JPH10150429A - Transmission circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a transmission circuit in which current consumption is reduced in response to a transmission output with a wide dynamic range. SOLUTION: This transmission circuit has an orthogonal modulator 3, a gain control amplifier 4, an up-mixer 7, a driver amplifier 8, a power amplifier 9 and an antenna 10 and is configured so as to generate a transmission output of a wide range. In this case, there are provided with a 1st switch 12 that bypasses an input signal of the driver amplifier 8, a 2nd switch 10 that bypasses an input signal of the power amplifier 9 and a controller 18 that applies on/off control to a power supply of the driver amplifier 8 and the power amplifier 9 to generate a control signal for the gain control amplifier 4, the 1st switch 12 and the 2nd switch 13. A current at a low transmission output is reduced by conducting the gain control of the gain control amplifier 4 depending on the transmission output, bypass control of the input signal to the power amplifier 9 and the driver amplifier 8, and power on/off control of the power amplifier 9 and the driver amplifier 8.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmission circuit of a transmitter for a code division multiple access system (CDMA system) used for digital mobile communication and the like. The present invention relates to a transmission circuit that can reduce consumption.

[0002]

2. Description of the Related Art In a CDMA system, a primary-modulated signal is secondarily modulated by a spread signal and transmitted, and a receiving side correlates (despreads) with a spread signal of a desired channel to obtain a desired one. Extract the next modulated wave. In the process of the despreading, signals of other channels become noise. In the downlink from the base station to the mobile station, the target signal wave and other interference waves are similarly varied on the propagation path and reach each mobile station. The relationship between the reception levels of the signal wave and the interference wave is constant.

However, in the uplink from a mobile station to a base station, even if each mobile station transmits a signal wave with the same transmission power, the distance from the mobile station to the base station and the propagation environment are different. Then, the reception level of each signal wave at the base station differs. Therefore, in order for the base station to correctly demodulate each signal wave by despreading, the reception level of each signal wave must be aligned, and the mobile station needs to have high-accuracy and wide dynamic range transmission power control. .

As shown in FIG. 5, a transmitting circuit of a transmitter used in a conventional digital mobile communication system performs quadrature modulation on an I signal 1, a Q signal 2, an I signal and a Q signal modulated by a spread signal. Modulator 3, a gain control amplifier 4 that varies the gain of an input signal by a control voltage, and a gain control amplifier 4.
A control voltage 5 for controlling the gain of the amplifier, an up-mixer 7 for up-converting the output signal of the gain control amplifier 4 and the local signal 6 to an RF frequency, a driver amplifier 8 for amplifying the output signal of the up-mixer 7, A power amplifier (hereinafter abbreviated as PA) 9 for amplifying an output signal of the driver amplifier 8 and an antenna 10 for outputting an output signal of the PA 9 are provided.

In this transmission circuit, the input I signal 1,
The Q signal 2 is quadrature-modulated by the modulator 3, the gain is controlled by the gain control amplifier 4 according to the control voltage 5,
RF mixed with local signal 6 by up-mixer 7
The frequency is up-converted, and the driver amplifier 7 and
The signal is amplified by the PA 9 and output from the antenna 10.

[0006]

However, in the conventional transmission circuit, since the transmission power is controlled by only one gain control amplifier, the transmission power is controlled by a CDMA transmitter requiring a wide dynamic range. Even when transmitting with reduced output, the driver amplifier and PA are still powered, so despite the low transmission output,
There is a problem that current consumption is large.

SUMMARY OF THE INVENTION The present invention solves the above-mentioned conventional problems.
An object of the present invention is to provide a transmission circuit that can reduce current consumption according to a transmission output.

[0008]

Therefore, in the transmission circuit of the present invention, in addition to a gain control amplifier for varying the gain of an input signal according to a control voltage, a means for bypassing a signal to a driver amplifier and a PA; Sometimes driver amplifier and PA
Means is provided for turning off the power supply, and according to the transmission output, the signal is bypassed and the power supply is turned on / off. Therefore, the PA and the driver amplifier are bypass-controlled according to the transmission output, and the power supply of the PA and the driver amplifier is turned on / off.
By performing the off control, it is possible to reduce the current consumption according to the transmission output.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The invention according to claim 1 of the present invention is directed to a modulator for orthogonally modulating an I signal and a Q signal, and a gain control for varying the gain of an output signal of the modulator in accordance with a control voltage. An amplifier, an upmixer that mixes an output signal of the gain control amplifier and a local signal, a driver amplifier that amplifies an output signal of the upmixer, a power amplifier that amplifies an output signal of the driver amplifier, and a power amplifier that amplifies the output signal of the driver amplifier. An antenna that outputs an output signal, a first switch that bypasses an input signal of the driver amplifier, a second switch that bypasses an input signal of the power amplifier, and powers on / off the driver amplifier and the power amplifier. A controller for controlling off and generating a control signal for the gain control amplifier, the first switch, and the second switch. According to a transmission output, gain control of the gain control amplifier, bypass control of input signals of the power amplifier and the driver amplifier, and on / off control of power supplies of the driver amplifier and the power amplifier are performed. This has the effect that the power consumption can be reduced by controlling the power supply to be turned off by bypassing the power amplifier and the driver amplifier as the transmission output decreases.

According to a second aspect of the present invention, the driver amplifier and the power amplifier are gain control amplifiers that can be varied in accordance with a gain control voltage. It has the effect of being variable.

According to a third aspect of the present invention, the output signal of the power amplifier is switched according to a control signal.
An F switch and a detector for detecting an output signal of the RF switch, performing gain correction of the gain control amplifier before transmission, and performing gain correction of the driver amplifier and the power amplifier during transmission output control This has the effect that the accuracy of the transmission power control of the gain control amplifier, the driver amplifier and the power amplifier can be guaranteed.

According to a fourth aspect of the present invention, the driver amplifier and the power amplifier according to the third aspect are gain control amplifiers whose gain can be varied according to a control voltage. This has the effect that the precision of the transmission power control of the gain control amplifier, the driver amplifier and the power amplifier can be guaranteed.

Hereinafter, an embodiment of the present invention will be described with reference to FIG.
This will be described with reference to FIG. (First Embodiment) As shown in FIG. 1, a transmission circuit according to a first embodiment of the present invention includes an I signal 1, a Q signal 2,
A modulator 3 for orthogonally modulating an I signal and a Q signal, a gain control amplifier 4 for variably controlling an output signal of the modulator 3 according to a control voltage 5, and mixing an output signal of the gain control amplifier 4 with a local signal 6. Up-mixer 7, driver amplifier 8 for amplifying the output signal of up-mixer 7, first switch 12 for bypassing input / output of driver amplifier 8 according to control signal 14, and amplifying the output signal of driver amplifier 8 A power amplifier 9, a second switch 13 for bypassing the input / output of the power amplifier 9 in accordance with a control signal 15, an antenna 10 for outputting an output signal of the power amplifier 9, and a control for controlling the gain of the gain control amplifier 4. The voltage 5, the control signal 14 for the first switch 12, and the control signal for the second switch 13.
And a controller 18 for generating a power control signal 16 for the driver amplifier 8 and a power control signal 17 for the power amplifier 9.

Next, the operation of the transmission circuit according to the first embodiment will be described. First, the operation at the time of the maximum transmission output (Pmax) will be described. The input I signal 1 and Q signal 2 are quadrature-modulated by a modulator 3 and controlled by a gain control amplifier 4 by a controller.
The signal is variably amplified in accordance with the control voltage 5 output from 18, mixed with the local signal 6 by the upmixer 7, upconverted to an RF frequency, amplified by the driver amplifier 8 and the power amplifier 9, and output from the antenna 10. You.

When the gain of the power amplifier 9 is G1 and the gain of the driver amplifier 8 is G2, the transmission output Pout is Pout ≧ Pmax
The above operation is performed until −G1.

When the transmission output Pout is Pmax-G1-G2 <Pout <Pmax
In the case of -G1, the second switch 13 is turned on, and the power supply of the power amplifier 9 is turned off by the control signal 15, whereby the power amplifier 9 is bypass-controlled.
When Pmax−G1−G2, the first switch 12 is turned on, and the power supply of the driver amplifier 8 is turned off by the control signal 14, whereby the driver amplifier 8 is bypass-controlled. The transmission output of the gain control amplifier 4 is controlled by the control voltage 5.

Therefore, the power consumption is reduced at the time of low transmission output by performing bypass control of the power amplifier and the driver amplifier in accordance with the transmission output and performing on / off control of the power supply.

(Second Embodiment) A transmission circuit according to a second embodiment of the present invention uses the driver amplifier 8 and the power amplifier 9 of the first embodiment as variable gain control amplifiers. . As shown in FIG. 2, the transmission circuit includes a driver amplifier 19 that varies a gain according to a control voltage 21 and a power amplifier 20 that varies a gain according to a control voltage 22. Other configurations are the same as those of the first embodiment.

The transmitting circuit according to the second embodiment operates as follows. First, the operation at the time of the maximum transmission output (Pmax) will be described. The input I signal 1 and Q signal 2 are quadrature-modulated by a modulator 3 and controlled by a gain control amplifier 4 by a controller.
The signal is variably amplified in accordance with the control voltage 5 output from 18, mixed with the local signal 6 by the up-mixer 7, up-converted to an RF frequency, and controlled by the driver amplifier 19 in accordance with the control voltage 21 output from the controller 18. It is variably amplified, variably amplified by the power amplifier 20 according to the control voltage 22 output from the controller 18, and output from the antenna 10.

When the gain of the power amplifier 20 is G1 and the gain of the driver amplifier 19 is G2, the transmission output Pout is Pout ≧ Pmax
In the case of −G1, the gain of the power amplifier 20 is variably controlled by the control voltage 22 according to the transmission output, and the transmission output Pout
If Pmax−G1−G2 <Pout <Pmax−G1, the second switch 13 is turned on by the control signal 15 and the power supply of the power amplifier 20 is turned off by the power supply control signal 17 to bypass the power amplifier 20. The gain of the driver amplifier 19 is variably controlled by the control voltage 21 according to the transmission output.

When the transmission output Pout satisfies Pout ≦ Pmax−G1−G2, the first switch 12 is turned on by the control signal 14 and the power of the driver amplifier 19 is turned off by the power control signal 16 so that the driver is turned off. The amplifier 19 is bypass-controlled, and the transmission output is controlled by the control voltage 5 of the gain control amplifier 4 when the transmission output is lower than that.

Therefore, the gains of the power amplifier and the driver amplifier can be variably controlled according to the transmission output, and the current consumption can be continuously reduced according to the gain.
By performing power on / off control, current consumption can be reduced at low transmission output.

(Third Embodiment) As shown in FIG. 3, a transmitting circuit according to a third embodiment of the present invention includes an RF switch 23 for switching an output signal of a power amplifier 9 and an output of the RF switch 23. A detector 24 for power detection of the signal, and a detector 24
, And a control signal 26 for the RF switch 23. Other configurations are the same as those of the first embodiment.

The transmitting circuit according to the third embodiment operates as follows. First, at the start of operation, the RF switch 23 is set to the detector 24 side by the control signal 26, and the detection voltage V1 at the time of the maximum transmission output (Pmax) is detected.

Next, the second switch 13 is turned on by the control signal 15, and the power supply of the power amplifier 9 is turned off by the power supply control signal 17, thereby bypassing the power amplifier 9 and detecting the detection voltage V2.

Next, the second switch 13 is turned off by the control signal 15, the power of the power amplifier 9 is turned on by the power control signal 17, the power amplifier 9 is turned on, and the first switch 12 is turned on by the control signal 14. When the power is turned on and the power supply of the driver amplifier 8 is turned off by the power supply control signal 16, the driver amplifier 8 is bypass-controlled and the detection voltage V3 is detected.

Next, the first switch 12 is turned off by the control signal 14 and the power supply of the driver amplifier 8 is turned off by the power supply control signal 16.
To turn on the driver amplifier 8, to set the control voltage 5 of the gain control amplifier 4 to the minimum output, and to detect the detection voltage V4.

At this time, the gain of the power amplifier 9 is represented by V1-V2, the gain of the driver amplifier 8 is represented by V1-V3, and the gain control range of the gain control amplifier 4 is represented by V1-V4.
At 18, correction is made accordingly. After the correction, the RF switch 23 is set to the antenna 10 side by the control signal 26, and the same operation as in the first embodiment is performed.

Therefore, regardless of the temperature condition and the transmission frequency condition, the power amplifier 9, the driver amplifier 8,
The gain of the gain control amplifier 4 is corrected, transmission control can be performed with high accuracy, and the power amplifier and the driver amplifier are bypass-controlled in accordance with the transmission output and the power supply is turned on / off, so that the current consumption at the time of low transmission output is reduced. Can be reduced.

(Fourth Embodiment) A transmission circuit according to a fourth embodiment of the present invention comprises a power amplifier as shown in FIG.
An RF switch 23 for switching an output signal of the RF switch 20; a detector 24 for power detection of an output signal of the RF switch 23;
, And a control signal 26 for the RF switch 23. Other configurations are the same as those of the second embodiment.

The transmission circuit according to the fourth embodiment operates as follows. First, at the start of operation, the RF switch 23 is set to the detector 24 side by the control signal 26, and the detection voltage V1 at the time of the maximum transmission output (Pmax) is detected.

Next, the second switch 13 is turned on by the control signal 15, and the power supply of the power amplifier 20 is turned off by the power supply control signal 17, thereby bypassing the power amplifier 20 and detecting the detection voltage V2.

Next, the second switch 13 is turned off by the control signal 15, the power of the power amplifier 20 is turned on by the power control signal 17, the power amplifier 20 is turned on, and the first switch 12 is turned on by the control signal 14. By turning off the power supply of the driver amplifier 19 by the power supply control signal 16, the driver amplifier 19 is bypass-controlled and the detection voltage V3 is detected.

Next, the first switch 12 is turned off by the control signal 14 and the power supply of the driver amplifier 19 is turned off by the power supply control signal 16.
To turn on the driver amplifier 19, set the control voltage 5 of the gain control amplifier 4 to the minimum output, and detect the detection voltage V4.

At this time, the gain of the power amplifier 20 is represented by V1-V2, the gain of the driver amplifier 19 is represented by V1-V3, and the gain control range of the gain control amplifier 4 is represented by V1-V4.
At 18, correction is made accordingly. After the correction, the RF switch 23 is set to the antenna 10 side by the control signal 26, and the same operation as in the second embodiment is performed.

Therefore, regardless of the temperature condition and the transmission frequency condition, the power amplifier 20, the driver amplifier 19,
The gain of the gain control amplifier 4 is corrected, so that transmission control can be performed with high accuracy, and the power amplifier 20 and the driver amplifier 19 are bypass-controlled in accordance with the transmission output, and the power supply is turned on / off, so that when the transmission output is low, The current consumption can be reduced.

[0037]

As is apparent from the above description, the transmission circuit of the present invention can control the gain of the gain control amplifier, the bypass control of the power amplifier and the driver amplifier, and turn on / off the power supply according to the transmission output. By performing control,
According to the transmission output, high precision and low current consumption can be achieved.

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration of a transmission circuit according to a first embodiment of the present invention;

FIG. 2 is a diagram illustrating a configuration of a transmission circuit according to a second embodiment of the present invention;

FIG. 3 is a diagram illustrating a configuration of a transmission circuit according to a third embodiment of the present invention;

FIG. 4 is a diagram showing a configuration of a transmission circuit according to a fourth embodiment of the present invention;

FIG. 5 is a diagram illustrating a configuration of a conventional transmission circuit.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 I signal 2 Q signal 3 Modulator 4 Gain control amplifier 5 Control voltage 6 Local signal 7 Up mixer 8, 19 Driver amplifier 9, 20 Power amplifier 10 Antenna 12 First switch 13 Second switch 14 First switch Control signal to the second switch 15 power control signal to the driver amplifier 17 power control signal to the power amplifier 18 controller 21 control voltage to the driver amplifier 22 control voltage to the power amplifier 23 RF switch 24 detection 25 Detection voltage 26 Control signal to detector

Claims (4)

[Claims] A modulator for orthogonally modulating an I signal and a Q signal; a gain control amplifier for varying a gain of an output signal of the modulator in accordance with a control voltage; and an output signal and a local signal of the gain control amplifier. An up-mixer for mixing, a driver amplifier for amplifying an output signal of the up-mixer, a power amplifier for amplifying an output signal of the driver amplifier, an antenna for outputting an output signal of the power amplifier, and an input signal of the driver amplifier A first switch that bypasses the input signal of the power amplifier, a second switch that bypasses an input signal of the power amplifier, on / off control of the power supply of the driver amplifier and the power amplifier, and the gain control amplifier and the first switch. And a controller for generating a control signal for the second switch, wherein the gain control is increased in accordance with a transmission output. A transmission circuit, comprising: a gain control of a width unit; a bypass control of input signals of the power amplifier and the driver amplifier; and an on / off control of a power supply of the driver amplifier and the power amplifier. 2. The gain control amplifier according to claim 1, wherein said driver amplifier is a gain control amplifier that varies a gain according to a control voltage, and said power amplifier is a gain control amplifier that varies a gain according to a control voltage. 2. The transmission circuit according to claim 1, wherein the driver amplifier and the power amplifier are continuously subjected to variable gain control. 3. An RF switch for switching an output signal of the power amplifier according to a control signal; and a detector for detecting an output signal of the RF switch, wherein a gain of the gain control amplifier is corrected before transmission. 2. The transmission circuit according to claim 1, wherein a gain of the driver amplifier and the power amplifier is corrected during transmission output control. 4. The gain control amplifier according to claim 1, wherein the driver amplifier is a gain control amplifier that varies a gain according to a control voltage, and the power amplifier is a gain control amplifier that varies a gain according to a control voltage. 4. The transmission circuit according to claim 3, wherein the driver amplifier and the power amplifier are continuously variable-gain-controlled.