RU98106238A - METHOD FOR MANAGING REAL POWER OF TRANSFER OF A BASE STATION IN A CELLULAR COMMUNICATION SYSTEM AND A DEVICE FOR ITS IMPLEMENTATION - Google Patents

Claims (1)

1. A device for controlling the power of the final output signal w _{O the} base station in a cellular communication system, while the specified base station having a gain of the monitored transmit power y 'and the radio frequency transmission signal w provides communication over multiple channels, and the specified device contains many channel elements for calculating the set of expected powers, each of the specified set of expected powers corresponding to one of the specified many channels; a base station transceiver system controller (BSCPS) for generating a desired output power y _{d of the} indicated base station, wherein said BSCPS is based on the specified set of expected powers; a transmit power detector for measuring a final transmit power of a specified final output signal w _O ; a radio frequency interface (RFI) board for generating a specified gain of the monitored transmit power y ′ by processing the specified final transmit power and the specified desired output power y _d to obtain a control input signal u, and the specified RFI contains a transmission filter for filtering the specified control input signal u, to obtain the specified gain of the monitored transmission power y '; and an amplification unit for processing said gain of the monitored transmit power y ′ generated by said RFR and said radio frequency transmission signal to obtain said final output signal w _O. 2. The device according to claim 1, characterized in that said final output signal w _O comprises a plurality of signals generated by said plurality of channel elements, in which at least one of said plurality of signals contains a sequence of frames, each frame containing the number of data symbols s _d and the number of power control symbols s _pc, wherein at least one of said plurality of channels has a traffic channel gain G _t, subchannel power gain control G _s, MSE channel data traffic awn r _t and the data rate power control subchannel r _s, and wherein for each of said plurality of channel elements generating a traffic channel signal said expected power P is calculated using equation
P = S _d (G _t ² xr _t ) / (s _d + s _pc ) + s _pc (G _s ² xr _s ) / (s _d + s _pc ). 3. The device according to claim 2, characterized in that each of said plurality of channel elements generating a traffic channel signal further comprises a first sampling device for selecting from each Mth frame a specified sequence of data frames for said corresponding traffic channel gain G _t , the corresponding corresponding gain of the power control subchannel G _s , the corresponding corresponding data rate of the traffic channel r _t and the indicated corresponding data rate power control channel r _s to obtain a plurality of samples of the expected power P _m . 4. The device according to claim 3, characterized in that each of said plurality of channel elements further comprises a filter for filtering said plurality of samples of expected power P _m to obtain a plurality of filtered samples of expected power

according to the following equation

where ϑ ₁ is the time constant;

the previous state of the specified filter;

the output signal of the specified filter corresponding to P _m . 5. The device according to claim 4, characterized in that each of the specified set of channel elements, in addition, contains a second sampling device and a time stamp unit for sampling each N-th sample of the specified output signal of the specified filter

to obtain a sequence of selected filtered expected powers

and assigning each of said sequences of selected filtered expected powers an indication of a time stamp. 6. The device according to p. 5, characterized in that said SKPS contains an adder for summing up the set of specified sequences of selected filtered expected powers

each of which corresponds to one, different from the others, from the specified set of channel elements and each of which corresponds to the indication of a common time stamp to obtain the specified desired output power y _d . 7. The device according to claim 2, characterized in that said RFR comprises a first sampling device for sampling said measured transmit power during each Mth frame to obtain a sequence of sampled measured values y _m . 8. The device according to claim 7, characterized in that the specified RFI, in addition, contains a first adder for subtracting the value of the cyclic change in attenuation A _TX , _BREATHING from each of these sequences of sampled measured values of y _m . 9. The device according to claim 7, characterized in that the specified RFI, in addition, contains a filter for filtering the specified sequence of sampled measured values y _m to obtain a sequence of filtered power samples

according to the following equation

where ϑ ₁ is the time constant;

the previous state of the specified filter;

the output signal of the specified filter corresponding to y _m . 10. The device according to claim 9, characterized in that the specified RFI, in addition, contains a second sampling device and a time stamp unit for sampling each N-th sample of the indicated sequence of filtered power samples

to obtain a sequence of selected filtered expected powers

and assigning each of said sequences of selected filtered expected powers an indication of a time stamp. 11. The device according to p. 10, characterized in that the specified RFI, in addition, contains a third comparator for subtracting the gain of the monitored transmit power y 'from the specified sequence of selective filtered expected powers

12. The device according to claim 11, characterized in that each of said plurality of channel elements generating a traffic channel signal further comprises a first sampling device for selecting from each Mth frame a specified sequence of data frames for said corresponding traffic channel gain G _t , the corresponding corresponding gain of the power control subchannel G _s , the corresponding corresponding data rate of the traffic channel r _t and the indicated corresponding data rate with power control channel r _s to obtain multiple samples of the expected power P _m . 13. The device according to p. 12, characterized in that each of the specified set of channel elements, in addition, contains a filter for filtering the specified set of samples of the expected power P _m to obtain a set of filtered samples of the expected power

according to the following equation

where ϑ ₁ is the time constant;

the previous state of the specified filter, and

the output signal of the specified filter corresponding to P _m . 14. The device according to item 13, wherein each of the specified set of channel elements, in addition, contains a second sampling device and a time stamp unit for sampling each N-th sample of the specified output signal of the specified filter

to obtain a sequence of selected filtered expected powers

and assigning each of said sequences of selected filtered expected powers an indication of a time stamp. 15. The device according to 14, characterized in that the specified SKPS contains an adder to summarize the set of specified sequences of selected filtered expected powers

each of which corresponds to one, different from the others, from the specified set of channel elements and each of which corresponds to the indication of a common time stamp to obtain the specified desired output power y _d . 16. The device according to p. 15, characterized in that the specified RFR, in addition, contains a calibration adder for adding the calibration constant A _{TX, LOSS} to the specified desired output power y _d , in which the specified calibration constant A _{TX, LOSS} reflects the loss between the point where said transmit power detector measures said final transmit power, and an antenna for transmitting said final output signal w _O.  17. The device according to clause 16, wherein said amplification unit comprises a variable gain amplifier unit having a gain that depends on the specified gain of the monitored transmit power y 'and receives the specified radio frequency transmission signal w. 18. The device according to claim 1, characterized in that the amplification unit comprises a second adder for summing the transmit power ability indicator A _TX , _ANALOG , showing the maximum transmit power of the indicated base station, and the gain of the monitored transmit power y 'to obtain the adjusted coefficient gain of the monitored transmit power, a third adder to add the specified adjusted transmit power gain to the value of the cyclic attenuation A _TX , _{BREAT HING} to obtain a corrected transmit power gain with a cyclic attenuation, a variable gain amplifier unit having a gain depending on said adjusted transmit power gain with a cyclic attenuation, for receiving said radio frequency transmission signal w and providing a controlled signal amplitude, and a power amplifier with a large output power to amplify the specified signal with controlled amplitudes oh and receiving the specified final output signal w _O. 19. A method for controlling the power of the final output signal w _{O of a} base station in a cellular communication system, said base station having a gain of the monitored transmit power y ′, provides communication over a plurality of channels, comprising calculating a plurality of expected powers, each of the plurality of expected powers corresponding to one channel of said plurality of channels, summing said plurality of expected powers to generate a desired output y _d of said base hundred tion, measured said final output signal w _O to obtain a measured transmit power, comparing said desired output power y _d from said measured transmit power to obtain a control input u signal is filtered said control input u to obtain the gain of the transmit power tracking y ' , and adjust the power of the specified final output signal w _O in accordance with the specified gain of the monitored transmission power y '. 20. The method according to claim 19, characterized in that said final output signal w _O comprises a plurality of signals, wherein at least one of said plurality of signals contains a sequence of frames, each frame containing the number of data symbols s _d and the number of symbols power control s _pc, wherein at least one of said plurality of channels has a traffic gain factor G _t, the gain of the power control subchannel G _s, traffic data rate r _t and the data rate sous The power control channel r _s, and wherein for each of said plurality of channels corresponding to the traffic channel signal, said expected power P is calculated using equation
P = s _d (G _t ² xr _t ) / (s _d + s _pc ) + s _pc (G _s ² xr _s ) / (s _d + s _pc ). 21. The method according to claim 20, characterized in that, in addition, samples are taken from each Mth frame of the indicated sequence of data frames for the indicated corresponding traffic channel gain, G _t , the corresponding corresponding power control subchannel gain, G _s , corresponding to the corresponding speed transmitting data of the traffic channel r _t and said corresponding data rate of the power control subchannel r _s, and calculating the corresponding plurality of samples of the expected power P _m . 22. The method according to item 21, characterized in that they filter the specified set of samples of the expected power P _m to obtain a set of filtered samples of the expected power

according to the following equation

where ϑ ₁ is the time constant;

previous filtering result, and

filtering result corresponding to P _m . 23. The method according to item 22, wherein the sampling of each N-th sample from the specified set of filtered samples of the expected power

to obtain a sequence of selected filtered expected powers

and assign to each of the indicated sequences of selected filtered expected powers

timestamp indications. 24. The method according to p. 23, characterized in that summarize the set of these sequences of selected filtered expected power

each of which corresponds to one different from the indicated traffic channel signals and each of which corresponds to an indication of a common time stamp to obtain the indicated desired output power y _d . 25. The method according to claim 20, characterized in that the specified measured transmit power is sampled during each Mth frame to obtain a sequence of sampled measured values of y _m . 26. The method according A.25, characterized in that subtract the values of the cyclic change in attenuation A _TX , _BREATHING from each of these sequences of sampled measured values of y _m . 27. The method according A.25, characterized in that they filter the specified sequence of sampled measured values of y _m to obtain a sequence of filtered power samples

according to the following equation

where ϑ ₁ is the time constant;

previous filtering result;

filtering result corresponding to y _m . 28. The method according to item 27, wherein each N-th output signal of the specified sequence of filtered power samples is sampled

to obtain a sequence of selected filtered expected powers

and assigning to each of the indicated sequences of selected filtered expected powers an indication of a time stamp indicator. 29. The method according to p. 28, characterized in that they subtract the gain of the monitored transmit power y 'from the specified sequence of sample filtered expected powers

30. The method according to clause 29, characterized in that a sampling of a given sequence of data frames for a specified corresponding traffic channel gain G _t , a specified corresponding power control subchannel gain G _s , and a corresponding channel data rate is selected from each Mth frame traffic r _t and the corresponding corresponding data rate of the power control subchannel r _s and calculate the corresponding plurality of samples of the expected power P _m . 31. The method according to p. 30, characterized in that the filtering of the specified set of samples of the expected power P _m to obtain a set of filtered samples of the expected power

according to the following equation

where ϑ ₁ is the time constant;

previous filtering result, and

filtering result corresponding to P _m . 32. The method according to p. 31, characterized in that each N-th sample is selected from the specified set of filtered samples of the expected power

to obtain a sequence of selected filtered expected powers

and assign to each of the indicated sequences of selected filtered expected powers

time stamp indications. 33. The method according to p, characterized in that summarize the set of these sequences of selected filtered expected power

each of which corresponds to one different from the indicated traffic channel signals and each of which corresponds to an indication of a common time stamp to obtain the indicated desired output power y _d . 34. The method according to p. 33, characterized in that they add the calibration constant A _{TX, LOSS} to the specified desired output power y _d , while the specified calibration constant A _{TX, LOSS} reflects the loss between the point where the indicated transmit power is measured and the antenna for transmitting the specified final output signal w _O. 35. The method according to claim 19, characterized in that the addition of the transmit power ability indicator P _TX , _ANALOG showing the maximum possible transmit power of the indicated base station and the gain of the monitored transmit power y 'to obtain the adjusted gain of the monitored transmit power, and adding said corrected transmit power gain and a cyclic attenuation A _TX , _BREATHING to obtain a corrected gain transmit power with cyclic attenuation.