JP2002076949A - Transmission power controlling apparatus and method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a transmission power control apparatus and method in which an intermediate amplifier and an attenuator are controlled to maintain the desired transmission output power at the time of switching the amplifying lines of two systems within a mobile terminal. SOLUTION: A transmission power control apparatus (40) for receiving a transmission input signal to output a transmission output signal through variable gain amplifying process comprises a variable gain amplifier (11) for providing an output by receiving a transmission input signal and then amplifying the input signal based on the controlled gain value, a power amplifier (12) for outputting a signal by receiving an output signal from the variable gain amplifier and then amplifying the signal, distributor (42) for distributing an output signal from the variable gain amplifier to the power amplifier and a bypass route (28) for the power distribution, switch (47) for selectively switching an output signal from the power amplifier and an output signal from the bypass route to send the transmission output signal, and a power measuring circuit (48) for measuring, at least before the switching operation, both powers of an output signal from the power amplifier and an output signal from the bypass route and then outputting the result of measurement. Consequently, a value of gain is controlled to set the transmission output signal to the desired value even at the time of switching operation on the basis of the result of measurement from the power measuring circuit.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmission power control apparatus and method in a mobile terminal such as a portable telephone system or a commercial radio system, and more particularly to a high output power selectable by a desired output power for the purpose of reducing current consumption. The present invention relates to a transmission power control apparatus and method for controlling an intermediate amplifying / attenuator so that a desired transmission output power can be maintained even when switching between two-system amplification lines of an amplifier for low power and an amplifier for low power.

[0002]

BACKGROUND OF THE INVENTION In a system for communicating between a base station and a mobile station, such as a mobile phone system or a commercial radio system, useless power consumption of the mobile station is suppressed and the quality of wireless communication between the base station and the mobile station is reduced. In order to maintain the power, the power received by the base station is kept constant, and the transmission power from the mobile station is controlled to be the minimum required power. For example, in a CDMA system, transmission power from a mobile station is finely controlled every 1 dB in order to keep power received by a base station constant. The base station transmits a power control signal to the mobile station that transmitted the power every 625 μsec based on the magnitude of the power received by the base station. The power control signal is composed of, for example, 2 bits and includes control contents such as "increase the transmission power of the mobile station by 1 dB", "decrease the transmission power by 1 dB", and "maintain". For example, 5
Even if it is necessary to increase the dB, a 5 dB increase is achieved by increasing the frequency by 1 dB five times and increasing monotonically.
Similarly, when decreasing, it is monotonously decreased. On the mobile station side, the transmission power is 1 dB over a wide range of 70 dB up and down.
It is monotonically increasing and decreasing. FIG. 1 shows an example of a transmission power control device in a mobile station that performs such power control.

In a transmission power control device 10 shown in FIG. 1, a variable gain amplifier 11 receives and amplifies a transmission signal. Its amplification factor or gain G _X is varied in accordance with a gain control signal 1 from the processor 15. Processor 15
Forms a gain control signal 1 based on a power control signal wirelessly transmitted from a base station. Variable gain amplifier 11
Is sent to a power amplifier (PA) 12, which has a constant gain (= _GPI ) and is a final amplification stage, where it is further amplified. Vdd and Vgg are power supplies constantly supplied to the power amplifier 12. A coupler combiner monitors the transmit power of the output from power amplifier. Coupler 14
In order to prevent the transmission power from being affected by the monitor, it is possible to extract only a small power, for example, about 1/100 of the transmission power. The output from the power amplifier 12 is protected from the load fluctuation of the antenna by the isolator 16, and the intermodulation distortion (Inter Modulati) generated by the external strong external mobile station signal and the own station transmission signal.
on Distortion) is prevented. The duplexer 18 is a filter for separating transmission / reception signals according to frequency so that one antenna 19 is shared by the transmission system and the reception system. For example, in a CDMA system, the transmission signal frequency ranges from 1920 to 1980 MHz, and the reception signal frequency ranges from 2110 to 2170 MHz. The output from the power amplifier 12 passes through the coupler coupler 14, the isolator 16, and the duplexer 18 and is radiated from the antenna 19 to the air.

In a mobile station having the configuration shown in FIG. 1, when the transmission power is controlled from the maximum power (for example, 0.8 W) to the minimum power (for example, 3 mW), when the power is small, the power efficiency is extremely reduced. This is because, in the configuration of FIG. 1, a constant current consumption flows to the power amplifier 12 even when the transmission power is small, so that the power consumption-to-transmission power ratio of the mobile device increases and the power efficiency deteriorates. I will. In particular, when performing class A or class AB operation to reduce the distortion of the power amplifier 12, since the bias current required for the maximum power transmission is always supplied to the power amplifier 12 during transmission, the transmission power is reduced. When there is no signal, the power efficiency is significantly deteriorated. Particularly in CDMA, since operation is performed with relatively low power for a long time, reduction in power efficiency at low power becomes a significant problem.

[0005] The transmission power control device 20 shown in FIG.
Is to solve the problem. If the power to be transmitted by the mobile station is greater than a predetermined bypass threshold, FIG.
Similarly, the output from the variable gain amplifier 11 is amplified by the power amplifier 12 and radiated from the antenna. On the other hand, when the power to be transmitted becomes lower than the predetermined bypass threshold, the output from the variable gain amplifier 11 is bypassed without passing through the power amplifier 12 (28) and radiated from the antenna. To achieve this, the changeover switches 22, 24, which operate in synchronization,
The output signal from the variable gain amplifier 11 can pass through the bypass 28. Further, at the time of bypass, by cutting off the power supplied to the power amplifier 12 by the switch 26, the power consumption of the power amplifier 12 can be reduced to almost zero, and the problem of the power consumption described above with reference to FIG. You.

However, the required output transmission power of the mobile station monotonically decreases by 1 dB (see 32 in FIG. 3), and when the bypass threshold 35 is divided, the power has been passed through the power amplifier 12 until now. Since the state is switched to the bypass state, amplification by the power amplifier 12 cannot be obtained. In order to maintain a smooth monotonous decrease (refer to 32-34 in FIG. 3) so that the power before switching becomes minus 1 dB, when the bypass threshold 35 is passed, the changeover switches 22 and 24 are switched to the bypass road side. suddenly the gain G _X of the variable gain amplifier 11, it is necessary to raised only ideal gain amount G _PI of the power amplifier 12. However, the actual gain of the power amplifier 12 fluctuates from an ideal value due to input power, temperature change, and the like, and it is difficult to accurately grasp the gain. When the actual gain G _PA of the power amplifier 12 is only delta = 2.5 dB from the ideal gain component G _PI small (G _PI = G _PA +
2.5 dB), there is a problem that the gain increased by the variable gain amplifier 11 after switching is too large, and the transmission power, which must be reduced by 1 dB, rather increases by 1.5 dB (see 36 in FIG. 3). ). Conversely, the required output transmission power of the mobile station monotonically increases by 1 dB (not shown). Is switched to a state in which the power amplifier 12 is turned on. To maintain a smooth monotonic increase so that the power before switching plus 1 dB, the bypass threshold 35
Switches 22 and 24 when power supply 1
The gain G _{X of the} variable gain amplifier 11 is switched at the same time as switching to the second side.
It is necessary to reduce only the ideal gain amount G _PI of the power amplifier 12 of the. In this case as well, when there is an offset between the actual gain component G _PA ideal gain amount G _PI of the power amplifier 12, the same problem as above arises.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a transmission power control apparatus and a transmission power control method which minimizes the adverse effect of the offset when switching between a power amplifier and a bypass path.

[0008]

4 and 5 show a block diagram of a transmission power control apparatus 40 according to an embodiment of the present invention. The same circuit elements as those in FIGS. 1 and 2 are denoted by the same reference numerals, and redundant description will be omitted.

In FIG. 4, the output from the variable gain amplifier 11 is divided by a distributor 42 at a ratio of, for example, 50%, and distributed to the power amplifier 12 and the bypass path 28, respectively. Other ratios may be used. In this embodiment, the bypass path 28 is shown as a simple wiring path. However, another amplifier or an attenuator having a different gain from the power amplifier 12 may be provided in the bypass path. When a transmission power larger than the bypass threshold is required, as shown in FIG.
Power is supplied to the power amplifier 12 by 6, and the output from the power amplifier 12 is coupled to the coupler 14 by the two-input three-output switch 47, monitored, and supplied to the antenna 19. The output from the bypass 28 is supplied to a power measuring circuit 48 and monitored. Power measurement circuit 48
Is a circuit for converting the monitored power into a DC voltage proportional to the power. A combination of a resistor and a diode, a variable gain amplifier monitor 51, a power amplifier monitor 52, a transmission power monitor 53, and each analog-to-digital converter 55
And is an available circuit.

When a transmission power much smaller than the bypass threshold is required, as shown in FIG. 5, the power supply to the power amplifier 12 is cut off by the switch 26, and the output from the power amplifier 12 is switched to the switch 47. Is connected to the power measuring circuit 48, and the output from the bypass path 28 is coupled to the coupler coupler 14 by the switch 47, monitored, and supplied to the antenna 19.

Here, a case where switching from large transmission power to small transmission power is considered. That is, this is the case where the state transitions from FIG. 4 to FIG. If the transmission power is required to be reduced in steps of 1 dB in accordance with a command from the base station, the required transmission output power of the mobile station is monotonously reduced by 1 dB by the attenuator 46 (see 62 in FIG. 6).
When dividing the bypass threshold 65, the power amplifier 1
2 is switched to a bypass state.
Immediately before switching, the output power of the coupler coupler 14 and the output power of the bypass path are monitored by the power measuring circuit 48, and the two powers are compared in the processor 45.
Power difference between both (ΔP = coupler coupler output power 62
Based on the bypass path output 64), the processor 45 controls the gain of the switched variable gain amplifier 11 so that the monotonous decrease is maintained after the switching. Or
The switching to the bypass path is suspended while the power difference ΔP is larger than 2 dB, for example. When ΔP falls within 1 to 2 dB, the power difference ΔP is obtained, and the gain of the variable gain amplifier 11 is changed by 1 dB from the immediately preceding value. -Set to be smaller by ΔP,
Switching to the bypass path 28 may be performed at the next timing. Alternatively, the attenuator 46 monotonically decreases the gain by 1 dB until the bypass threshold is approached to some extent.
The transmission output power may be monotonically reduced by controlling the gain of the variable gain amplifier 11 when the bypass threshold is approached to some extent. In this case, the comparison between the output power 62 of the coupler coupler 14 and the power of the power amplifier output power 66 may be performed 3 dB before the switching, and the three comparison values may be averaged. By doing so, even if the actual gain GPA of the power amplifier 12 _differs from the ideal gain _GPI , it is possible to maintain a monotonic decrease in the transmission output.

After switching to the bypass path, the power supply to the power amplifier 12 is not immediately shut off. This is to prepare for a case where the output from the command from the base station increases. When the transmission output falls below the PA on / off threshold 67 (for example, 3 dB before the bypass threshold), the power supply to the power amplifier 12 is shut off.

Next, a case where switching from small transmission power to large transmission power is considered. That is,
This is a case where the state transitions from FIG. 5 to FIG. If the increase in transmission power is continuously requested in 1 dB steps according to a command from the base station, the required output transmission power of the mobile station monotonically increases by 1 dB by the variable gain amplifier 11 (see 62 in FIG. 6). , PA on / off threshold value 67, power amplifier 12 is turned on and attenuated by attenuator 46. When the transmission output exceeds the bypass threshold value, the power is switched from the bypass path 28 to the power amplifier 12. Immediately before switching, the output power 62 of the coupler coupler 14 and the output power 66 of the power amplifier are monitored by the power measuring circuit 48, and the two powers are compared in the processor 45. The comparison is made 3dB before the switch,
Three comparison values may be averaged. The power difference between both (ΔP =
Based on the output power of the coupler coupler 62—the power amplifier output 66), the processor 45 controls the gain of the switched variable gain amplifier 11 (eg, the value immediately before the switch) so that the monotonic increase is maintained after the switch. 1 dB
+ ΔP), and the attenuation value of the attenuator 46 can be set to a desired value before switching. By doing so, the power amplifier 1
Even if the actual gain GPA of 2 _differs from the ideal gain _GPI , a monotonic increase in transmit power can be maintained.

It is necessary to provide a hysteresis so that the power for turning on / off the power of the power amplifier 12 is, for example, around +/- 3 dB of a predetermined switching power. The attenuator 46 needs the amount of attenuation of the gain of the power amplifier 12 + α.

[Brief description of the drawings]

FIG. 1 is a block diagram of a transmission power control device according to the related art.

FIG. 2 is a block diagram of a transmission power control device according to another related art.

FIG. 3 is a graph showing transmission power in the related art.

FIG. 4 is a block diagram of a transmission power control device according to an embodiment of the present invention, showing a state where a power amplifier side is used.

FIG. 5 is a block diagram of a transmission power control device according to an embodiment of the present invention, showing a state where a bypass road side is used.

FIG. 6 is a graph showing transmission power according to an embodiment of the present invention.

[Explanation of symbols]

 Reference Signs List 40 transmission power control device 11 variable gain amplifier 12 power amplifier 28 bypass path 42 distributor 47 switch 48 power measurement circuit 46 variable attenuator

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Hiroyoshi Kikuchi 3-20-1, Minamiazabu, Minato-ku, Tokyo Motorola Co., Ltd. F-term (reference) 5J100 AA02 AA26 BA01 BB15 BC01 BC06 CA28 CA29 DA07 FA01 5K060 BB00 CC04 DD04 HH06 LL01

Claims (6)

[Claims] 1. A transmission power control device (40) for receiving a transmission input signal and performing variable gain amplification to output a transmission output signal: receiving the transmission input signal, amplifying the output with a controlled gain value, and outputting the amplified signal. A variable gain amplifier (11); a power amplifier (12) for receiving and amplifying an output signal from the variable gain amplifier; and power distributing an output signal from the variable gain amplifier to the power amplifier and a bypass path (28). A distributor (42) that selectively switches between an output signal from the power amplifier and an output signal from the bypass path to generate the transmission output signal (47); at least before the switching, A power measuring circuit (48) for measuring both powers of an output signal from an amplifier and an output signal from the bypass path and outputting a measurement result; and the measurement result from the power measurement circuit And controlling the gain value so that the transmission output signal becomes a desired value even at the time of switching based on the transmission power control. 2. A transmission power control device (40) for receiving a transmission signal and variable-gain amplifying and outputting a transmission output signal, comprising:
A variable gain amplifier (11) that receives the transmission input signal, amplifies the output signal with a controlled gain value, and outputs the amplified signal; a variable attenuator (46) that attenuates the output signal from the variable gain amplifier with a controlled attenuation value and outputs the signal. A divider (42) for distributing the power of the output signal from the variable gain amplifier to the variable attenuator and the bypass path (28); a power amplifier (12) for amplifying and outputting the output signal from the variable attenuator. A switch (4) that selectively switches between an output signal from the power amplifier and an output signal from the bypass path to generate the transmission output signal.
7); at least before the switching, a power measurement circuit (4) that measures both powers of the output signal from the power amplifier and the output signal from the bypass path and outputs a measurement result.
8); and a transmission power control device, based on the measurement result from the power measurement circuit, controlling the attenuation value such that the transmission output signal has a desired value even at the time of switching. 3. The apparatus according to claim 1, wherein the measurement result is a value corresponding to a difference between an output signal from the power amplifier and an output signal from the bypass path. 4. A method for receiving a transmission input signal and performing variable gain amplification to output a transmission output signal: receiving the transmission input signal and amplifying the transmission input signal with a controlled gain value (11); Distributing the divided signal to a power amplifier (12) and a bypass line (28); further amplifying and outputting the divided signal in the power amplifier; and outputting from the power amplifier. Selectively switching between a signal and an output signal from said bypass path to said transmission output signal (47); at least before said switching, an output signal from said power amplifier and an output signal from said bypass path. Measuring both powers and outputting a measurement result (48); and based on the measurement result,
Controlling the gain value so that the transmission output signal has a desired value even at the time of switching. 5. A method of receiving a transmission input signal and performing variable gain amplification to output a transmission output signal: receiving the transmission input signal and amplifying the transmission input signal with a controlled gain value (11); Distributing power to the variable attenuator (46) and the bypass path (28); attenuating the distributed signal with a controlled attenuation value in the variable attenuator; power amplifier (12) amplifying and outputting the attenuated signal; selectively switching between an output signal from the power amplifier and an output signal from the bypass path to obtain the transmission output signal ( 47); at least immediately before the switching, measuring both the power of the output signal from the power amplifier and the output signal from the bypass path, and outputting the measurement result (4).
8); and controlling the attenuation value based on the measurement result so that the transmission output signal has a desired value even at the time of switching. 6. The method according to claim 4, wherein the measurement result is a value corresponding to a difference between an output signal from the power amplifier and an output signal from the bypass path.