Abstract:
A wireless communication system, to control a peak power to an average power ratio because an amplifier characteristic of the wireless communication system include non-linear characteristic if input signal large the amplifier makes distortions. A wireless communication system comprises for suppressing a peak power to an average power ratio to process known signal like a pilot signal.

Description:
FIELD OF THE INVENTION 
   The present invention relates to a wireless communication system and wireless communication device that transmits and receives known signals such as pilot signals. The wireless communication system and wireless communication device suppresses the peak to average power ratio. 
   BACKGROUND OF THE INVENTION 
   Recent wireless communication systems have been utilizing code division multiplexing (CDM) and orthogonal frequency division multiplexing (OFDM). For example,  FIG. 12  shows an outline of a wireless communication system arranged with multiple base stations BS 1 , BS 2  connected to a network (the network not pictured in the drawing) and a mobile station MS. The mobile station MS communicates with the base stations BS 1 , BS 2  with a good reception condition depending upon the mobile station MS position. A CDM system is a multiplex system which spreads a frequency utilizing different spreading codes. CDM systems tend to suffer from a problem in that if the number of the spreading codes increases the peak power becomes larger than the average power. An OFDM system is a transmission system which transmits on multiple sub-carriers related with respect to orthogonal frequency position. OFDM systems tend to suffer from a problem in that if the sub-carrier&#39;s phase timing overlap the peak power becomes larger than the average power. 
   The base stations BS 1 , BS 2  and mobile station MS have a composition that includes a reception processing unit that demodulates and decodes signals received by an antenna and a transmission processing unit that transmits encoded and modulated signals from an antenna, and the transmission processing unit has a transmission amplifier that amplifies signals of wireless frequency. This transmission amplifier has an amplification characteristic which includes linear and non-linear characteristics. If an input signal amplitude is large, the transmission amplifier amplifies the input signal in a non-linear characteristic area therefore, the amplified output signal of the amplifier includes distortion. 
   Proposals to deal with such problems have been shown by Japanese laid open application 2000-106548 which is known prior art in CDM systems. 
   Moreover, Japanese laid open application H11-205276 is known prior art in OFDM systems of multiple sub-carriers. 
   Regarding the CDM and OFDM systems, if the transmission amplifier is built so as to amplify up to the peak power without distortion, there will be a problem of increasing cost of the amplifier. 
   Possible solutions to the above problems include the idea to suppress the peak and improve the peak to average power ratio (PAPR) by applying a system that provides a dummy code for peak suppression as in the above-described conventional CDM system, or a system that provides a subcarrier for peak suppression as in the OFDM system. However because a dummy code or non-information signal for PAPR suppression has a problem that the data information transmission efficiency is decreased. 
   SUMMARY OF THE INVENTION 
   The present invention, addresses the above previous problems controls the PAPR by making use of known signals or a channel that transmits known signals. 
   The present invention includes a wireless communication system having a multiplex unit and a transmitter. The multiplex unit multiplexes a signal by combining a processed signal with a data signal. The transmitter transmits the multiplexed signal The processed signal includes a known signal which is processed to suppress a peak power to an average power ratio. 
   The present invention further includes a wireless communication system having a reverse spread unit and a calculator. A reverse spread unit receives a transmitted signal which includes a known signal and a processed signal that shares a time domain a first known signal and a second known signal for suppressing a peak power to an average power ratio. The calculator calculates to compensate the second known signal in accordance with the first known signal. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is an explanatory diagram of the main parts of a first working example of this invention. 
       FIG. 2  is an explanatory diagram of first and second pilot signals on the transmission side. 
       FIG. 3  is an explanatory diagram of first and second pilot signals on the receiver side. 
       FIGS. 4(   a ) and  4 ( b ) are explanatory diagrams of the phase change of the pilot signal. 
       FIG. 5  is an explanatory diagram of the main parts of the reception unit of a wireless communication device. 
       FIG. 6  is an explanatory diagram of the main parts of the reception unit of a wireless communication device. 
       FIG. 7  is an explanatory diagram of the pattern of the first and second pilot signals. 
       FIGS. 8(A) and 8(B)  are explanatory diagrams of the pattern of the first and second pilot signals. 
       FIGS. 9(A) and 9(B)  are explanatory diagrams of the pattern of the first and second pilot signals. 
       FIG. 10  is an explanatory diagram of the pattern of the first and second pilot signals. 
       FIGS. 11(A) and 11(B)  are explanatory diagrams of the effects of a simulation. 
       FIG. 12  is a schematic explanatory diagram of a wireless communication system useful in explaining the present invention. 
   

   DETAILED DESCRIPTION 
   The wireless communication system of this invention has, in a wireless communication system that performs wireless communication using multiplexed signals that include data and known signals, a transmission unit that transmits together on the time axis the known signals and signals processed for suppressing the peak to average power ratio. 
   If the known signals are transmitted on at least a certain frequency, then the transmission unit transmits, without temporal overlap, known signals to be transmitted on the certain frequency and signals processed so as to be able to suppress the peak to average power ratio to be transmitted on the certain frequency. 
   If the known signals undergo spread processing using at least a certain spread code and are transmitted, then the transmission unit transmits, without temporal overlap, known signals to be spread by the certain spread code and transmitted, and signals processed so as to be able to suppress the peak to average power ratio to be spread by the certain spread code and transmitted. 
   In a wireless communication system that performs wireless communication using multiplexed signals that include data and known signals, a transmission-side device divides the known signals into a first known signal and a second known signal, rotates the known signals to a phase that allows the peak to average power ratio to be suppressed and makes them into a second signal, and transmits together on the time axis the second signal and an unmodified first known signal, and a reception-side device that has a means that receives the first known signal and the second signal and, based on the first known signal, restores the second signal to the original known signal. 
   Also a wireless communication device of this invention transmits and receives signals in which multiple data and known signals are multiplexed, divides the known signals into a first known signal and a second known signal, makes the known signals into a second signal by processing either the phase or the amplitude or both so as to be able to suppress the peak to average power ratio based on signals by which the multiple data are multiplexed, and transmits together on the time axis the second signal and an unmodified first known signal of the known signals. 
   Also, it has a peak to average power ratio suppression signal calculation unit that processes and makes into the second signal either the phase or the amplitude, or both, of the known signals so as to be able to suppress the peak to average power ratio based on signals by which the multiple data are multiplexed, and a switching unit that inputs the known signals, with the unmodified first known signal, into the peak to average power ratio suppression signal calculation unit and controls the time period with the second signal. 
   Also, it has a control means that controls the switching unit so as to adaptively vary the time period of the combination on the time axis of the first known signal of the known signals unmodified and the second signal by which the known signals are processed by the peak to average power ratio suppression signal calculation unit. 
   Also, in a wireless communication device that has a channel that transmits known signals and that amplifies signals to be transmitted via the channel by an amplification unit in common with the transmission data of another channel and transmits them, it has in the channel via which the known signals are to be transmitted a control unit that controls so as to give them to the amplification unit after including signals that are not known signals. 
   The wireless communication system of this invention has, in a wireless communication system that performs wireless communication using multiplexed signals that include data and pilot signals or other known signals, a means that transmits together on the time axis, each in its prescribed time period, pilot signals and other known signals and signals by which are processed the phase or amplitude or both so as to be able to suppress the peak to average power ratio. 
   The wireless communication device of this invention has, in a wireless communication device that transmits and receives signals that multiplex multiple data and known signals, a means that divides the pilot signals and other known signals into a first known signal and a second known signal, processes phase or amplitude or both so as to be able to suppress the peak to average power ratio based on the signals that multiplex the known signals and multiple data, makes it into a second signal, combines on the time axis this second signal and the first known signal of the known signals unmodified, multiplexes them by multiplexing unit  3 , amplifies them by transmission amplification unit  2 , and transmits them from antenna  1 . 
     FIG. 1  is an explanatory diagram of the main parts of the first working example of this invention.  FIG. 1  may apply to the CDM system and shows the main parts of the transmission function of a wireless communication system or device. 
   In the diagram,  1  is an antenna,  2  is a transmission amplification unit,  3  is a multiplexing unit,  4  is a PAPR (peak to average power ratio) suppression signal calculation unit,  5 - 1  to  5 -n and  6  are spread units,  7  is a composition unit,  8  is a switching unit, and  9  is a control unit. 
   Transmission amplification unit  2  also up-converts signals multiplexed by multiplexing unit  3  to a transmission wireless frequency, a transmission amplifier for amplifying and transmitting from antenna  1 . 
   The structure of spread units  5 - 1  to  5 -n is shown receiving a plurality of transmission data streams. The spread units  5 - 1  to  5 -n spread the plurality of data, Data # 1  to Data #n, in accordance with spread codes. The spread codes are respectively allocated data by data. 
   Then, the spread output signals of the spread units  5 - 1  to  5 -n are multiplexed (combined) by composition unit  7 . 
   Also shown in  FIG. 1  is a pilot signal “Pilot” received by the switching unit  8 . In this example the pilot signal “Pilot” may be considered to be a known signal. 
   Switching unit  8  switches over the pilot signal “Pilot” to either of the input into spread unit  6  directly (as is) or as an input into spread unit  6  via PAPR suppression signal calculation unit  4 . Switching unit  8  switches over the pilot signal in accordance with a signal from a control unit  9 . 
   As shown in the  FIG. 1  example the pilot signal “Pilot” from the switching unit  8  is input directly into spread unit  6  in this case is as P 1  the first known signal. The second signal P 2  to be input into spread unit  6  is output from PAPR suppression signal calculation unit  4 . 
   The PAPR suppression signal calculation unit  4  has a composition for generating the second signal P 2  that is to suppress the peak power value by using a signal that undergoes multiplexing composition by composition unit  7  and the pilot signal Pilot. The output of the PAPR suppression signal calculation unit  4  is supplied to the spread unit  6 . 
   The switching processing of switching unit  8  can be controlled by control unit  9 . For example, control unit  9  the switching to a predetermined switching pattern so as to select the direct input of the signal P 1  for a prescribed time period of the leading part of the slot or frame, and to the signal P 2  for other time periods, etc. In another example, control unit  9  may provide control for peak suppression in accordance with calculation results yielded by PAPR suppression signal calculation unit  4 . For example the PAPR suppression signal calculation unit  4  may provide input to the control unit  9 . 
   Therefore the multiplexed signals to be input into transmission amplification unit  2  and amplified are in a peak-suppressed state and it is possible to suppress the unneeded radiation component. 
   Moreover, both P 1  and P 2  are processed by the same spread unit  6  therefore the spread code is applied the same code. In this case it should be noted that P 1  and P 2  are not transmitted by switching unit  8  with any temporal overlap. 
   Also, in spread unit  6 , P 1  can be transmitted with multiple spread codes, but P 2  can be transmitted with one spread code among the multiple spread codes. 
   Also, with regard to the frequency relationships as well, P 1  and P 2  are both transmitted on the same frequency. And although, P 1  can be transmitted with multiple frequencies, but P 2  can be transmitted with one frequency among the multiple frequencies. 
   In the CDM system or the OFDM system, the processed pilot signal “pilot” which is a known pattern or signal is transmitted. For data reception processing, the receiver can correlate transmission paths because the receiver can obtain radio transmission path status information from the received and divided pilot signal. 
   By using a known signal for example pilot signal this invention does not need a channel etc, to transmit a special signal for suppressing PAPR. 
   The receiver divides the second signal P 2  from the received signal to use the first known signal, for example pilot signal etc. And also, the receiver corrects the phase and amplitude of the second signal P 2  so as to correct all pilot signal  1  is known signal, therefore the receiver is able to correct propagation path correction, etc. 
     FIG. 2  is an explanatory diagram of an example of a first pilot signal P 1  and a second pilot signal P 2  as the known signals referred to above; 
   Assuming the modulation system for the case in which a pilot signal is to be transmitted by QPSK modulation. 
   If the known pilot signal is signal point (1,1), then conventionally a pilot signal is transmitted as this signal point (1,1) multiplexed together with the data, etc. 
   But in this working example, a first pilot signal P 1  is transmitted in every prescribed time period for the pilot signal which is the known signal point (1,1). 
   In order to make it possible for PAPR suppression to be done by PAPR suppression signal calculation unit  4 , after this first pilot signal P 1  is transmitted, one of the four signal points (1,1), (1,−1), (−1,1), (−1,−1) is selected and processed; that is, it is transmitted as second pilot signal P 2  in a phase-controlled state. 
   Moreover, a single or plural of the first pilot signal P 1  is always transmitted every prescribed time period, and during this first pilot signal P 1 , second pilot signal P 2  is transmitted multiplexed onto the time axis (here too, without temporal overlap). 
   The time interval for first pilot signal P 1  should be selected so as to allow the phase change due to the wireless propagation path during this period to be ignored to some extent. 
   On the receiver side, the phase of second pilot signal P 2  can be corrected by taking the phase of first pilot signal P 1  as a reference, making possible restoration to pilot signals of a known phase relationship. 
   Therefore correction processing can be done on the received data by a reception-side propagation path correction means using the pilot signal. 
   In this way, PAPR suppression is done by transmitting a pilot signal in which a first pilot signal P 1  and a second signal P 2  are combined on the time axis (for example, combined without temporal overlap), and on the receiver side, as shown in  FIG. 3 , this pilot signal is set so as to be able to ignore the phase change of the second signal P 2  received during the first pilot signal P 1  of known pattern, and because the second pilot signal P 2  is one of the four signal points (1,1), (1,−1), (−1,1), (−1,−1), processing can be done that returns it to known signal point (1,1) of the first pilot signal P 1 . Therefore processing as a pilot signal can be done in the same way as in the case in which an ordinary pilot signal undergoes reception processing. 
   In the aforesaid case, the second signal P 2 , for which the first pilot signal P 1  is phase-rotated in 90-degree units so as to obtain a PAPR suppression effect in order to effect PAPR suppression, is set to a phase that corresponds to the calculation results in PAPR suppression signal calculation unit  4 , but the transmission can be done with this second signal P 2  phase-rotated in units of θ=360/n (where n is an integer greater than or equal to 2). For example, if we set n=2, then second signal P 2  can be transmitted selected from the calculation results in PAPR suppression signal calculation unit  4  from the two choices 0 degrees and 180 degrees, and if we set n=4, it can be selected from the four phase rotations referred to above. In this case, the higher the value n is set to, the greater the number of choices that can be selected, so the PAPR suppression effect can be improved. 
     FIGS. 4(   a ) and  4 ( b ) are explanatory diagrams of the phase change; in  4 ( a ), if the phase change is large as indicated by the dotted-line arrow, then if the selection phase θ of second signal P 2  is made small and the number of choices is made large, then on the receiver side the phase change in the wireless propagation path and the selection phase of second signal P 2  will come to approximate each other, and reception demodulation of second signal P 2  may be difficult. In that case, the selection phase θ of second signal P 2  is made large. That is, the n in θ=360/n is set to a small value. By this, reception demodulation of second signal P 2  becomes easier. And as shown in  FIG. 4(   b ), if the phase change is small as indicated by the dotted-line arrow, then even if the phase rotation θ is made small, that is, even if the n in the aforesaid θ=360/n is set to a large value, then reception demodulation of second pilot signal P 2  will be easy, and because the selection of phases can be made finer, the PAPR suppression effect can be improved. 
   In  FIG. 1 , amplitude control (amplitude control unit not pictured) can be provided that controls the amplitude of first pilot signal P 1 , second signal P 2 , or both, according to the calculation results given by PAPR suppression signal calculation unit  4 . For example, if the amplitude is to be controlled with respect to second signal P 2 , then on the receiver side the amplitude of second signal P 2  can be corrected based on the reception demodulation results of first pilot signal P 1 . Also, both the phase and amplitude of second signal P 2  can be controlled in correspondence with the calculation results given by PAPR suppression signal calculation unit  4 . For the amplitude of first pilot signal P 1  as well, PAPR suppression can be done by controlling it. 
   In  FIG. 5 , which shows the composition of the main parts of the reception unit of a wireless communication device to which the CDM system is applied,  11  is a pilot signal despread unit,  12  and  13  are switching units,  14  is a pilot signal compensation unit,  15  is a pilot signal compensation quantity calculation unit,  16  is a data despread unit,  17  is a propagation path correction unit, and  18  is a control unit. Omitted from the diagram are the makeup of the reception antenna, demodulation unit, and other high-frequency processing parts and the processing units for reception data, etc. 
   By control unit  18 , switching operations are carried out in such a way that during the reception time period of first pilot signal P 1 , switching units  12  and  13  are set to the switching state shown in the diagram, and during the reception time period of second signal P 2 , switching unit  12  is connected between pilot signal despread unit  11  and pilot signal compensation unit  14 , and switching unit  13  is connected between pilot signal compensation unit  14  and propagation path correction unit  17 . If a pilot signal pattern that shows the transmission time periods of the first and second pilot signals P 1  and P 2  is preset, the switching control of switching units  12  and  13  by this control unit  18  follows this pattern, and if it changes adaptively, switching control can be done in correspondence with the transmission time periods of first and second pilot signals P 1  and P 2  by receiving control information that indicates the pilot signal pattern. 
   Moreover, although there is no need to detect the reception time period of the first pilot signal, various methods can be applied. For example, a wireless communication device that transmits the first pilot signal can be detected by taking the signals of separate transmitting channels as distinguishing marks. For example, it can be arranged that the first pilot signal is transmitted from the time when a signal of a separate channel corresponds to a part that constitutes a specified signal pattern (the same timing as that part, or a time that is a prescribed time before or after that part), and by detection of the specified signal pattern on the receiver side, the start of the first pilot signal that is inserted periodically can be detected. 
   Also, if it is set up so that the first pilot signal is transmitted multiply and continuously, then by receiving the same signal multiple times in a row, it can be detected that it is the first pilot signal, and that the continuous time period is the transmission time period of the first pilot signal. At that time, in consideration of the fact that the second pilot signal also will be the same signal continuously, the transmission time period of the first pilot signal can be detected by the fact that the continuous time period appears repeatedly multiple times with a known periodicity. And if the first pilot signal is transmitted periodically, then if it can be detected for multiple periods that the same signal can be received periodically, it will be possible to detect the transmission time period of the first pilot signal. 
   The first pilot signal P 1  and the second signal P 2  undergo despread processing in pilot signal despread unit  11  according to the spread code assigned to the pilot signal, and by the switching state of switching units  12  and  13  that is pictured in the diagram, first pilot signal P 1  is input into pilot signal compensation quantity calculation unit  15  and propagation path correction unit  17 . And in the same way as in the case of an ordinary pilot signal, data that undergoes despread processing by data signal despread unit  16  is corrected in propagation path correction unit  17  and is transferred to a later-stage processing unit that is not pictured in the diagram. 
   In the time period that corresponds to the transmission time period of second signal P 2 , switching units  12  and  13  are switched from the state pictured in the diagram, second signal P 2  is input into pilot signal compensation unit  14 , in pilot signal compensation quantity calculation unit  15 , compensation of the phase rotation, etc. corresponding to second signal P 2  is done based on the compensation quantity for the phase rotation, etc. corresponding to second signal P 2  for which the first pilot signal P 1  is taken as the reference, and it is input into propagation path correction unit  17  as a pilot signal of the same known pattern as the first pilot signal. Therefore by taking second signal P 2  as a pilot signal of the same known pattern as first pilot signal P 1 , correction of the propagation path properties can be done with respect to the data. 
     FIG. 6  shows the configuration of the principal parts of the reception unit of a wireless communication device to which is applied a CDM system in which part of the configuration shown in  FIG. 5  has been modified; the same symbols as in  FIG. 5  denote the same named parts. Moreover, control unit  18  has been omitted from the diagram. Also, in the configuration shown in  FIG. 5 , the case is shown in which first pilot signal P 1  is used and then compensation of second signal P 2  is done, but in  FIG. 6  it has a configuration in which second signal P 2  compensated by pilot signal compensation unit  14  is also input into pilot signal compensation quantity calculation unit  15 , and compensation of second signal P 2  is done. 
     FIG. 7  is an explanatory diagram for the transmission ratio of first pilot signal P 1  and second signal P 2 ; taking symbol M of first pilot signal P 1  and symbol N of second signal P 2  as pilot frames, these pilot frames can be transmitted repeatedly. As stated above, the length of the pilot frame in this case can also be set to a time period that is long enough so that the phase change in the transmission time period of second signal P 2  during first pilot signal P 1  can be ignored. Also, it is usual to set the ratio M/N of first pilot signal P 1  and second signal P 2  to a preset value, but this could also be varied based on the state of the wireless propagation path, etc. 
     FIG. 8  (A) shows the case in which a pilot signal is used in which, within one pilot frame, first pilot signal P 1 - 1  is arranged as symbol M, then second signal P 2  is arranged as symbol N, then first pilot signal P 1 - 2  is arranged as symbol L; their ratio M/N/L can be set to a preset value. Also, as stated above, the interval between first pilot signals P 1 - 1  and P 1 - 2  can be set to a time period whereby the phase change can be ignored. 
   In  FIG. 8(B) , (a) and (b) are an explanatory diagram for the case in which there is an interval in which no pilot signal is transmitted; (a) shows the case in which the pilot signal pattern shown in  FIG. 7  is used, and (b) shows the case in which the pilot signal pattern shown in  FIG. 8  (A) are used. If the phase change in the interval during which no pilot signal is transmitted is large, in the case of the pilot signal pattern shown in (a), the end of the interval during which there is no transmission is second signal P 2 , and in the case of the pilot signal pattern shown in (b) it is first pilot signal P 1 - 2 , so the demodulation processing of second signal P 2  in the reception-side demodulation of the pilot signal has the advantage of having better demodulation precision than the case shown in (a). 
     FIG. 9  (A) shows the case in which pilot signals are repeatedly transmitted in a pattern where the ratio between first pilot signal P 1  and second signal P 2  changes as M 1 :N 1 , M 2 :N 2 , M 3 :N 3 . If pilot signals are transmitted by a pattern in which the ratio is changed with each pilot frame in this way, it can be done by controlling switching unit  8  by control unit  9  in  FIG. 1 . If such switching control is applied to, for example, a wireless communication system that performs synchronization using pilot signals, then by using a pilot frame in which first pilot signal P 1  has a high ratio, the receiver side can perform synchronization with greater precision than if a pilot frame of another ratio were used. 
     FIG. 9(B)  shows as Case 1  and Case 2 , the ratio of first pilot signal P 1  and second signal P 2  in the pilot frames is made different, and which of Case 1  and Case 2  to adopt can be changed adaptively. For example, when it is determined in PAPR suppression signal calculation unit  4  (see  FIG. 1 ) that the PAPR is large, or when there are many spread codes in the CDM system, then Case 2  is selected, which includes many second signals P 2  for carrying out PAPR suppression, and when it is determined that the PAPR is small, or when there are few spread codes in the CDM system, then Case 1  is selected, which includes many first pilot signals P 1 , and in order to notify the receiver side of this pilot signal pattern, notice is given to the receiver side by control information, for example setting Case 1 =0, Case 2 =1 by a one-bit configuration. Moreover, if a selection is to be made from among a larger variety of pilot signal patterns by the two types Case 1  and Case 2 , the receiver side can be given notice of the pilot signal pattern by a number of bits that corresponds to the number of types. This amounts to, for example, doing switching control of switching units  12  and  13  by reception-side control unit  18  shown in  FIG. 5 . 
     FIG. 10  shows cases in which the pilot frame is not fixed but is variable; Case 1  and Case 2  depict the case in which the length of the pilot frame is the same and the ratio of first pilot signal P 1  and second signal P 2  is different, while Case 3  and Case 4  depict the case in which the length of the pilot frame is shorter than in Case 1  and Case  2 . The selection from among Case 1  to Case 4  can be made according to the following conditions.
     Case 1 : if it is anticipated that the phase change in the wireless propagation path is small and the PAPR is small;   Case 2 : if it is anticipated that the phase change in the wireless propagation path is small and the PAPR is large;   Case 3 : if it is anticipated that the phase change in the wireless propagation path is large and the PAPR is small;   Case 4 : if it is anticipated that the phase change in the wireless propagation path is large and the PAPR is large.   
   That is, if the phase change of the communication path that includes the wireless propagation path is large, the precision of the pilot demodulation signal on the receiver side can be improved by making the pilot frame smaller. If the pilot signal pattern is varied adaptively in this way, by notifying the receiver side of the control information, it is possible on the receiver side to do reception processing on the first and second pilot signals P 1  and P 2  and return the second signal P 2  to first pilot signal P 1 . 
     FIG. 11  (A) shows the results of a simulation of the peak suppression effect, and  FIG. 11(B)  shows the results of a simulation of a conventional example and of this invention.  FIG. 11  (A) shows the PAPR suppression effect if one applies high-speed downlink packet access (HSPDA) for speeding up the transmission rate of the downlink in the wideband-code division multiple access (W-CDMA) system; it shows the results of a computer simulation, given that the transmission signal is set to 24-code multiplex, the pilot channel for peak power suppression is set to a common pilot channel (CPICH), and the ratio of the CPICH power to the total transmission power is set to 0.1. The peak to average power ratio (PAPR) is plotted along the horizontal axis, and the cumulative probability is plotted along the vertical axis. “With peak suppression” in the diagram is the result if the ratio of the first pilot signal P 1  to second signal P 2  in this invention is set to 1:9. It is seen that there is a peak suppression effect of about 0.8 dB at a cumulative probability of 10 −4 . 
     FIG. 11  (B), like in  FIG. 11(A) , shows the results of a simulation if HSPDA is applied and the travel speed of the mobile wireless communication device is set to 3 km/h; Ior/Ioc (the ratio of own-cell power to multi-cell power on the receiver side) is plotted along the horizontal axis, and the throughput of the high-speed downlink shared channel (HS-DSCH) is plotted along the vertical axis. In this invention, because peak suppression is done using a pilot signal by CPICH, there is no need to set up a new channel for peak suppression as in a conventional example, so the HS-DSCH power can be allocated just for the portion of the channel for peak suppression of the conventional example. As a result, it is clear that in this invention the signal-to-interference ratio (SIR) of the HS-DSCH is greater, and the throughput is better, than in the conventional example. By changing from the PAPR suppression means of the conventional example to the PAPR suppression means of this invention, the rate of throughput increase becomes about 10% in the region where or/Ioc=15 dB or less. 
   For the known signals referred to above, the explanation has dealt mainly with the case in which a pilot signal is used in the CDM system, but a pilot signal and other known signals in a multiplexing transmission system such as the OFDM system can be transmitted as a first known signal and a second signal that controls the phase or amplitude or both so as to perform PAPR suppression. 
   Also, it is a concept of whether a channel is the same or different, but if the transmission frequency and spread code are the same, it can be deemed to be the same channel, even if the transmission times are different. 
   That is, for example, in  FIG. 1 , although the transmission part of P 1  and the transmission part of P 2  differ temporally, their transmission frequency and spread code are the same, and both P 1  and P 2  can be deemed to be being transmitted on the same channel (pilot channel). 
   This invention provides advantages because it transmits together on the time axis known signals and signals that are processed with respect to the known signals so as to be able to suppress the peak to average power ratio. Also, it makes use of part of a channel that transmits known signals, with this invention it is unnecessary to newly introduce a special channel for peak suppression. There is no need to newly allocate for suppression purposes any frequency that is different from the channel that transmits known signals, or any different spread code.