JP3662888B2 - Transmission power control apparatus and method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a transmission power control apparatus and method thereof, and more particularly to a transmission power control system having a function of protecting an output of a transmission apparatus in a CDMA (Code Division Multiple Access) communication system.
[0002]
[Prior art]
An example of a conventional transmission power control apparatus for overpower protection of a CDMA mobile communication radio system is shown in FIG. Referring to FIG. 11, the signal processor 2 multiplexes the I-phase and Q-phase signals of each channel subjected to the spread processing, and the amplitude limiter 6i that limits the amplitude of these multiplexed outputs. , 6q, roll-off filters 7i and 7q that satisfy the roll-off coefficient of the Nyquist theory corresponding to the operation system and attenuate harmonics, and a quadrature modulation unit 8 that performs quadrature modulation on I-phase and Q-phase baseband signals; The D / A converter 9 converts the orthogonally modulated baseband signal into an IF signal.
[0003]
The radio unit 3 also includes a frequency converter 10 that converts the IF signal input from the signal processing unit 2 into an RF signal, a variable amplifier 11 that varies the power of the RF signal, and an RF signal that is transmitted from the antenna 5. Is composed of a transmission amplifying device 12 that amplifies the signal to a specified power with a fixed gain.
[0004]
[Problems to be solved by the invention]
The conventional overpower protection circuit is configured by amplitude limiters 6i and 6q. In the CDMA system, transmission power control is performed for each channel, so the total transmission power of a signal obtained by multiplexing a plurality of channels is There is a possibility that the power exceeds the limit value of the transmission power of the transmission amplifier 12. In a transmission state exceeding the limit of the transmission power device 12, communication quality may be deteriorated due to distortion of the RF signal, or in the worst case, a failure of the transmission power device 12 or a circuit for protecting the failure may be stopped. As a result, the communication system may stop as a result.
[0005]
In the CDMA system, a plurality of channels are multiplexed, so that a large amount of instantaneous power is generated. For this reason, when instantaneous power is generated, the amplitude limiters 6i and 6q are limited to a certain limit value, thereby increasing the power consumption due to the instantaneous power and the adjacent channel leakage power resulting from distortion of the transmission amplifying device 12. The failure due to the deterioration of the intermodulation distortion characteristics and the input of instantaneous power to the transmission amplifier 12 is protected.
[0006]
Therefore, in the prior art, as shown in an example of the conventional modulation accuracy characteristic of FIG. 12, the modulation accuracy is excessively less than 2% so that the modulation accuracy does not deteriorate even when the amplitude limit is set. The current situation is that they are designed.
[0007]
It is an object of the present invention to degrade characteristics and failure due to distortion of a transmission amplifying device without degrading modulation accuracy at the time of occurrence of instantaneous power generated at the time of channel signal multiplexing or in an excessive output state of transmission power due to a system malfunction. It is to provide a transmission power control apparatus and method capable of appropriately protecting the transmission power.
[0008]
[Means for Solving the Problems]
A transmission power control apparatus according to the present invention includes a combining unit that combines transmission data of a plurality of channels that are orthogonal to each other for each phase, an amplitude limiting unit that limits the amplitude of the combined signal for each phase, and the amplitude limiting unit. A transmission power control apparatus in a transmission apparatus including orthogonal modulation means for orthogonally modulating an output and transmission power control means for transmitting the orthogonal modulation output by performing power control, wherein transmission power is calculated from amplitude information of the combined signal. Detecting means, and when the transmission power is equal to or greater than a first threshold, canceling the amplitude limitation of the amplitude limiting means and controlling the gain of the transmission power control means. In this state, the transmission power is Control means for controlling the amplitude limit of the amplitude limit means and the gain of the transmission power control means to return to an initial set value when the threshold value is less than the threshold value.
[0009]
Another transmission power control apparatus according to the present invention includes a combining unit that combines transmission data of a plurality of channels that are orthogonal to each other for each phase, an amplitude limiting unit that limits the amplitude of the combined signal for each phase, and the amplitude limiter. A transmission power control apparatus in a transmission apparatus including orthogonal modulation means for orthogonally modulating the output of the means and transmission power control means for transmitting the orthogonal modulation output by performing power control, wherein the transmission power control apparatus transmits from the amplitude information of the combined signal. A means for detecting power, and when the transmission power is greater than or equal to a predetermined threshold, the amplitude limit value of the amplitude limiter is variably controlled according to the transmission power, and at the same time, the gain control of the transmission power control means is controlled. And control means.
[0010]
A transmission power control method according to the present invention includes a combining unit that combines transmission data of a plurality of channels orthogonal to each other for each phase, an amplitude limiting unit that limits the amplitude of the combined signal for each phase, and the amplitude limiting unit. A transmission power control method in a transmission device including orthogonal modulation means for orthogonally modulating an output and transmission power control means for transmitting the orthogonal modulation output by performing power control, wherein transmission power is calculated from amplitude information of the combined signal. Detecting, and when the transmission power is greater than or equal to a first threshold, canceling the amplitude limitation of the amplitude limiting unit and controlling the gain of the transmission power control unit. In this state, the transmission power is And a control step for controlling the amplitude limiting of the amplitude limiting means and the gain of the transmission power control means to return to an initial set value when the threshold is less than the threshold value. To.
[0011]
Another transmission power control method according to the present invention includes a combining unit that combines transmission data of a plurality of channels that are orthogonal to each other for each phase, an amplitude limiting unit that limits the amplitude of the combined signal for each phase, and the amplitude limiter. A transmission power control method in a transmission apparatus including orthogonal modulation means for orthogonally modulating the output of the means and transmission power control means for transmitting the orthogonal modulation output by performing power control, wherein the transmission power is transmitted from amplitude information of the combined signal. A step of detecting power, and when the transmission power is equal to or greater than a predetermined threshold, the amplitude limit value of the amplitude limiter is variably controlled according to the transmission power, and at the same time, the gain control of the transmission power controller is controlled. And a control step.
[0012]
The operation of the present invention will be described. The transmission power is detected by the power detector from the amplitude information of the baseband signal output from the amplitude limiter, and the gain of the variable amplifier in the radio unit and the limit value of the amplitude limiter in the signal amplifier are controlled. Thus, protection of the transmission amplifier is realized.
[0013]
Specifically, the transmission power is detected from the amplitude information of the multiplexed composite signal, and when the transmission power is equal to or greater than the first threshold, the amplitude limitation of the amplitude limiting unit is released, and the transmission power control unit that is a variable amplifier Gain control is performed, and in this state, when the transmission power becomes less than the second threshold value, control is performed so that the amplitude limitation of the amplitude limiting unit and the gain of the transmission power control unit are returned to the initial setting values. As another example, when the transmission power is greater than or equal to a predetermined threshold, the amplitude limit value of the amplitude limiter is variably controlled according to the transmission power, and at the same time, the gain control of the transmission power control unit is controlled. Achieve the above objective.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a diagram showing an outline of a radio base station to which an embodiment of the present invention is applied. In FIG. 1, a radio base station 1 spreads and multiplexes data input from its host device, performs orthogonal modulation and outputs, and an intermediate frequency signal (hereinafter referred to as “frequency signal” input from the signal processing unit 2). The radio unit 3 that converts the frequency of the IF signal) into a high frequency (hereinafter referred to as an RF signal) used for system operation and outputs the signal, and signal processing from the transmission power value calculated from the amplitude value of the baseband signal of the signal processing unit 2 The control unit 4 includes an amplitude limit value of the unit 2 and a control unit 4 that controls the gain of the radio unit 3. Reference numeral 5 denotes an antenna.
[0015]
FIG. 2 is a block diagram showing details of each part of FIG. In FIG. 2, the signal processing unit 2 limits the instantaneous power generated by the multiplexing to the set limit value by multiplexing units 5i and 5q that multiplex each spread channel data for each I phase and Q phase. Amplitude limiting units 6i and 6q that guarantee an increase in power consumption due to instantaneous power and distortion of the transmission amplifier 12, and a roll-off filter 7i that satisfies the roll-off coefficient of the Nyquist theory corresponding to the operation system and attenuates harmonics 7q, an orthogonal modulation unit 8 that orthogonally modulates I-phase and Q-phase baseband signals, and a D / A conversion unit 9 that converts the orthogonally modulated baseband signals into IF signals.
[0016]
The radio unit 3 includes a frequency conversion unit 10 that converts an IF signal input from the signal processing unit 2 into an RF signal, a variable amplifier 11 that varies the power of the RF signal according to a control voltage from the control unit 4, and an antenna 5. In order to transmit, it is comprised from the transmission amplification apparatus 12 which amplifies RF signal to fixed electric power with fixed gain.
[0017]
The control unit 4 changes the gain of the variable amplifier 11 according to the power detection unit 13 that detects the power value transmitted from the antenna 5 from the amplitude information of the baseband signal input from the signal processing unit 3, The transmission power control unit 14 changes the limit values of the amplitude limiting units 6i and 6q, and the D / A conversion unit 15 converts the control data from the transmission power control unit 14 into a voltage value and outputs the voltage value to the variable amplifier 11. Is done.
[0018]
The operation of the present embodiment will be described with reference to FIGS. 3 is a diagram showing an example of data after spreading, FIG. 4 is a diagram showing an example of data after multiplexing, FIG. 5 is a diagram showing an example of data subjected to amplitude limitation, and FIG. 6 shows the operation of this embodiment. FIG. 7 is a diagram illustrating an example of characteristics of modulation accuracy and power consumption when the limit value is set and when the limit value is canceled.
[0019]
First, the signal processing unit 2 spreads data from the host device (not shown in FIG. 2 because it is not directly related to the present invention), and in the multiplexing units 5i and 5q, for each I phase and Q phase. Perform multiplexing. The data input to the multiplexing units 5i and 5q shown in FIG. 3 is multiplexed to be converted into a multiplexed signal shown in FIG. The amplitude limiters 6i and 6q output the shaded portion as a signal by limiting the instantaneous power generated in the multiplexed signal to the limit value indicated by the dotted line in FIG.
[0020]
Then, after passing through the roll-off filters 7i and 7q, the I / Q quadrature modulation is performed, and the D / A converter 8 converts the IF signal into an IF signal, thereby generating a CDMA modulation wave and the radio unit 3 is output.
[0021]
Next, the operation of the wireless unit 3 shown in FIG. 2 will be described. The radio unit 3 frequency-converts the IF signal output from the D / A conversion unit 9 of the signal processing unit 2 into an RF signal by the frequency conversion unit 10, and the variable amplifier 11 and the transmission amplification device 12 gain-controlled by the control unit 4. And is transmitted from the antenna 5 to each terminal.
[0022]
Next, the operation of the control unit 4 of FIG. 2 will be described with reference to the flowchart of FIG. The control unit 4 first detects the amplitude values of the I and Q phase baseband signals after the amplitude limiting units 6i and 6q in the power detection unit 13 (step A1), and the calculation formula √ (Ich ² + Qch ^2). ) (1)
An amplitude value is calculated from the value, and a difference [X dB] between the value obtained by converting the amplitude value into a log value and the actually transmitted power is corrected, and the transmission power A [dBm] is calculated as a transmission power A [ dBm] = 10 × log (amplitude value) + X dB (2)
Calculate according to
[0023]
This operation is performed an arbitrary number of times and the average is taken to obtain highly accurate transmission power (step A2). Next, the transmission power control unit 14 determines whether or not the transmission power A [dBm] is equal to or higher than Y [dBm]. If the transmission power A [dBm] is less than Y [dBm], data is captured again and the transmission power A [ If dBm] does not become Y [dBm] or more, this operation is repeated (step A3). This state is assumed to be a normal operation.
[0024]
Next, in the normal state, when the transmission power A [dBm] becomes Y [dBm] or more from the above power (step A3), the limit values of the amplitude limiters 6i and 6q are canceled as shown in FIG. It changes so that instantaneous electric power can pass as it is (step A4). Then, Y [dBm] −A [dBm] + G [dB] which is the following calculation formula (3)
(Where G = initial gain of variable amplifier 11)
In order to suppress the transmission power of the transmission amplifying device 12 to Y [dBm], the gain of the variable amplifier 11 is calculated and the control data is output to the D / A converter 15. It is converted into a voltage value by the D / A converter 15 and the gain of the variable amplifier 11 is changed (step A5). A state in which the transmission power is suppressed by the variable amplifier 11 is defined as an overoutput state.
[0025]
Again, the amplitude value of the baseband signal is taken in and the transmission power is calculated (steps A6 and A7). If the power is in a state equal to or higher than Z [dBm] (step A8), the gain of the variable amplifier 11 is changed (step A5) as described above, and this operation is repeated.
[0026]
Next, when the transmission power A [dBm] is less than Z [dBm] in the overpower state (step A8), the limit values of the amplitude limiters 6i and 6q and the gain of the variable amplifier 11 are returned to the initial values. (Steps A9 and A10), the process returns to taking in amplitude values (Step A1).
[0027]
In steps A3 and A8 of the above operation, since a difference is made in the power for switching the operation state, the continuous switching operation does not occur, so that deterioration in communication quality of the system can be suppressed. Control of the limit values of the amplitude limiters 6i and 6q in steps A4 and A9 will be described with reference to FIG. FIG. 7 is a diagram showing an example of the characteristics of modulation accuracy and adjacent channel leakage power when the limit value is set and when the limit value is canceled. When the limit value is set (normal state), the higher the transmission power is, the more limited the amplitude is limited by the amplitude limiters 6i and 6q, so that the modulation accuracy is deteriorated. If it is 46 [dBm] or more, the modulation accuracy is 17.5 [%] or more defined by 3GPP, and the specified value is divided, so the communication quality deteriorates.
[0028]
Therefore, the modulation accuracy is improved to 5 [%] by canceling the amplitude limitation. However, the adjacent channel leakage power deteriorates from 52 [dB] to 46 [dB], but the adjacent channel leakage power defined by 3GPP satisfies 45 [dB] or more, thereby preventing the communication quality from deteriorating. It becomes possible to do. As described above, control is performed while achieving a trade-off between adjacent channel leakage power and modulation accuracy. In this case, the standard points are stored and the control is performed dynamically.
[0029]
Hereinafter, a specific example of the overoutput operation according to this embodiment will be described with reference to FIGS. As the characteristics of each block, the initial gain (G [dB]) of the variable amplifier 11 is 10 [dB], and the correction value (X [dB]) of the difference from the actual transmission power of the power detector 13 is 20 [dB]. The switching power (Y [dBm]) from the normal state to the overpower state is 45 [dBm], and the switching power from the overpower state to the normal state (Z [dBm]) is 43 [dBm].
[0030]
First, in the normal state, when the average amplitude value of the baseband signal is “100” for both the I phase and the Q phase, the power detection unit 13 calculates the transmission power as 41.5 [dBm] from Equation (1). (Steps A1, A2). Since this electric power is 45 [dBm] or less, the process returns to signal capture again (step A3).
[0031]
Next, when the average amplitude value of the baseband signal fluctuates to “300” for both the I phase and the Q phase, the transmission power 46.3 [dBm] is detected by the power detection unit 13 (steps A1 and A2). Since it is 45 [dBm] or more (step A3), the limit values of the amplitude limiters 6i and 6q are canceled (step A4). Further, from the calculation formula (3), the gain of the variable amplifier 11 is set to the control voltage from the D / A converter 15 so as to be 8.7 [dB] (step A5). And it switches to an overoutput state.
[0032]
Next, when the average amplitude value of the baseband signal fluctuates to “400” for both the I phase and the Q phase, the transmission power 47.5 [dBm] is detected (steps A6 and A7), and the transmission power is 43 [dBm]. ] (Step A8), the control voltage is canceled by the D / A converter 15 so that the gain of the variable amplifier 11 becomes 7.5 [dB] from the calculation formula (3). Is output (step A5).
[0033]
Next, when the average amplitude value of the baseband signal fluctuates to “120” for both the I phase and the Q phase, the transmission power 42.3 [dBm] is detected (steps A6 and A7), and the transmission power is 43 [dBm]. ] (Step A8), the control value and the gain of the variable amplifier 11 are returned to the initial values (steps A9 and A10). And it switches to a normal state.
[0034]
FIG. 8 is a block diagram showing the configuration of another embodiment of the present invention, and the same parts as those in FIG. As shown in FIG. 8, in this embodiment, the memory 16 is provided in the control unit 4, and the other configuration is the same as the example of FIG. FIG. 9 is a flowchart showing the operation, and FIG. 10 is a graph showing a limit value setting table of the amplitude limiters 6i and 6q in the memory 16 shown in the figure. In another embodiment of the present invention, the deterioration of the modulation accuracy is suppressed by dynamically changing the limit values of the amplitude limiters 6i and 6q.
[0035]
The control unit 4 first detects the amplitude values of the I-phase and Q-phase baseband signals after the amplitude limiting units 6i and 6q in the power detection unit 13 (step A1 in FIG. 9), and is the same as in the previous embodiment. Next, the transmission power is obtained (step A2).
[0036]
Next, the transmission power control unit 14 determines whether or not the transmission power A [dBm] is equal to or higher than Y [dBm]. If the transmission power A is less than Y [dBm], the limit value of the amplitude limiting unit, the variable amplifier 11 The gain is initialized, the amplitude value is detected again, and this operation is repeated unless the transmission power A [dBm] becomes Y [dBm] or more (step A3).
[0037]
Next, when the transmission power A [dBm] is equal to or higher than Y [dBm] from the above power, the limit value corresponding to the detected power of the amplitude limiters 6i and 6q is read from the table in the memory 16 and set. (Step A4). Thereafter, the gain of the variable amplifier 11 is calculated and the control data is output to the D / A converter 15 in order to suppress the transmission power of the transmission amplifying device 12 to Y [dBm] from the equation (1) (step A5). Returning to step A6 again, the above operation is repeated.
[0038]
By using the table in the memory 16, high-speed transmission power control is possible, and the instantaneous power to be passed can be set to any power by the table in the memory 16, so that the trade-off between adjacent channel leakage power and modulation accuracy can be achieved. It is possible to control while turning off. In this case, the standard points are stored and controlled dynamically with a table.
[0039]
【The invention's effect】
The first effect of the present invention is to protect the transmission amplifier from distortion and failure, and as a result, it is possible to prevent the communication system from being stopped. The reason is that the transmission power is detected, and the output of the transmission power amplifying apparatus can be suppressed to a certain level using a variable amplifier.
[0040]
The second effect is that communication quality deterioration can be prevented. The reason for this is that in the normal transmission power state, the amplitude is limited and the instantaneous power is suppressed to suppress an increase in power consumption due to the instantaneous power, and the adjacent channel leakage power and intermodulation due to distortion of the transmission amplifier are also suppressed. Degradation of modulation characteristics is prevented by preventing the distortion characteristics from deteriorating and suppressing the output power of the transmission amplifying device to a constant power with a variable amplifier in the overpowered state of the transmission power and releasing the limit value of the amplitude limiter. This is because it is possible to prevent deterioration in communication quality by preventing distortion of the transmission amplifier.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a schematic configuration of an embodiment of the present invention.
FIG. 2 is a block diagram showing details of the configuration of an embodiment of the present invention.
FIG. 3 is a diagram illustrating an example of data after diffusion of data input from a higher-level device.
FIG. 4 is a diagram showing an example of data after multiplexing.
FIG. 5 is a diagram showing an example of data subjected to amplitude limitation.
FIG. 6 is a flowchart showing the operation of one embodiment of the present invention.
FIG. 7 is a graph showing an example of modulation accuracy and adjacent channel leakage power with respect to a limit value of an amplitude limiter.
FIG. 8 is a block diagram showing a configuration of another embodiment of the present invention.
FIG. 9 is a flowchart showing the operation of another embodiment of the present invention.
FIG. 10 is a graph showing a table in a memory according to another embodiment of the present invention.
FIG. 11 is a block diagram showing a conventional configuration.
FIG. 12 is a graph showing an example of modulation accuracy and adjacent channel leakage power with respect to a limit value of a conventional amplitude limiter.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Radio base station 2 Signal processing part 3 Radio | wireless part 4 Control part 5 Multiplexing part 6 Amplitude limiting part 7 Roll-off filter 8 Orthogonal modulation part 9, 15 D / A conversion part 10 Frequency conversion part 11 Variable amplification part 12 Transmission amplification apparatus 13 Amplitude value calculation (power detection) unit 14 Transmission power control unit 16 Memory

Claims (12)

Combining means for combining transmission data orthogonal to each other for each phase for each phase, amplitude limiting means for limiting the amplitude of the combined signal for each phase, and orthogonal modulating means for orthogonally modulating the output of the amplitude limiting means; A transmission power control device in a transmission device including transmission power control means for transmitting the orthogonal modulation output by performing power control,
Means for detecting transmission power from amplitude information of the combined signal;
When the transmission power is equal to or greater than the first threshold, the amplitude limitation of the amplitude limiting unit is canceled and the gain control of the transmission power control unit is performed. In this state, the transmission power is less than the second threshold. Control means for controlling the amplitude limit of the amplitude limit means and the gain of the transmission power control means to return to the initial set value when
A transmission power control apparatus comprising: The transmission power control apparatus according to claim 1, wherein the first threshold value and the second threshold value are set to different values. The transmission power control apparatus according to claim 1 or 2, wherein the control means performs gain control of the transmission power control means so that the transmission power becomes constant. Combining means for combining transmission data orthogonal to each other for each phase for each phase, amplitude limiting means for limiting the amplitude of the combined signal for each phase, and orthogonal modulating means for orthogonally modulating the output of the amplitude limiting means; A transmission power control device in a transmission device including transmission power control means for transmitting the orthogonal modulation output by performing power control,
Means for detecting transmission power from amplitude information of the combined signal;
Control means for variably controlling the amplitude limit value of the amplitude limiting means according to the transmission power when the transmission power is equal to or greater than a predetermined threshold, and at the same time, controlling the gain control of the transmission power control means;
A transmission power control apparatus comprising: 5. The transmission power control apparatus according to claim 4, wherein the control means controls the amplitude limit value of the amplitude limit means while referring to a predetermined table. 6. The transmission power control apparatus according to claim 1, wherein the transmission data is CDMA communication system data. A CDMA transmission apparatus comprising the transmission power control apparatus according to claim 1. Combining means for combining transmission data orthogonal to each other for each phase for each phase, amplitude limiting means for limiting the amplitude of the combined signal for each phase, and orthogonal modulating means for orthogonally modulating the output of the amplitude limiting means; A transmission power control method in a transmission device including transmission power control means for transmitting the orthogonal modulation output by performing power control,
Detecting transmission power from amplitude information of the combined signal;
When the transmission power is equal to or greater than the first threshold, the amplitude limitation of the amplitude limiting unit is canceled and the gain control of the transmission power control unit is performed. In this state, the transmission power is less than the second threshold. And a control step of controlling the amplitude limiting of the amplitude limiting means and the gain of the transmission power control means to return to an initial set value in the event of a failure. 9. The transmission power control method according to claim 8, wherein the first threshold value and the second threshold value are set to different values. The transmission power control method according to claim 8 or 9, wherein the control step performs gain control of the transmission power control means so that transmission power becomes constant. Combining means for combining transmission data orthogonal to each other for each phase for each phase, amplitude limiting means for limiting the amplitude of the combined signal for each phase, and orthogonal modulating means for orthogonally modulating the output of the amplitude limiting means; A transmission power control method in a transmission device including transmission power control means for performing power control and transmitting the quadrature modulation output,
Detecting transmission power from amplitude information of the combined signal;
A control step for variably controlling the amplitude limit value of the amplitude limiter according to the transmission power when the transmission power is equal to or greater than a predetermined threshold, and at the same time controlling the gain control of the transmission power control unit;
Including a transmission power control method. 12. The transmission power control method according to claim 8, wherein the transmission data is data of a CDMA communication system.

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