistor and a diode provided in the forward direction on the ground side.   3. The amplifier with a standby function according to claim 1, wherein a dual gate field effect transistor is used in place of the two signal amplification field effect transistors.

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