JPH09261292A - Device and method for controlling gain of linearizer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simplify a circuit scale and adjustment by feeding-back the output of a power amplifier when an orthogonally modulated modulating signal is level adjusted and amplified to an orthogonal modulator and adjusting the level of a return side attenuator. SOLUTION: The orthogonal modulator 1 orthogonally modulates a local signal and the power amplifier 3 amplifies the modulating signal which is level- adjusted by a forward-side attenuator(ATT) 2 so as to output it. A forward-side detecting means 4 detects the gain of the power amplifier 3 and a forward-side adjusting means 6 adjusts the forward-side ATT 2 so as to permit difference between the signal detected by the forward-side detecting means 4 and a set value to be zero. Moreover, the return-side ATT 7 permits the input signal of an orthogonal demodulator 10 to be variable. A return-side adjusting means 9 adjusts the return-side ATT 7 so as to permit difference between the gain of the orthogonal demodulator 10 detected by the return-side detecting means 8 and the set value to be zero and the signal demodulated by the orthogonal demodulator 10 is fed-back to the orthogonal modulator 1.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gain control device and a gain control method for a linearizer, and more particularly to a linearizer using a Cartesian loop for suppressing the spread of a transmission spectrum due to phase distortion in a digital radio device for burst transmission. The present invention relates to a gain control device and a gain control method.

[0002]

2. Description of the Related Art A conventional gain control device for a linearizer using a Cartesian loop is shown in FIG. The gain control device of the linearizer of this conventional example includes a gain detection means 38 for detecting the gain of the loop, and a forward attenuator so that the difference between the signal detected by the gain detection means 38 and a preset value becomes zero. Gain adjusting means 4 for adjusting 36
0, an output control circuit 39 for controlling the gain adjusting means 40 to obtain an output level of several stages, a fixed attenuator 42 of the same number as the required output level, and a switching circuit 41 for switching the fixed attenuator 42. .

Another conventional example similar to the present invention is disclosed in Japanese Unexamined Patent Publication No.
No. 7228 “Automatic controller for transmission power of narrow band modulated burst carrier” is available. In this conventional example, the amplitude of the pattern signal that gives a smooth ramp characteristic to the output power of the narrow band modulated burst carrier and the RF amplifier is regulated by the voltage control attenuator. A signal synthesized by multiplying the ramping control signal and a plurality of voltage level pattern signals that determine the transmission power level is compared with a period signal by an output level detector of an RF amplifier whose output level is voltage controllable. There is. Therefore, it is said that it becomes possible to control the output characteristic and the power gain according to the voltage level pattern of the smooth rising and falling slopes with a small number of bits and a memory capacity.

[0004]

However, in the above-mentioned conventional example, since the return side attenuator is fixed,
The same number of fixed attenuators is required to obtain several stages of gain, and each fixed attenuator needs to be adjusted in the initial setting of the device during production. Therefore, there is a problem that the circuit scale is large and the initial setting of the device at the time of production becomes complicated. Further, since the automatic gain control is performed only on the forward side, if the level on the return side changes due to a change in frequency or a temperature change, negative feedback will not be performed normally and the output will change. Therefore, there is a problem that the output fluctuates due to the influence of the temperature characteristic and the frequency characteristic of the system on the return side.

It is an object of the present invention to provide a gain control device and a gain control method for a linearizer, which enables simplification of circuit scale and adjustment.

[0006]

In order to achieve the above object, a gain control device for a linearizer according to the present invention according to claim 1 orthogonally modulates a local signal with a baseband waveform having a preamble at the beginning of a transmission slot. A quadrature modulator that outputs a modulation signal, a forward-side attenuator that adjusts the level of the modulation signal, a forward-side circuit unit that has a power amplifier that amplifies the modulation signal whose level is adjusted to a predetermined value by the forward-side attenuator, and a forward-side circuit unit. Forward side detecting means for detecting the gain of the circuit section, forward side adjusting means for adjusting the forward side attenuator by the detected value detected by the forward side detecting means and a preset setting value, and the adjusting operation of the forward side adjusting means. -Side loop circuit with output control circuit for controlling And a return-side attenuator that detects the modulation signal amplified by the power amplifier and adjusts the level of this detected detection signal, the detection signal adjusted by the return-side attenuator is orthogonally demodulated by the local signal, and this demodulation signal is quadrature modulator Quadrature demodulator that feeds back to the input section, return side detection means that detects the signal to be fed back, return side that controls the adjustment operation of the level of the return side attenuator based on the detected value and the preset value And a return side circuit section having an adjusting means, the forward side loop circuit section and the return side circuit section each automatically control the gain, and the signal level of the modulation signal output by the forward side circuit section is adjusted. It is characterized by automatic control.

The feedback signal is detected by an input section for inputting a detection signal adjusted by the return-side attenuator to the quadrature demodulator, and is further fed back to the input section of the quadrature modulator. It is preferable to use a signal after quadrature demodulation.

The linearizer gain control method of the present invention according to claim 4 is a linearizer gain control method in a digital radio apparatus for performing burst transmission, wherein the output of the orthogonal demodulator is first output in the preamble period at the beginning of the transmission slot. Is not fed back to the input of the quadrature modulator, the gain adjustment on the forward side of the loop is adjusted by adjusting the forward side attenuator by the forward side adjusting means from the signal detected by the forward side detecting means. The output of the quadrature demodulator within the preamble period after completion of the adjustment of the gain on the forward side of the loop and the holding process of holding the adjustment value of this gain adjustment process in the data transmission section following the preamble period of the transmission slot. Is fed back to the input of the quadrature modulator, And a return side gain adjusting step of adjusting the return side attenuator by the return side adjusting means from the signal detected by the side detecting means, and transmitting the adjustment value of the return side gain adjusting step to the preamble period of the transmission slot. It is characterized by using a Cartesian loop by holding it in a section.

[0009]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a gain control device and a gain control method for a linearizer according to the present invention will be described in detail with reference to the accompanying drawings. 1 to 3, there is shown an embodiment of a linearizer gain control device of the present invention. 1 to 3 are circuit configuration block diagrams of the present embodiment, and FIGS. 2 and 3 are diagrams showing variations based on FIG.

The linearizer gain control apparatus according to the present embodiment comprises an open loop forward side circuit section, a forward side loop circuit section, a return side circuit section forming a loop, and a local oscillation circuit section.

The forward side circuit section of the above circuit configuration section comprises a quadrature modulator 1, a forward side attenuator 2 and a power amplifier (PA) 3. The forward side loop circuit unit is composed of the forward side detecting means 4, the forward side adjusting means 6, and the output control circuit 5. The return side circuit section includes a return side attenuator 7, a return side detecting means 8, a return side adjusting means 9, and a quadrature demodulator 1.
0. The local oscillation circuit unit includes a local oscillation circuit 11 and a phase shifter 12.

The quadrature modulator 1 constituting the above-mentioned circuit on the forward side transmits the local signal at the beginning of the transmission slot,
It is a modulator that performs quadrature modulation with a baseband waveform having an unmodulated wave (hereinafter also referred to as a preamble) and outputs a modulated signal. The forward attenuator 2 is an attenuator that changes the level of the modulation signal output by the quadrature modulator 1. The power amplifier (PA) 3 is an amplifier that amplifies and outputs the modulated signal whose signal level is adjusted to a predetermined value by the forward attenuator 2.

The forward side detecting means 4 constituting the forward side loop circuit section is a detector for detecting the gain of the power amplifier 3 constituting the forward side circuit section. The output control circuit 5 is a control circuit that controls the gain so that the gain control device of the present linearizer obtains several transmission levels. The control by the output control circuit 5 is executed via the forward side adjusting means 6. The forward side adjusting means 6 is an adjusting circuit that adjusts the forward side attenuator 2 so that the difference between the signal detected by the forward side detecting means 4 and a preset value becomes zero. This adjustment is executed under the control of the output control circuit 5.

The return-side attenuator 7 which constitutes the return-side circuit section is an attenuator which makes the input signal level of the quadrature demodulator 10 variable. The return side detection means 8 is a detector that detects the gain of the quadrature demodulator 10. The return side adjusting means 9 is an adjusting circuit that adjusts the return side attenuator 7 so that the difference between the detection value detected by the return side detecting means 8 and a preset setting value becomes zero. The quadrature demodulator 10 is a demodulator that quadrature demodulates the signal amplified by the power amplifier 3 with a local signal. The signal demodulated by the quadrature demodulator 10 is fed back to the input section of the quadrature modulator 1.

The local oscillation circuit 11 which constitutes the local oscillation circuit section is an oscillator which generates a local signal. The phase shifter 12 is a circuit that outputs a signal for controlling the phase of the signal demodulated by the quadrature demodulator 10.

In the gain control device for the linearizer of this embodiment, the quadrature modulator 1, the forward attenuator 2 and the power amplifier (PA) 3 constitute an open loop circuit unit. The forward-side detection means 4 that constitutes the forward-side loop circuit unit includes the power amplifier 3
Output is detected and the gain is adjusted by the forward attenuator (ATT) 2 based on the detected value. Further, the return-side attenuator 7 adjusts the gain of the return-side circuit portion forming the feedback loop.

In the linearizer gain control device of the present embodiment configured as described above, in the preamble period, the forward side detecting means 4 outputs the output of the power amplifier 3 as the gain on the forward side of the loop formed in the open loop. To detect. The detection value detected by the forward side detection means 4 is compared with a predetermined set value which is set in advance.
The attenuation factor of the forward attenuator 2 is adjusted by the forward adjusting means 6 so that the difference between these values becomes zero. The output control circuit 5 controls this adjustment. The open loop forward side circuit section and the forward side loop circuit section automatically control the data transmission period to a predetermined gain so as to hold the adjusted value.

After the adjustment of the gain of the circuit on the forward side is completed, the gain of the circuit on the return side forming the loop is automatically controlled with the loop closed within the preamble period. In this automatic control, the return side detecting means 8 detects the input of the quadrature demodulator 10, and the return side adjusting means 9 returns so that the difference between the detected value and a preset value becomes zero. It is performed by adjusting the side attenuator 7.

Also, when the transmission level is controlled by the output control circuit 5 in several stages, the return-side attenuator 7 is adjusted so that the input level of the quadrature demodulator 10 becomes constant. As a result, the gain of the entire loop during the modulated signal transmission period can hold the adjusted predetermined value.

FIG. 2 is a circuit configuration block diagram showing a first modification. The linearizer gain control device of the first modification is different from the above-described embodiment in the connection destination of the input signal of the return-side detection means 8 that constitutes the return-side circuit portion. That is, the axis signal I that is output from the quadrature demodulator 10 on the loop return side and that is a non-modulated signal is used as an input signal. Other connections and control procedures are the same as those in the above embodiment.

In the above embodiment based on the circuit configuration of FIG. 1, since the input level of the quadrature demodulator is detected, variations in the quadrature demodulator 10 cannot be corrected. The frequency characteristics and temperature characteristics of 10 can be corrected.

FIG. 3 is a circuit configuration block diagram showing a second modification. In the linearizer gain control device of the second modification, the connection destination of the input signal of the return side detection means 8 is different from that of the above embodiment. That is, the output signals I and Q from the quadrature demodulator 10 on the loop return side are used as input signals. Other connections and control procedures are the same as those in the above embodiment.

In this modification 2, in addition to the effects of modification 1,
Since both the signals I and Q are viewed, there is an advantage that the accuracy of the phase shifter 12 hardly affects the gain adjustment. In the first modified example based on the circuit configuration of FIG. 2, only the axis to which the non-modulated signal is input is detected during the preamble transmission period, and therefore the phase shift of the axes I and Q appears in the adjustment due to the accuracy of the phase shifter. there is a possibility.

According to the gain control device and the gain control method for the linearizer of the above-described embodiment or modification, the gains on the forward side and the return side of the loop of the linearizer using the Cartesian loop are automatically controlled, respectively. It controls the gain of the entire loop. Therefore, only one attenuator on the return side is required regardless of the transmission level. Further, the initial setting of the device at the time of production can be adjusted only once. Further, it is possible to prevent the transmission output from varying due to the frequency change and the temperature change.

Although the above-described embodiment is an example of a preferred embodiment of the present invention, the present invention is not limited to this, and various modifications can be made without departing from the gist of the present invention.

[0026]

As is clear from the above description, the gain control device and the gain adjustment method for the linearizer of the present invention are:
A quadrature-modulated modulation signal is output, and the modulation signal whose level has been adjusted to a predetermined value is amplified. In this amplification, the gain of the output of the power amplifier is detected, and the forward attenuator is adjusted to a preset value. Further, the output signal is detected, the detected signal is quadrature demodulated by the local signal, and the demodulated signal is fed back to the input section of the quadrature modulator. The signal fed back is detected and the level of the attenuator on the return side is adjusted.

Therefore, the gain control using the Cartesian loop enables highly stable control, and only one attenuator on the return side is required regardless of the transmission level. As a result, the circuit can be made small. Furthermore, it is easy to change the transmission level and the frequency, and the loop gain can be kept constant regardless of temperature changes. Further, the initial setting of the device at the time of production need only be adjusted once, and the transmission level can be finely controlled.

[Brief description of drawings]

FIG. 1 is a circuit configuration block diagram showing an embodiment of a gain control device for a linearizer of the present invention.

FIG. 2 is a circuit configuration block diagram showing a first modification.

FIG. 3 is a circuit configuration block diagram showing a second modification.

FIG. 4 is a circuit configuration block diagram showing a gain control device for a conventional linearizer.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Quadrature modulator 2 Forward side attenuator 3 Power amplifier 4 Forward side detecting means 5 Output control circuit 6 Forward side adjusting means 7 Return side attenuator 8 Return side detecting means 9 Return side adjusting means 10 Quadrature demodulator 11 Local oscillation circuit 12 Phase shifter

Claims (4)

[Claims] 1. A quadrature modulator which outputs a modulation signal obtained by quadrature modulating a local signal with a baseband waveform having a preamble at the beginning of a transmission slot, a forward attenuator for adjusting the level of the modulation signal, and a level by the forward attenuator. , A forward side circuit section having a power amplifier for amplifying the modulated signal adjusted to a predetermined value, a forward side detecting means for detecting a gain of the forward side circuit section, and a detection value detected by the forward side detecting means. And a preset setting value, the forward side adjusting means for adjusting the forward side attenuator, an output control circuit for controlling the adjusting operation of the forward side adjusting means, and a forward side loop circuit section, which is amplified by the power amplifier. The modulated signal detected by the A return-side attenuator for adjusting the bell, a quadrature demodulator for quadrature demodulating the detection signal adjusted by the return-side attenuator by the local signal and feeding the demodulated signal back to the input unit of the quadrature modulator, and the fed-back signal A return-side circuit unit having a return-side detecting unit for detecting, a return-side adjusting unit for controlling a level adjusting operation of the return-side attenuator based on the detected value and a preset setting value. The forward side loop circuit section and the return side circuit section each automatically control the gain, and the signal level of the modulation signal output by the forward side circuit section is automatically controlled. Gain control device for linearizer. 2. The gain control device for a linearizer according to claim 1, wherein the signal fed back is detected by an input unit for inputting a detection signal adjusted by the return-side attenuator to the quadrature demodulator. 3. The signal to be fed back is a signal after quadrature demodulation of the quadrature demodulator, which is fed back to the input unit of the quadrature modulator.
Gain control device for linearizer described 4. A gain control method for a linearizer in a digital radio apparatus for performing burst transmission, wherein, in a preamble period at the beginning of a transmission slot, first, an output of a quadrature demodulator is not fed back to an input of a quadrature modulator, A gain adjustment step of adjusting the gain on the forward side of the loop by adjusting the forward side attenuator by the forward side adjustment means from the signal detected by the forward side detection means, and the adjustment value of the gain adjustment step of the transmission slot. The output of the quadrature demodulator is fed back to the input of the quadrature modulator within the preamble period after the holding process of holding the data transmission period following the preamble period and the adjustment of the gain on the forward side of the loop is completed, and the loop is closed. Adjust the return side from the signal detected by the return side detection means A return side gain adjusting step of adjusting the return side attenuator by means, and holding the adjustment value of the return side gain adjusting step in the data transmission section following the preamble period of the transmission slot, thereby using the Cartesian loop. A gain control method for a linearizer characterized in that