Patent Document

CROSS REFERENCE TO RELATED APPLICATIONS 
     The present application is a divisional of application Ser. No. 10/762,356, filed Jan. 23, 2004, now U.S. Pat. No. 7,242,959, which is a continuation of application Ser. No. 09/703,052, filed Oct. 31, 2000, now U.S. Pat. No. 6,847,818. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a cellular communications system, and more particularly to a transmission power control technique in a base station. 
     2. Description of Related Art 
     In code division multiple access (CDMA) systems, soft handover is a well-known technique where a mobile station is simultaneously communicating with multiple base stations, allowing hitless connection switching by making a connection to a new base station while maintaining a connection to an old base station. Soft handover provides diversity, which is a method of using independent fading signals received on several transmission paths all carrying the same message to improve the reliability of the transmission. 
     In the case of downlink (from base station to mobile station) soft handover, however, multiple base stations simultaneously transmit radio signals to the mobile station, resulting in substantial interferences at adjacent cells. As a technique of suppressing an increase in interference in the case of downlink soft handover, a downlink transmission power control method has been proposed by Furukawa (Technical Report of Institute of Electronics, Information and Communication Engineers, RCS97-218, February 1998, pp. 40, Second chapter). An outline of the downlink transmission power control method will be described with reference to  FIGS. 1-4 . 
     It is assumed that a mobile station is communicating with multiple base stations for soft handover. 
     Referring to  FIG. 1 , a downlink signal from each of the base stations is received at an antenna and is transferred to a down converter  102  through a duplexer  101 . The down converter  102  converts the received radio-frequency (rf) signal into a baseband signal and outputs it to a pilot signal receiver  103 . The pilot signal receiver  103  detects a pilot signal from the received baseband signal and measures the intensity or quality thereof. A primary base station decision section  104  compares the intensity/quality measurements of the received signals to determine a base station transmitting a signal having the maximum intensity/quality as a primary base station to communicate with. A base station selection signal generator  105  generates a base station selection signal from the identification number of the primary base station. A control signal generator  106  generates control signals including a transmission power control signal and outputs the control signals to a combiner  107  together with the base station selection signal received from the base station selection signal generator  105 . The combiner  107  combines the control signals and the base station selection signal with an uplink information signal to produce a transmission signal. The transmission signal is converted to an rf transmission signal by an up converter  108 . The rf transmission signal is further amplified by an rf amplifier  109  and then transmitted as an uplink signal to the base stations through the duplexer  101 . Each of the base stations communicating with the mobile station receives the uplink signal including the base station selection signal from the mobile station. 
     Referring to  FIG. 2 , at each of the base stations connected to the mobile station, the uplink signal is received at an antenna and is transferred to a down converter  202  through a duplexer  201 . The down converter  202  converts the received rf uplink signal to a baseband signal and outputs it to both a transmission power control signal demodulator  203  and a base station selection signal demodulator  204 . The transmission power control signal demodulator  203  demodulates the transmission power control signal from the received baseband signal and outputs it to a transmission power controller  205 . The base station selection signal demodulator  204  demodulates the base station selection signal from the received baseband signal and outputs it to a primary/non-primary base station mode controller  206 . 
     The transmission power controller  205  produces an interim controlled transmission power value P 1  depending on the transmission power control signal inputted from the transmission power control signal demodulator  203  and outputs the interim controlled transmission power value P 1  to the primary/non-primary base station mode controller  206 . 
     The primary/non-primary base station mode controller  206  updates the interim controlled transmission power value P 1  depending on the base station selection signal to produce a final controlled transmission power value P 2  and output it to a transmission controller  207 . The details of the primary/non-primary base station mode controller  206  will be described later. 
     The transmission controller  207  receives a downlink transmission signal and performs the output power control such that the transmission power of the downlink transmission signal is set to the final controlled transmission power value P 2 . The power-controlled downlink transmission signal is converted into radio frequency by an up converter  208 . The rf downlink transmission signal is amplified by the rf amplifier  209  and then transmitted to the mobile station through the duplexer  201 . 
     Referring to  FIG. 3A , a transmission signal between the mobile station and multiple base stations has a frame structure. A frame D- 001  consists of Fn slots to which consecutive numbers from 0 to Fn−1 are assigned, respectively. 
     As described above, the mobile station transmits the base station selection signal for soft handover to the base stations which it is communicating with. The base station selection signal is composed of a string of bits identifying each of the base stations. Since a plurality of bits are used to form a base station selection signal, redundancy can be provided, resulting in reduced transmission error due to noises and/or fading. Hereinafter, a string of 8 bits identifying each of the base stations is called “a base station selection code word.” An example will be described with reference to  FIG. 3B . 
     As shown in  FIG. 3B , assuming that a base station selection code word E- 002  is “00001111”, each part of the code word E- 002  is assigned to the dedicated field E- 001  of a different uplink slot E- 003 . In other words, the base station selection code word E- 002  is divided into 8 parts (here, each part is one bit) and the respective 8 parts are transmitted by the dedicated fields E- 001  of different slots E- 003 . Here, a period of base station selection control E- 004  is 8 slots, each of which has the desiccated field E- 001  for storing a corresponding bit of the 8-bit base station selection code word E- 002 . It is possible to accommodate two or more bits of the base station selection code word E- 002 . The larger the number of bits to be accommodated, the shorter the period of base station selection control E- 004 . 
     In the cellular system, each base station and each mobile station measure intensities of pilot signals and interference signals received from adjacent cells at regular intervals in order to use them for handover control and call admission control. In the case where a base station performs the measuring of pilot signals and interference signals, the uplink transmission of each mobile station connected to the base station is temporarily halted to allow the precise measuring of signals from outside cells. Further, there are some cases where the uplink transmission of a mobile station is halted during communication so as to suppress uplink interference in the case of packet transmission and no-voice transmission. 
     Conventional BS Mode Update 
     As described before, the primary/non-primary base station mode controller  206  in each of the base stations updates the interim controlled transmission power value P 1  depending on the base station selection code word E- 002  to produce a final controlled transmission power value P 2 . The conventional base station mode control is performed as shown in  FIG. 4 . 
     Referring to  FIG. 4 , the primary/non-primary base station mode controller  206  inputs the base station selection code word E- 002  from the base station selection signal demodulator  204  (step S 401 ) and detects the base station identification number BS_ID RSV  from the base station selection code word E- 002  (step S 402 ). Then, it is determined whether the base station identification number BS_ID RSV  is identical to the identification number ID of its own (step S 403 ). If the base station identification number BS_ID RSV  is identical to the own identification number ID (YES at step S 403 ), then the final controlled transmission power value P 2  is set to the interim controlled transmission power value P 1  inputted from the transmission power controller  205 , that is, P 2 =P 1  (primary base station mode), (step S 404 ). If the base station identification number BS_ID RSV  is not identical to the own identification number ID (NO at step S 403 ), then the final controlled transmission power value P 2  is set to a predetermined minimum transmission power value P MIN , that is, P 2 =P MIN  (non-primary base station mode), (step S 405 ). The predetermined minimum transmission power value P MIN  may be 0. The final controlled transmission power value P 2  is output to the transmission controller  207  (step S 406 ). 
     In this manner, at each of the base stations communicating with the mobile station, the transmission power selectively switches on and off depending on the base station selection code word E- 002  received from the mobile station. Accordingly, multiple base stations are prevented from simultaneously transmitting the same signal to a single mobile station and thereby interference to adjacent cells is suppressed, resulting in improved communication capacity. 
     1) Loss of BS Selection Signal 
     In the case where the uplink transmission of each mobile station connected to the base station is temporarily halted as described before, however, the base station selection code word E- 002  to be transmitted to the base stations is punctured in part or in entirety as shown in  FIG. 3C . 
     More specifically, when the uplink transmission of the mobile station is halted for an uplink transmission puncturing period F- 001  in the base station control period E- 004 , the base station selection code word E- 002  is punctured in part and an incomplete code word F- 002  is received at the base stations. Such a partial or entire loss of the base station selection code word E- 002  results in substantially reduced reliability on base station selection control. 
     2) Variation in BS Update Timing 
     As described before, during the soft handover operation, a plurality of base stations transmit the same signal to a single mobile station. In this case, the transmission timing of the signal is adjusted so that the signals transmitted by the base stations arrive at the mobile station within an acceptable time deviation. Since propagation distances from the mobile station to the base stations vary from base station to base station, the respective transmission timings of the base stations are different. On the other hand, the base stations also receive the uplink signal from the mobile station at different timings due to the different propagation distances. 
     In the case where the respective transmission timings of the downlink signals and the receiving timings of the uplink signal including the base station selection signal at the base stations are different as described above, there are cases where actual BS mode update timings of the base stations vary from base station to base station. The details will be described hereinafter. 
     Referring to  FIG. 5 , a time slot is denoted by reference symbol G- 001  and each transmission signal has a frame structure where 15 slots are numbered from 0 to 14. For simplicity, it is assumed that two base stations  1  and  2  transmit downlink transmission signals G- 002  and G- 003  to the mobile station with the respective transmission timings (propagation delays: D 1  and D 2 ) adjusted so that the downlink transmission signals arrive at the mobile station within an acceptable time deviation. 
     Accordingly, the mobile station receives the downlink transmission signals G- 002  as a downlink reception signal G- 004  from the base station  1  and, at the approximately same time, receives the downlink transmission signals G- 003  as a downlink reception signal G- 005  from the base station  2 . 
     The mobile station transmits an uplink transmission signal G- 006  to the base stations  1  and  2  a time period of transmission timing offset T TR  after the downlink reception signals G- 004  and G- 005  have been received. As described before, the uplink transmission signal G- 006  includes the base station selection code word such that respective parts of the base station selection code word are conveyed in the dedicated fields as shown in  FIG. 3B . 
     The base station  2  receives the uplink transmission signal G- 006  as an uplink reception signal G- 007  with a propagation delay time of D 3  and the base station  1  receives the uplink transmission signal G- 006  as an uplink reception signal G- 008  with a propagation delay time of D 4 . 
     It is assumed that an entire base station selection code word is received when the slot numbered  14  has been received. In this case, the base station  2  starts the primary/non-primary BS mode update operation as shown in  FIG. 4  when receiving the last part of the base station selection code word stored in the dedicated field G- 020  in the slot numbered  14  of the uplink reception signal G- 007 . As shown in  FIG. 5 , the timing of receiving the last part of the base station selection code word falls into the subsequent slot numbered  0 . Therefore, the actual primary/non-primary mode update is performed at the further subsequent slot G- 017  numbered  1 . 
     Similarly, the base station  1  starts the primary/non-primary BS mode update operation as shown in  FIG. 4  when receiving the last part of the base station selection code word stored in the dedicated field G- 021  in the slot numbered  14  of the uplink reception signal G- 008 . As shown in  FIG. 5 , the timing of receiving the last part of the base station selection code word falls into the next slot but one, that is numbered  1 . Therefore, the actual primary/non-primary mode update is performed at the further next slot numbered  2 . 
     In this manner, from the standpoint of the mobile station, the primary base station update timing of the base station  1  is the slot G- 018  numbered  2  and that of the base station  2  is the slot G- 019  numbered  1 . Since the BS selection code word is transmitted during a period of base station selection control, variations in BS mode update timing may cause loss of a downlink signal. To avoid such a signal loss, the mobile station needs an added circuit for monitoring the BS mode update timing at all times. 
     SUMMARY OF THE INVENTION 
     An object of the present invention is to provide a transmission power control method and system allowing stable and reliable signal transmission. 
     Another object of the present invention is to provide a primary base station mode update method ensuring stable and reliable operation in case of loss of a base station selection signal. 
     Still another object of the present invention is to provide a primary base station mode update method allowing synchronization among the mode update timings of base stations communicating with a mobile station. 
     According to an aspect of the present invention, a method for controlling transmission power of a downlink signal from a base station to a mobile station depending on a base station selection signal, wherein the mobile station selects at least one primary base station among a plurality of base stations which are connected to the mobile station for soft handover to produce the base station selection signal designating said at least one primary base station, includes the steps of: at each of the base stations, receiving the base station selection signal from the mobile station; measuring an amount of loss of the base station selection signal; determining whether the amount of loss of the base station selection signal exceeds a threshold; when the amount of loss of the base station selection signal does not exceed the threshold, setting the transmission power of the downlink signal to a selected one of a normally controlled level and a minimum level depending on the base station selection signal; and when the amount of loss of the base station selection signal exceeds the threshold, setting the transmission power of the downlink signal to the normally controlled level. 
     The amount of loss of the base station selection signal may be a number of erroneously received bits in the base station selection signal. The amount of loss of the base station selection signal may be a ratio of a punctured length to a length of the base station selection signal. The threshold may vary depending on a length of the base station selection signal. The threshold may vary depending on the length of the base station selection signal. 
     According to anther aspect of the present invention, a method for controlling transmission power of a downlink signal which is transmitted in frames from a base station to a mobile station depending on a base station selection signal, wherein the mobile station selects at least one primary base station among a plurality of base stations which are connected to the mobile station for soft handover to produce the base station selection signal designating said at least one primary base station, wherein an uplink signal including the base station selection signal is transmitted in frames to the base stations, the method includes the steps of: at each of the base stations, a) receiving the uplink signal including the base station selection signal from the mobile station; b) determining a transmission power update timing so that the downlink signal received at the mobile station changes in transmission power at a predetermined timing synchronized with that of other base stations; and c) when reaching the transmission power update timing, setting the transmission power of the downlink signal to a selected one of a normally controlled level and a minimum level depending on the base station selection signal. 
     Each frame of the uplink signal and the downlink signal may be composed of a plurality of time slots which are numbered consecutively, wherein the transmission power update timing in each of the base stations is represented by a number of same time slot. 
     The time slot number indicating the transmission power update timing may be determined by delaying a receiving time of the base station selection signal by an amount of time determined so that the downlink signal received at the mobile station changes in transmission power at same timing. 
     The time slot number indicating the transmission power update timing is preferably determined by
 
(j+Tos)mod Fn,
 
where j is number of a time slot indicating a last portion of the base station selection signal, Tos is waiting time for transmission power update, Fn is number of slots included in one frame, and mod is an operator whose result is the remainder of a division operation.
 
     The waiting time Tos may vary depending on a propagation delay between the base station and the mobile station. The waiting time Tos may vary depending on the time slot number j. 
     As described above, according to the present invention, when the amount of loss of a base station selection signal received from a mobile station exceeds a predetermined level, the base station mode does not reduce the transmission power of the downlink signal regardless of whether the base station selection signal instructs the base station itself to be the primary base station or not. Therefore, base station selection error due to a low-reliable base station selection signal can be avoided. Especially, in the case where a base station is designated as the primary base station, it is avoided that the base station erroneously reduces or switches off the transmission power. 
     Further, since the update timings of the base stations are in synchronization with each other in the downlink signal received at the mobile station, loss of a downlink signal caused by loss of synchronism can be avoided without the need of an added circuit for monitoring the mode update timing at the mobile station. 
    
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
         FIG. 1  is a schematic diagram showing a configuration of a mobile station in a mobile communications system; 
         FIG. 2  is a schematic diagram showing a configuration of a base station in the mobile communications system; 
         FIG. 3A  is a diagram showing a frame format of an uplink signal transmitted from a mobile station to a base station; 
         FIG. 3B  is a diagram showing the frame format of an uplink signal for explaining a method of transmitting a base-station selection signal; 
         FIG. 3C  is a diagram showing the frame format of an uplink signal for explaining an uplink transmission stop period; 
         FIG. 4  is a flow chart showing a conventional method of updating the primary/non-primary base station mode; 
         FIG. 5  is a time chart showing the base-station mode update timing in the conventional method; 
         FIG. 6  is a flow chart showing a method of updating the primary/non-primary base station mode according to a first embodiment of the present invention; 
         FIG. 7  is a flow chart showing a method of updating the primary/non-primary base station mode according to a second embodiment of the present invention; 
         FIG. 8  is a time chart showing the base-station mode update timing according to the second embodiment; and 
         FIG. 9  is a flow chart showing a method of updating the primary/non-primary base station mode according to a third embodiment of the present invention. 
     
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     The preferred embodiments of the present invention will be described in detail with reference to  FIGS. 6-9 . Each of the embodiments will be described as a control operation of the primary/non-primary base station mode controller  206  at a base station, which may be implemented by a control program running on a program-controlled processor in the primary/non-primary base station mode controller  206 . 
     As described before, the primary/non-primary base station mode controller  206  in each of the base stations updates the interim controlled transmission power value P 1  depending on the base station selection code word E- 002  to produce a final controlled transmission power value P 2 . 
     First Embodiment 
     Referring to  FIG. 6 , a first embodiment of the present invention controls the transmission power taking into consideration the amount of loss of a base station selection signal or code word. 
     More specifically, the primary/non-primary base station mode controller  206  inputs the base station selection code word from the base station selection signal demodulator  204  (step S 601 ) and measures the amount of loss of the base station selection code word (step S 602 ). The amount of loss of the base station selection code word may be the number of punctured bits as shown in  FIG. 3C  or the ratio of the number of punctured bits to the number of all bits of the base station selection code word. Hereafter, the amount of loss of the base station selection code word is denoted by L CW . 
     Subsequently, it is determined whether the amount of loss of the base station selection code word, L CW , is greater than a threshold L TH  (step S 603 ). The threshold L TH  may vary depending on the length of the base station selection code word. 
     If L CW &gt;L TH  (YES at step S 603 ), then it is determined that the demodulated base station selection code word is not sufficiently reliable and the final controlled transmission power value P 2  is set to the interim controlled transmission power value P 1  inputted from the transmission power controller  205 , that is, P 2 =P 1  (primary base station mode), (step S 604 ). In other words, the transmission power is not suppressed regardless of whether the base station itself is the primary base station or not. 
     If L CW  is equal to or lower than L TH  (NO at step S 603 ), then the base station identification number BS_ID RSV  is detected from the base station selection code word (step S 605 ). Then, it is determined whether the base station identification number BS_ID RSV  is identical to the identification number ID of its own (step S 606 ). 
     If the base station identification number BS_ID RSV  is identical to the own identification number ID (YES at step S 606 ), then the final controlled transmission power value P 2  is set to the interim controlled transmission power value P 1 , that is, P 2 =P 1  (primary base station mode), (step S 604 ). If the base station identification number BS_ID RSV  is not identical to the own identification number ID (NO at step S 606 ), then the final controlled transmission power value P 2  is set to a predetermined minimum transmission power value P MIN , that is, P 2 =P MIN  (non-primary base station mode), (step S 607 ). The predetermined minimum transmission power value P MIN  may be 0. The final controlled transmission power value P 2  is output to the transmission controller  207  (step S 608 ). 
     Alternatively, if the base station identification number BS_ID RSV  is not identical to the own identification number ID (NO at step S 606 ), it may be further determined whether the reception quality of the base station selection code word satisfies a predetermined level. If the reception quality does not satisfy the predetermined level, then it is determined that the demodulated base station selection code word is not sufficiently reliable, and the final controlled transmission power value P 2  may be set to the interim controlled transmission power value P 1  (step S 604 ). 
     As described above, in the case where the amount of loss of the base station selection code word is greater than the threshold, in other words, where the demodulated base station selection code word is not sufficiently reliable, the transmission power is not suppressed regardless of whether the base station itself is designated as the primary base station or not. 
     Second Embodiment 
     Referring to  FIG. 7 , a second embodiment of the present invention controls the BS mode update timing so that synchronization among the primary/non-primary mode update timings of base stations is achieved. 
     More specifically, the primary/non-primary base station mode controller  206  inputs the base station selection code word from the base station selection signal demodulator  204  (step S 701 ) and detects the base station identification number BS_ID RSV  from the base station selection code word E- 002  (step S 702 ). Then, variable i is set to the number of a current slot and variable j is set to the number of a slot conveying the last part of the base station selection code word (step S 703 ). Thereafter, it is determined whether the following equation (1) is satisfied (step S 704 ):
 
 i =( j+Tos )mod  Fn   (1),
 
where Tos is waiting time for mode update, Fn is the number of slots included in one frame, and X mod Y is an operator whose result is the remainder of a division operation (X/Y). In other words, the base station mode updating operation is not performed until the current slot reaches a slot numbered (j+Tos) mod Fn.
 
     When the equation (1) is satisfied (YES at step S 704 ), it is determined whether the base station identification number BS_ID RSV  is identical to the identification number ID of its own (step S 705 ). If the base station identification number BS_ID RSV  is identical to the own identification number ID (YES at step S 705 ), then the final controlled transmission power value P 2  is set to the interim controlled transmission power value P 1  inputted from the transmission power controller  205 , that is, P 2 =P 1  (primary base station mode), (step S 706 ). If the base station identification number BS_ID RSV  is not identical to the own identification number ID (NO at step S 705 ), then the final controlled transmission power value P 2  is set to a predetermined minimum transmission power value P MIN , that is, P 2 =P MIN  (non-primary base station mode), (step S 707 ). The predetermined minimum transmission power value P MIN  may be 0. The final controlled transmission power value P 2  is output to the transmission controller  207  (step S 708 ). 
     Alternatively, if the base station identification number BS_ID RSV  is not identical to the own identification number ID (NO at step S 705 ), it may be further determined whether the reception quality of the base station selection code word satisfies a predetermined level. If the reception quality does not satisfy the predetermined level, then it is determined that the demodulated base station selection code word is not sufficiently reliable, and the final controlled transmission power value P 2  may be set to the interim controlled transmission power value P 1  (step S 706 ). 
     Referring to  FIG. 8 , a time slot is denoted by reference symbol J- 001  and each transmission signal has a frame structure where Fn (=15) slots are numbered from 0 to 14. For simplicity, it is assumed that two base stations  1  and  2  transmit downlink transmission signals J- 002  and J- 003  to the mobile station with the respective transmission timings (propagation delays: D 1  and D 2 ) adjusted so that the downlink transmission signals arrive at the mobile station within an acceptable time deviation. 
     Accordingly, the mobile station receives the downlink transmission signals J- 002  as a downlink reception signal J- 004  from the base station  1  and, at the approximately same time, receives the downlink transmission signals J- 003  as a downlink reception signal J- 005  from the base station  2 . 
     The mobile station transmits an uplink transmission signal J- 006  to the base stations  1  and  2  a time period of transmission timing offset T TR  after the downlink reception signals J- 004  and J- 005  have been received. As described before, the uplink transmission signal J- 006  includes the base station selection code word such that respective parts of the base station selection code word are conveyed in the dedicated fields as shown in  FIG. 3B . 
     The base station  2  receives the uplink transmission signal J- 006  as an uplink reception signal J- 007  with a propagation delay time of D 3  and the base station  1  receives the uplink transmission signal J- 006  as an uplink reception signal J- 008  with a propagation delay time of D 4 . 
     It is assumed that an entire base station selection code word is received when the slot numbered  14  has been received, that is, j=14, and the mode update waiting time Tos is set to 3, Fn=15. In this case, (j+Tos) mod Fn=2. Therefore, the base station  1  performs the actual mode update at the slot J- 017  numbered  2 . Similarly, the base station  1  also performs the actual mode update at the slot J- 017  numbered  2 . 
     In this manner, from the standpoint of the mobile station, the primary base station update timing of the base station  1  is in synchronization with that of the base station  2 . 
     It is preferable that the waiting time Tos is as short as possible to achieve high-speed mode switching. Since the propagation delay and processing delay in a base station may vary, it is possible to make the waiting time Tos variable during communication. 
     Further, the waiting time Tos may be varied depending on the number j of the slot conveying the last part of the base station selection code word. In this case, the primary base station mode update timing at the mobile station can be set to a desired timing. 
     Third Embodiment 
     Referring to  FIG. 9 , a third embodiment of the present invention is a combination of the first and second embodiments. Steps S 901 -S 905  are the same as the steps S 701 -S 705  of  FIG. 7 , respectively. If the base station identification number BS_ID RSV  is identical to the own identification number ID (YES at step S 905 ), then it is determined whether the amount of loss of the base station selection code word, L CW , is greater than a threshold L TH  (step S 906 ). 
     If L CW &gt;L TH  (YES at step S 906 ), then it is determined that the demodulated base station selection code word is not sufficiently reliable and the final controlled transmission power value P 2  is set to the interim controlled transmission power value P 1  inputted from the transmission power controller  205 , that is, P 2 =P 1  (primary base station mode), (step S 604 ). In other words, the transmission power is not suppressed regardless of whether the base station itself is the primary base station or not. 
     If L CW  is equal to or lower than L TH  (NO at step S 906 ), then the final controlled transmission power value P 2  is set to a predetermined minimum transmission power value P MIN , that is, P 2 =P MIN  (non-primary base station mode), (step S 908 ). The final controlled transmission power value P 2  is output to the transmission controller  207  (step S 909 ). 
     Alternatively, if the base station identification number BS_ID RSV  is not identical to the own identification number ID (NO at step S 905 ), it may be further determined whether the reception quality of the base station selection code word satisfies a predetermined level. If the reception quality does not satisfy the predetermined level, then it is determined that the demodulated base station selection code word is not sufficiently reliable, and the final controlled transmission power value P 2  may be set to the interim controlled transmission power value P 1  (step S 907 ). 
     As described above, according to the present invention, when the amount of loss of a base station selection signal received from a mobile station exceeds a predetermined level due to an uplink puncturing operation of the mobile station, the base station mode is set to the primary mode regardless of whether the base station selection signal instructs the base station itself to be the primary base station or not. Therefore, such a decision error that the base station is erroneously set to the non-primary base station mode due to reception error can be effectively eliminated, resulting in stable and reliable quality of a downlink signal from the base station to the mobile station. 
     Further, since the update timings of the base stations are in synchronization with each other in the downlink signal received at the mobile station, loss of a downlink signal caused by loss of synchronism can be avoided without the need of an added circuit for monitoring the mode update timing at the mobile station.

Technology Category: 5