Apparatus and method for controlling transmission power in a mobile communication system
First Claim
1. A transmission power controlling apparatus in a mobile communication system supporting a single FA (Frequency Allocation), comprising:
- a channel device group for generating an I (In phase) channel baseband signal and a Q (Quadrature phase) channel baseband signal from channel data;
a pulse shaping filter for pulse-shape-filtering the baseband signals;
a power controller for controlling the PAPRs (Peak-to-Average power Ratio) of the pulse-shape-filtered signals according to a threshold power required for linear power amplification; and
a frequency converter for upconverting the power-controlled signals to RF (Radio Frequency) signals and outputting the RF signals, wherein the power controller comprises;
a scale determiner for receiving original I and Q channel signals from the pulse shaping filter, measuring the instant power of the original I and Q channel signals at each sampling period, comparing the instant power with the threshold power, and determining scale values according to the comparison result;
a cancellation signal calculator for calculating target signals by multiplying the original I and Q channel signals by the scale values and calculating cancellation signals by subtracting the original I and Q channel signals from the target signals;
a signal delay for delaying the original I and Q channel signals by a time required for the operations of the cancellation signal calculator and the scale determiner and a summer for adding the delayed signals to the pulse-shape-filtered signals.
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Abstract
An apparatus and method for maximizing the efficiency of a power amplifier by reducing the PAPR of a BS in a mobile communication system. A power controller between I and Q channel pulse shaping filters and a frequency converter calculates cancellation signals for signal pulses that increase the PAPR at each sampling period, pulse-shape-filters cancellation signals at the highest levels among the cancellation signals, and adds the filtered cancellation signals to the original signals. Thus, spectral regrowth outside a signal frequency band is suppressed. In the case of a system supporting multiple frequency allocations, the PAPR is controlled for each FA according to its service class. Therefore, minimum system performance is ensured and power use efficiency is increased.
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Citations
32 Claims
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1. A transmission power controlling apparatus in a mobile communication system supporting a single FA (Frequency Allocation), comprising:
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a channel device group for generating an I (In phase) channel baseband signal and a Q (Quadrature phase) channel baseband signal from channel data;
a pulse shaping filter for pulse-shape-filtering the baseband signals;
a power controller for controlling the PAPRs (Peak-to-Average power Ratio) of the pulse-shape-filtered signals according to a threshold power required for linear power amplification; and
a frequency converter for upconverting the power-controlled signals to RF (Radio Frequency) signals and outputting the RF signals, wherein the power controller comprises; a scale determiner for receiving original I and Q channel signals from the pulse shaping filter, measuring the instant power of the original I and Q channel signals at each sampling period, comparing the instant power with the threshold power, and determining scale values according to the comparison result;
a cancellation signal calculator for calculating target signals by multiplying the original I and Q channel signals by the scale values and calculating cancellation signals by subtracting the original I and Q channel signals from the target signals;
a signal delay for delaying the original I and Q channel signals by a time required for the operations of the cancellation signal calculator and the scale determiner and a summer for adding the delayed signals to the pulse-shape-filtered signals. - View Dependent Claims (2, 3, 4, 5)
where Pth is the threshold power, Paverage is the average power of the mobile communication system, and backoff is the ratio of a maximum power required to achieve linear amplification to the average power.
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6. A method of controlling transmission power in a mobile communication system supporting a single FA (Frequency Allocation), comprising the steps of:
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generating an I (In phase) channel baseband signal and a Q (Quadrature phase) channel baseband signal from channel data;
pulse-shape-filtering the baseband signals;
controlling the PAPRs (Peak-to-Average power Ratio) of the pulse-shape-filtered signals according to a threshold power required for linear power amplification; and
upconverting the power-controlled signals to RE (Radio Frequency) signals and outputting the RE signals, wherein the PAPR controlling step further comprises the steps of; receiving original pulse-shape-filtered signals, measuring the instant power of the original pulse-shape-filtered signals at each sampling period, and determining scale values by comparing the instant power with a threshold power;
calculating target signals by multiplying the original signals by the scale values and calculating cancellation signals by subtracting the original signals from the target signals; and
combining the cancellation signals to the original pulse-shape-filtered signals. - View Dependent Claims (7, 8, 9, 10, 11)
where Pth is the threshold power, Paverage is the average power of the mobile communication system, and backoff is the ratio of a maximum power required to achieve linear amplification to the average power.
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12. A transmission power controlling apparatus in a mobile communication system supporting a plurality of FAs (Frequency Allocations), comprising:
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a plurality of channel device groups for generating I (In phase) channel baseband signals and Q (Quadrature phase) channel baseband signals from channel data for the FAs;
a plurality of pulse shaping filters connected to the channel device groups, for pulse-shape-filtering the FA baseband signals; and
an FA power controller for controlling the PAPRs (Peak-to-Average power Ratio) of the pulse-shape-filtered signals according to a threshold power required for linear power amplification, wherein the FA power controller comprises; a scale determiner for receiving original I and Q channel signals of the FAs from the pulse shaping filters, measuring the instant signal of the original I and Q channel signals at each sampling period, comparing the instant power with a threshold power, and determining scale values according to the comparison result;
a plurality of power controllers corresponding to the FAs, for controlling the PAPRs of the original FA signals using the scale values; and
a summer for summing the outputs of the power controllers. - View Dependent Claims (13, 14, 15, 16, 17, 18, 19, 20, 21)
where Pi(i=1, 2, . . . , N) is the instant power of an ith FA signal, Pth is the threshold power, and Si is a scale value for the ith FA.
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17. The transmission power controlling apparatus of claim 12, wherein if the plurality of FAs have different service classes, each of the scale values is determined by the following equation,
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i × P th ∑ i = 1 N ( α i P i ) where Si is the scale value of an ith FA (i=1, 2, . . . , N), α
i is a weighting factor assigned to the ith FA, Pth is the threshold power, and Pi is the instant power of the ith FA signal.
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18. The transmission power controlling apparatus of claim 12, wherein if the plurality of FAs have different service classes, each of the scale values is determined by the following equation,
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P i ≤ P th_i , then S i = 1 if P i 〉 P th_i , then S i = P th_i P i where Pi is the instant power (i=1, 2, . . . , N), Pth — i is a threshold power for the service class of an ith FA, and Si is a scale value for the ith FA signal.
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19. The transmission power controlling apparatus of claim 18, wherein if a FA signal having a higher service class than the ith FA signal has a scale value of 1, the threshold power of the ith FA signal is updated by adding the ith threshold power (Pth
— - i) to the remaining power from the threshold power of the FA of the higher service class.
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20. The transmission power controlling apparatus of claim 19, wherein the remaining power is the difference between the threshold power and the instant power of the FA signal of the higher service class.
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21. The transmission power controlling apparatus of claim 12, wherein the threshold power is determined by the following equation
Pth=average power(Paverage)×- 10(backoff/10)
where Pth is the threshold power, Paverage is the average power of the mobile communication system, and backoff is the ratio of a maximum power required to achieve linear amplification to the average power.
- 10(backoff/10)
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22. A method of controlling transmission power in a mobile communication system supporting a plurality of FAs (Frequency Allocations), comprising the steps of:
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generating I (In phase) channel baseband signals and Q (Quadrature phase) channel baseband signals from channel data for the FAs;
pulse-shape-filtering the FA baseband signals; and
controlling the PAPRs (Peak-to-Average power Ratio) of the pulse-shape-filtered signals according to a threshold power required for linear power amplification, and outputting the PAPR-controlled signals in an RF band, wherein the PAPR controlling step further comprises the steps of; receiving the original pulse-shape-filtered signals of each FA, measuring the instant power of the original pulse-shape-filtered signals at each sampling period, and determining a scale value for the FA by comparing the instant power with a threshold power;
controlling the PAPRs of the original FA signals using the scale value; and
combining the PAPR-controlled FA signals. - View Dependent Claims (23, 24, 25, 26, 27, 28, 29, 30, 31, 32)
where Pi(i=1, 2, . . . , N) is the instant power of an ith FA signal, Pth is the threshold power, and Si is a scale value for the ith FA.
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28. The method of claim 22, wherein if the plurality of FAs have different service classes, each of the scale values is determined by the following equation,
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i × P th ∑ i = 1 N ( α i P i ) where Si is the scale value of an ith FA (i=1, 2, . . . , N), α
i is a weighting factor assigned to the ith FA, Pth is the threshold power, and Pi is the instant power of the ith FA signal.
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29. The method of claim 22, wherein if the plurality of FAs have different service classes, each of the scale values is determined by the following equation,
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P i ≤ P th_i , then S i = 1 if P i 〉 P th_i , then S i = P th_i P i where Pi is the instant power (i=1, 2, . . . , N) of an ith FA, Pth — i is a threshold power for the service class of an ith FA, and Si is a scale value for the ith FA signal.
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30. The method of claim 29, wherein if an FA signal having a higher service class than the ith FA signal has a scale value of 1, the threshold power of the ith FA signal is updated by adding the ith threshold power (Pth
— - i) to the remaining power from the threshold power of the FA of the higher service class.
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31. The method of claim 30, wherein the remaining power is the difference between the threshold power and the instant power of the FA signal of the higher service class.
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32. The method of claim 22, wherein the threshold power is determined by the following equation
Pth=average power(Paverage)×- 10(backoff/10)
where Pth is the threshold power, Paverage is the average power of the mobile communication system, and backoff is the ratio of a maximum power required to achieve linear amplification to the average power.
- 10(backoff/10)
Specification