JP5275270B2 - Base station, terminal, base station transmission control method, and terminal transmission control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable a first communication system and a second communication system to simultaneously communicate with each other in the same area at the same frequency band, while suppressing the interference of the second communication system with the first communication system, when the first and second communication systems of different types coexist at the same frequency band. <P>SOLUTION: A base station 100 in the second communication system using the same frequency band as the first communication system includes: an area deciding unit 106 that decides whether a terminal is located in an area where the second communication system interferes with the first communication system when the base station 100 communicates with the terminal of the second communication system by using a first transmission parameter and first transmission power; and a control unit 107 that sets a transmission parameter of the terminal at a second transmission parameter having higher resistance to errors than the first transmission parameter and sets the transmission power of the terminal at second transmission power lower than the first transmission power, when the area deciding unit 106 decides that the terminal is located in the area. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a base station, a terminal, a base station transmission control method, and a terminal transmission control method.

  As represented by IMT-Advanced, which is being studied for standardization, in the next-generation mobile communication system, it is necessary to secure a wide frequency band in order to perform high-speed and large-capacity communication. For example, in IMT-Advanced, the use of the frequency bands of 450 MHz to 470 MHz, 698 MHz to 806 MHz, 2.3 GHz to 2.4 GHz, and 3.4 GHz to 3.6 GHz makes it possible to use the International Telecommunications Union Radiocommunication Division (ITU -R).

  However, in recent wireless communication systems in general, demand for expanding communication capacity has increased, and while it has been desired to expand the frequency band used in one wireless communication system, the available frequency resources have been depleted. ing. Therefore, in order to effectively use limited frequency resources, it has become very important to allow a plurality of wireless communication systems to coexist in the same frequency band.

  For example, among the frequency bands allocated for next-generation mobile communication systems such as IMT-Advanced, the 3.4 GHz to 3.6 GHz band is an existing communication represented by a fixed satellite communication system (FSS: Fixed Satellite Service). Used in the system. That is, the frequency band used in IMT-Advanced and the frequency band used in the existing communication system overlap.

  Therefore, since a frequency is shared with such an existing system (for example, FSS), a later new system (for example, IMT-Advanced system) provides services while suppressing interference with the existing system. There must be.

  As a conventional technique for suppressing interference from a new system to an existing system, a technique for restricting communication of the new system in an area where the new system may interfere with the existing system has been proposed (for example, see Patent Document 1). ).

  Specifically, in the above-described conventional technology, a terminal of a new system has a function of receiving a signal transmitted by an apparatus of an existing system. And the terminal of a new system performs a carrier search in the said area (henceforth a use restriction area). Then, if the signal of the existing system does not exist, the terminal of the new system determines that the communication of the new system is possible in the use restricted area. If the signal of the existing system exists, the terminal of the new system Determine that communication with the new system is not possible.

Japanese Patent No. 3756110

  Here, in the above prior art, when the terminal of the new system detects a signal of the existing system in the use restricted area (that is, when the existing system is communicating), the communication of the new system in the use restricted area is not performed at all. It becomes impossible. That is, in the above-described conventional technology, the existing system and the new system cannot communicate simultaneously using the same frequency band in the same area.

  An object of the present invention is to suppress interference caused by the second communication system to the first communication system when different types of the first communication system and the second communication system using the same frequency band coexist. It is to provide a base station, a terminal, a base station transmission control method, and a terminal transmission control method in which one communication system and a second communication system can simultaneously communicate in the same area using the same frequency band.

  The base station of the present invention is a base station in a second communication system that uses the same frequency band as that of the first communication system, wherein the base station uses the first transmission parameter and the first transmission power. A means for specifying an area in which the second communication system interferes with the first communication system when communicating with a terminal of the second communication system; and whether or not the terminal is located in the area. A determination unit configured to determine, and when the determination unit determines that the terminal is located in the area, the transmission parameter for the terminal is set to a second transmission parameter having higher error tolerance than the first transmission parameter. And the control means which sets the transmission power with respect to the said terminal to 2nd transmission power lower than the said 1st transmission power is taken, and the structure which comprises is taken.

  The terminal of the present invention is a terminal in a second communication system that uses the same frequency band as the first communication system, and the lower the power of the received signal received from the base station in the second communication system, Power control means for increasing the power of a transmission signal to be transmitted to a base station, and when the base station communicates with the terminal using a first transmission parameter and a first transmission power, the second communication system Determining means for determining whether or not the terminal is located in an area that interferes with the first communication system, and the power control means determines that the terminal is located in the area Even if the received signal is transmitted at a power lower than the first transmission power, the power of the transmission signal is set to a power corresponding to the first transmission power.

  The base station transmission control method of the present invention is a base station transmission control method in a second communication system that uses the same frequency band as the first communication system, wherein the base station transmits the first transmission parameter and the first transmission parameter. A specifying step of specifying an area in which the second communication system interferes with the first communication system when communicating with a terminal of the second communication system using one transmission power; A determination step for determining whether or not a terminal is located, and if it is determined in the determination step that the terminal is located in the area, the transmission parameter for the terminal is more error resistant than the first transmission parameter. A control step of setting a high second transmission parameter and setting a transmission power for the terminal to a second transmission power lower than the first transmission power; A configuration having a.

  The terminal transmission control method of the present invention is a terminal transmission control method in a second communication system that uses the same frequency band as the first communication system, and is received from a base station in the second communication system. When the power of the transmission signal to be transmitted to the base station is increased as the signal power is lower, and when the base station communicates with the terminal using the first transmission parameter and the first transmission power. A determination step of determining whether or not the terminal is located in an area where the second communication system interferes with the first communication system, and the power control step includes: If the received signal is transmitted at a lower power than the first transmission power, the power of the transmission signal corresponds to the first transmission power. Set to power, a configuration.

  According to the present invention, even when different types of first communication systems (for example, FSS) and second communication systems (for example, IMT-Advanced system) using the same frequency band coexist, The first communication system and the second communication system can simultaneously communicate using the same frequency band in the same area while suppressing interference given to the two communication systems.

The figure which shows the heterogeneous communication system which uses the same frequency band concerning one embodiment of this invention The block diagram which shows the structure of the base station in the IMT-Advanced system which concerns on one embodiment of this invention The block diagram which shows the structure of the terminal in the IMT-Advanced system which concerns on one embodiment of this invention The figure which shows an example of the transmission parameter which concerns on one embodiment of this invention The figure which shows D / U ratio versus BER characteristic in each modulation system concerning one embodiment of this invention

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  In the present embodiment, as an example of different types of communication systems using the same frequency band, as shown in FIG. 1, the case where the above-described IMT-Advanced system (new system) and FSS (existing system) coexist will be described. To do. That is, a case where an IMT-Advanced system that is a system different from FSS is operated using the same frequency as FSS will be described.

  In FIG. 1, an FSS radio station (FSS earth station) communicates with an FSS satellite station. In FIG. 1, a base station of an IMT-Advanced system (hereinafter referred to as IMT-Advanced base station) communicates with an IMT-Advanced terminal (hereinafter referred to as IMT-Advanced terminal).

  Further, in the following description, an FDD (Frequency Division Duplex) method is used as a method for dividing the uplink and the downlink in the FSS and IMT-Advanced systems. At this time, in the FSS earth station shown in FIG. 1, since directivity control is performed toward the direction of the FSS satellite station (above the FSS earth station), interference from the IMT-Advanced terminal to the FSS earth station in the uplink Is hardly a problem. On the other hand, in FIG. 1, since the reception power of a signal (downlink signal) transmitted from the FSS satellite station is very small, interference from the IMT-Advanced base station to the FSS earth station in the downlink is a big problem. Therefore, in the present embodiment, a case will be described in which interference with the FSS earth station is suppressed in the downlink of the IMT-Advanced system.

  In FIG. 1, the IMT-Advanced base station transmits transmission parameters (coding rate, modulation scheme and spreading) to the IMT-Advanced terminal according to the channel quality between the IMT-Advanced base station and the IMT-Advanced terminal. Rate) and transmission power are adaptively changed. That is, the IMT-Advanced base station performs AMC (Adaptive Modulation and Coding) and adaptive power control.

  FIG. 2 is a block diagram showing a configuration of base station 100 which is an IMT-Advanced base station according to the present embodiment. In the present embodiment, base station 100 includes a plurality of antennas 101 and performs multi-antenna signal processing.

  In the base station 100 shown in FIG. 2, the reception unit 102 performs reception processing such as down-conversion and A / D conversion on the signals (signals from the IMT-Advanced terminal) received via the plurality of antennas 101 to receive the signals. The processed signal is output to demodulation / decoding section 103 and estimation section 104.

  Demodulation / decoding section 103 demodulates and decodes the signal input from receiving section 102 and outputs the decoded signal as received data.

  The estimation unit 104 estimates the position of the terminal that transmitted the signal, using the signals received by the plurality of antennas 101, respectively. For example, the estimation unit 104 estimates the arrival direction of the signal, that is, the direction in which the terminal that transmitted the signal is located, using the signals input from the reception unit 102 and received by the plurality of antennas 101, respectively. Moreover, the estimation part 104 estimates the distance between the base station 100 and the terminal which transmitted the signal based on the received power of the signal input from the receiving part 102. Then, the estimation unit 104 outputs position information indicating the direction in which the terminal is located and the distance between the base station and the terminal to the area determination unit 106.

  As a method for estimating the position of the terminal, a method in which the terminal notifies the base station 100 of position information indicating the position of the terminal (for example, positioning information by GPS (Global Positioning System)) may be used. In this method, the estimation unit 104 acquires terminal position information (positioning information) from the demodulation / decoding unit 103 (not shown), and specifies the position of the terminal indicated by the position information.

  The restricted area setting unit 105 specifies an area where the IMT-Advanced system interferes with the FSS when the FSS and the IMT-Advanced system perform communication at the same time, and holds the specified area. In addition, since the specified area is a target area where the base station 100 limits transmission power (described later), the specified area is referred to as a power limited area in the following description. Specifically, the restricted area setting unit 105 is a transmission parameter (first transmission parameter) that is adaptively controlled in the base station 100 (IMT-Advanced base station) based on propagation path quality and the like in the IMT-Advanced terminal. In the following, the IMT-Advanced system interferes with the FSS when it communicates with the IMT-Advanced terminal using normal transmission parameters and transmission power (first transmission power; hereinafter referred to as normal transmission power). An area (area that can cause interference) is specified, and the specified area is set as a power limit area. The limited area setting unit 105 holds information indicating the distance and direction from the base station 100 to the power limited area.

  Here, the method of setting the power restriction area is not limited to the above. For example, the restricted area setting unit 105 uses known station location information (positional information) of the FSS earth station and decides it based on the gain, half-value angle, and the like of the antenna provided in the FSS earth station centered on the FSS earth station. An area within a circle whose radius is the distance to be measured may be set as the power restriction area. Alternatively, the restricted area setting unit 105 may set an area on a straight extension line connecting the base station 100 (IMT-Advanced base station) and the FSS earth station as the power restricted area.

  The area determination unit 106 determines whether or not the IMT-Advanced terminal is located in the power restriction area. Specifically, the area determination unit 106 refers to the information on the power restriction area held by the restriction area setting unit 105 (the direction and distance of the power restriction area), and the IMT-Advanced terminal input from the estimation unit 104 It is determined whether or not the position (direction and distance of the terminal) of the IMT-Advanced terminal indicated in the position information is within the power restriction area. Then, the area determination unit 106 outputs the determination result to the control unit 107.

  The control unit 107 controls transmission parameters and transmission power of a transmission signal addressed to the IMT-Advanced terminal based on the determination result input from the area determination unit 106. Specifically, when the area determination unit 106 determines that the IMT-Advanced terminal is located in the power limited area, the control unit 107 sets the transmission parameter for the IMT-Advanced terminal as a normal transmission parameter (first transmission parameter). The transmission parameter (second transmission parameter) having higher error tolerance than the parameter) is set. For example, when it is determined that the IMT-Advanced terminal is located in the power restriction area, the control unit 107 sets the coding rate of the transmission signal to a coding rate lower than the coding rate in the normal transmission parameter, Set the transmission signal modulation method to a modulation method with a lower modulation multi-level than the modulation method for normal transmission parameters, and set the transmission signal spreading factor to a higher spreading factor than the normal transmission parameter spreading factor. To do.

  In addition, when the area determination unit 106 determines that the IMT-Advanced terminal is located in the power restriction area, the control unit 107 determines the transmission power for the IMT-Advanced terminal from the normal transmission power (first transmission power). Is set to a low transmission power (second transmission power). In addition, when it is determined that the IMT-Advanced terminal is located in the power restriction area, the control unit 107 switches from the normal transmission parameter and the normal transmission power to the changed transmission parameter and the transmission power (switching timing). Set.

  On the other hand, when the area determination unit 106 determines that the IMT-Advanced terminal is located outside the power restriction area, the control unit 107 sets the transmission parameter and transmission power for the IMT-Advanced terminal to the normal transmission parameter and normal transmission power. Set to.

  Then, in accordance with the switching timing, the control unit 107 instructs the set transmission parameters (coding rate, modulation scheme, and spreading factor) to the coding / modulation unit 109, and instructs the set transmission power to the transmission unit 110. Further, when it is determined that the IMT-Advanced terminal is located in the power restriction area, the control unit 107 sets the transmission parameter, switching timing, and IMT-Advanced terminal in the power restriction area for the IMT-Advanced terminal. Control information including information indicating whether or not (power limit area flag) is output to the combining unit 108.

  The combining unit 108 combines the transmission data and the control information input from the control unit 107, and outputs a transmission signal as a combination result to the encoding / modulating unit 109.

  Encoding / modulating section 109 encodes and modulates the transmission signal input from combining section 108 in accordance with the coding rate and modulation method instructed from control section 107, and transmits the modulated transmission signal to the transmission section. To 110.

  The transmission unit 110 performs transmission power control on the transmission signal input from the encoding / modulation unit 109 based on the transmission power instructed from the control unit 107. Then, the transmission unit 110 performs transmission processing such as D / A conversion, amplification, and up-conversion on the transmission signal after transmission power control, and transmits the transmission signal subjected to the transmission processing from the antenna 101.

  FIG. 3 is a block diagram showing a configuration of terminal 200 that is an IMT-Advanced terminal according to the present embodiment.

  In terminal 200 shown in FIG. 3, receiving section 202 performs reception processing such as down-conversion and A / D conversion on a signal (signal from IMT-Advanced base station (FIG. 2)) received via antenna 201, The signal subjected to the reception process is output to the demodulation / decoding unit 203.

  The demodulation / decoding unit 203 demodulates and decodes the signal input from the receiving unit 202 according to the transmission parameters (coding rate and modulation scheme) input from the control unit 205, and separates the decoded signal. Output to the unit 204.

  The separation unit 204 separates the signal input from the demodulation / decoding unit 203 into a data signal and control information. Separation section 204 then outputs the data signal as received data and outputs control information to control section 205. The control information includes transmission parameters (coding rate, modulation scheme and spreading factor) set for terminal 200, switching timing indicating the timing of switching transmission parameters and transmission power, and IMT-Advanced terminal A power limit area flag indicating whether or not it is within the power limit area is included.

  Based on the control information input from demultiplexing section 204, control section 205 controls transmission parameters for the received signal and transmission power for the transmission signal. Specifically, when the power restriction area flag included in the control information indicates that the terminal 200 is located in the power restriction area, the control unit 205 includes the control information in accordance with the switching timing included in the control information. The transmission / reception unit 203 is instructed to the transmission / reception unit 203 (transmission parameter having higher error tolerance than the normal transmission parameter). In addition, when the power restriction area flag indicates that the terminal 200 is located in the power restriction area, the control unit 205 transmits the transmission signal with normal transmission power (for example, transmission power before the switching timing). Then, the transmitter 208 is instructed.

  In addition, the control unit 205 generates control information regarding the terminal 200 and outputs the control information to the synthesis unit 206. For example, when position information (for example, positioning information by GPS) indicating the position of the terminal is used as a method of estimating the position of the terminal in the base station 100 (FIG. 2), the control unit 205 determines the position of the terminal 200. Control information including the position information shown is generated. In addition, the control unit 205 instructs the encoding / modulation unit 207 of the transmission parameter of the transmission signal (uplink signal).

  The combining unit 206 combines the transmission data and the control information input from the control unit 205, and outputs a transmission signal as a combination result to the encoding / modulation unit 207.

  Encoding / modulating section 207 encodes and modulates the transmission signal input from combining section 206 according to the transmission parameter instructed from control section 205, and outputs the modulated transmission signal to transmitting section 208. .

  The transmission unit 208 performs transmission power control on the transmission signal input from the encoding / modulation unit 207 based on the transmission power instructed from the control unit 205. The transmission unit 208 performs transmission processing such as D / A conversion, amplification, and up-conversion on the transmission signal after transmission power control, and transmits the transmission signal subjected to the transmission processing from the antenna 201.

  Next, details of processing in base station 100 (IMT-Advanced base station) shown in FIG. 2 will be described.

  In the following description, a case where the IMT-Advanced base station (base station 100) shown in FIG. 1 transmits a signal (downlink signal) to IMT-Advanced terminal A or IMT-Advanced terminal B will be described. Note that the IMT-Advanced terminal A and the IMT-Advanced terminal B shown in FIG. 1 have the configuration of the terminal 200 shown in FIG.

  Further, in the IMT-Advanced terminal A and the IMT-Advanced terminal B shown in FIG. 1, it is assumed that the channel quality with the IMT-Advanced base station is approximately the same. That is, the same transmission parameters (modulation scheme, coding rate, and spreading rate) and transmission power can be normally set in IMT-Advanced terminal A and IMT-Advanced terminal B shown in FIG.

  In the following description, open loop transmission power control is performed in the IMT-Advanced system. That is, the IMT-Advanced terminal does not receive an instruction (feedback) from the IMT-Advanced base station, for example, based on the propagation path quality estimated using the signal transmitted from the IMT-Advanced base station. (Uplink signal) transmission power is controlled.

  First, the limited area setting unit 105 of the IMT-Advanced base station (base station 100) sets the power limited area using the station location information (known) of the FSS earth station shown in FIG. In other words, in the power limited area shown in FIG. 1, when the IMT-Advanced base station communicates with the IMT-Advanced terminal with normal transmission parameters and normal transmission power, the IMT-Advanced system can interfere with the FSS. There is sex.

  Next, the area determination unit 106 of the IMT-Advanced base station determines whether or not the IMT-Advanced terminal is located within the power restriction area shown in FIG. For example, as illustrated in FIG. 1, the area determination unit 106 compares the location information of the IMT-Advanced terminal A obtained by the estimation unit 104 with the information on the power limited area held by the limited area setting unit 105, It is determined that the IMT-Advanced terminal A is located outside the power restriction area. Further, the area determination unit 106 compares the IMT-Advanced terminal B position information obtained by the estimation unit 104 with the information on the power restriction area held by the restriction area setting unit 105, so that the IMT-Advanced terminal B It is determined that it is located within the restricted area.

  Therefore, the control unit 107 of the IMT-Advanced base station sets normal transmission parameters for the IMT-Advanced terminal A (terminal located outside the power restriction area) shown in FIG. For example, as illustrated in FIG. 4, the control unit 107 sets a high-order modulation scheme, a low spreading factor, and a high coding rate for the IMT-Advanced terminal A illustrated in FIG. 1. On the other hand, the control unit 107 transmits a transmission parameter having higher error tolerance than the normal transmission parameter (“outside power limit area” shown in FIG. 4) for the IMT-Advanced terminal B (in the power limit area) shown in FIG. ('Within power limit area' shown in FIG. 4) is set. For example, as illustrated in FIG. 4, the control unit 107 sets a low-order modulation scheme, a high spreading factor, and a low coding rate for the IMT-Advanced terminal B illustrated in FIG.

  Moreover, the control part 107 of an IMT-Advanced base station sets normal transmission power with respect to IMT-Advanced terminal A (terminal located outside a power restriction area) shown in FIG. On the other hand, the control unit 107 sets transmission power lower than normal transmission power for the IMT-Advanced terminal B (terminal located in the power restriction area) shown in FIG. That is, the control unit 107 limits transmission power to the IMT-Advanced terminal B located in the power restriction area.

  Here, the control unit 107 of the IMT-Advanced base station sets the transmission power for the IMT-Advanced terminal located in the power restriction area to the transmission power determined based on the interference tolerance in the FSS earth station. . For example, the control unit 107 of the IMT-Advanced base station allows the FSS earth station to accept a D / U ratio (DUR: Desired to Undesired Ratio) (dB value) for an IMT-Advanced terminal located in the power restriction area. The transmission power is set low until the transmission power satisfying (hereinafter referred to as the upper limit transmission power) is satisfied. Here, the D / U ratio that the FSS earth station can tolerate is the D / U ratio when there is no interference wave in the FSS earth station and the D / U ratio that does not change the BER (Bit Error Ratio). That is, the control unit 107 of the IMT-Advanced base station sets the transmission power that has been reduced to a level that does not interfere with the FSS earth station for the IMT-Advanced terminals located in the power restriction area.

  For example, FIG. 5 shows a case where the reception power (reception level) of the interference wave (U) at the reception antenna end is changed with the reception power (reception level) at which the desired wave (D) becomes error-free (D / U ratio is changed). An example of the BER characteristic in the case of changing) is shown. As shown in FIG. 5, when the modulation method is QPSK, the D / U ratio is about 9 [dB] and error-free, and when the modulation method is 16QAM, the D / U ratio is about 18 [dB]. It becomes error free. That is, in FIG. 5, the D / U ratio that the FSS earth station can tolerate is D / U ratio = about 9 [dB] when the modulation method is QPSK, and the D / U ratio when the modulation method is 16QAM. = Approximately 18 [dB].

  Therefore, in FIG. 5, the control unit 107 of the IMT-Advanced base station shown in FIG. 1 satisfies the D / U ratio of about 9 [dB] when the modulation scheme is QPSK with respect to the IMT-Advanced terminal B. A transmission power (upper limit transmission power) is set, and when the modulation method is 16QAM, a transmission power (upper limit transmission power) that satisfies a D / U ratio of about 18 [dB] is set.

  Then, the transmission section 110 of the IMT-Advanced base station shown in FIG. 1 has a transmission parameter with higher error tolerance than the normal transmission parameter ('outside power limit area' shown in FIG. 4) for the IMT-Advanced terminal B. The transmission signal is transmitted at a transmission power (upper limit transmission power) that satisfies the D / U that can be allowed by the FSS earth station (in the “power limited area” shown in FIG. 4). On the other hand, the transmission section 110 of the IMT-Advanced base station shown in FIG. 1 transmits a transmission signal to the IMT-Advanced terminal A with normal transmission parameters (“outside power limit area” shown in FIG. Send.

  Accordingly, even when a signal (downlink signal) is transmitted from the IMT-Advanced base station (base station 100) to the IMT-Advanced terminal located in the power restriction area, the FSS earth station has no interference wave. A D / U ratio similar to the D / U ratio in this case (D / U ratio acceptable by the FSS earth station) can be obtained. That is, the signal (downlink signal) from the IMT-Advanced base station (base station 100) to the IMT-Advanced terminal located in the power restriction area does not interfere with the FSS earth station. That is, even when different types of FSS and IMT-Advanced systems using the same frequency band coexist, interference that the IMT-Advanced system gives to the FSS can be suppressed.

  Further, in the IMT-Advanced terminal A and the IMT-Advanced terminal B shown in FIG. 1, since the channel qualities with the IMT-Advanced base station are similar to each other, the IMT-Advanced terminal A and the IMT-Advanced shown in FIG. It is highly likely that the same transmission parameter is normally set for the terminal B (when located outside the power restriction area). However, the IMT-Advanced base station (base station 100), for the IMT-Advanced terminal B located within the power restriction area, from the transmission parameters set in the IMT-Advanced terminal A located outside the power restriction area Also set transmission parameters with high error tolerance.

  In this way, the IMT-Advanced base station (base station 100) sets a transmission parameter with higher error tolerance than the normal transmission parameter for the IMT-Advanced terminal B located in the power restriction area, The transmission power for the IMT-Advanced terminal B located in the power restriction area can be reduced. In other words, the IMT-Advanced base station (base station 100) reduces the transmission power with respect to the IMT-Advanced terminal B located in the power restriction area, but has an error tolerance so that communication is easy even in this state. Set higher transmission parameters. Thereby, even if the IMT-Advanced terminal B shown in FIG. 1 transmits a signal with a transmission power lower than the normal transmission power, the IMT-Advanced terminal B shown in FIG. The probability of receiving increases.

  Therefore, within the power limited area shown in FIG. 1, the IMT-Advanced base station (base station 100) does not interfere with the FSS earth station while the FSS earth station is communicating with the FSS satellite station. A signal (downlink signal) can be transmitted. At this time, it is also possible to make it difficult for the IMT-Advanced terminal located in the power restriction area to reduce the probability of receiving the signal (downlink signal) from the IMT-Advanced base station without error. As a result, the FSS and the IMT-Advanced system can communicate simultaneously using the same frequency band in the same area. In other words, in the IMT-Advanced system, communication can be performed at the same frequency as the frequency used by the FSS regardless of the occurrence of communication in the FSS, so that the frequency utilization efficiency of the IMT-Advanced system can be improved. it can.

  Further, as described above, the IMT-Advanced base station performs transmission power control for the IMT-Advanced terminals located in the power restriction area. Here, when open-loop transmission power control is performed, IMT-Advanced terminals located within the power restriction area have a lower transmission power drop due to transmission power control at the IMT-Advanced base station than actual channel quality. There is a possibility that it is erroneously determined that the propagation path quality is low. In this case, there is a high possibility that the IMT-Advanced terminal transmits a signal (uplink signal) with a transmission power larger than the transmission power corresponding to the actual channel quality. Therefore, in the uplink, interference may occur in the IMT-Advanced system in addition to the FSS. Further, in the IMT-Advanced terminal, useless power is consumed.

  However, as described above, the control unit 107 of the IMT-Advanced base station shown in FIG. 1 notifies the IMT-Advanced terminal B of the power restriction area flag indicating that the IMT-Advanced terminal B is in the power restriction area. . Then, when the notified power limit area flag indicates that the IMT-Advanced terminal B is in the power limit area, the IMT-Advanced terminal B shown in FIG. (Transmission power set before timing), that is, a signal (uplink signal) is transmitted to the IMT-Advanced base station with transmission power corresponding to actual channel quality.

  Thereby, even when the IMT-Advanced base station shown in FIG. 1 reduces the transmission power to the IMT-Advanced terminal B, the IMT-Advanced terminal B propagates between the IMT-Advanced base station and the IMT-Advanced terminal B. There is no possibility of misrecognizing that the channel quality is worse than the actual channel quality. That is, an IMT-Advanced terminal located in the power restriction area can transmit a signal (uplink signal) with normal transmission power.

  Thus, according to the present embodiment, when different types of first communication systems (here, FSS) and second communication systems (here, IMT-Advanced systems) using the same frequency band coexist. The first communication system and the second communication system can simultaneously communicate using the same frequency band in the same area while suppressing interference given to the first communication system by the second communication system.

  Further, according to the present embodiment, in the IMT-Advanced system (second communication system), the terminal switches the transmission parameter and the transmission power based on the notification from the base station. That is, in the IMT-Advanced system, the terminal does not need to determine whether or not the terminal is located within the power restriction area. As a result, in this embodiment, a terminal for an IMT-Advanced system, which is a new system, eliminates the need for a circuit for interference suppression processing to the FSS, such as reception processing of an FSS signal that is an existing system, and IMT -An increase in the circuit scale of the Advanced terminal can be prevented.

  In addition, according to the present embodiment, the IMT-Advanced system (second communication system) determines whether or not to perform interference suppression processing (such as transmission power restriction) in order to determine whether signals from other communication systems are to be used. Does not require a career search. Therefore, even if it is difficult for other communication systems to perform a carrier search because the received signal is very weak, such as FSS, or the directivity of the signal is upward. Interference can be suppressed.

  In the present embodiment, the IMT-Advanced system is described as an example of a mobile communication system that is a new system. However, the mobile communication system is not limited to the IMT-Advanced system, and the present invention is applied to other communication systems. You may apply. In the present embodiment, a satellite communication system (FSS) is given as an example of an existing communication system that coexists with a mobile communication system, but the same may be considered between other types of communication systems.

  Further, in this embodiment, when the IMT-Advanced terminal is located in the power restriction area, the base station resets all the transmission parameters of the coding rate, modulation scheme, and spreading factor of the transmission signal, so that the transmission signal The case of improving the error tolerance of has been described. However, in order to improve the error tolerance of the transmission signal, the base station may reset only one transmission parameter of the coding rate, the modulation scheme, and the spreading factor, and the coding rate, the modulation scheme, and Of the spreading factor, only a set of arbitrary transmission parameters may be reset. For example, the base station may reset only the modulation scheme and spreading factor, or may reset only the modulation scheme and coding rate.

  In the present embodiment, the case where the IMT-Advanced system performs open-loop power control has been described, but the present invention is not limited to this. For example, the IMT-Advanced terminal may perform closed loop power control for controlling power in response to an instruction (feedback) from the IMT-Advanced base station.

  The present invention is useful, for example, when a mobile communication system and a satellite communication system share the same frequency.

100 base station 200 terminal 101, 201 antenna 102, 202 receiving unit 103, 203 demodulation / decoding unit 104 estimation unit 105 restricted area setting unit 106 area determination unit 107, 205 control unit 108, 206 combining unit 109, 207 encoding / modulation 110, 208 Transmitter 204 Separator

Claims (10)

A base station in a second communication system that uses the same frequency band as the first communication system,
An area in which the second communication system interferes with the first communication system when the base station communicates with a terminal of the second communication system using the first transmission parameter and the first transmission power. Identification means to identify;
Determining means for determining whether or not the terminal is located in the area;
When the determination means determines that the terminal is located in the area, the transmission parameter for the terminal is set to a second transmission parameter having higher error tolerance than the first transmission parameter, and transmission to the terminal is performed. Control means for setting the power to a second transmission power lower than the first transmission power;
A base station. The control means further sets the transmission parameter for the terminal to the first transmission parameter when the determination means determines that the terminal is located outside the area, and sets the transmission power for the terminal to the first transmission parameter. Set to the first transmit power,
The base station according to claim 1. When the determination unit determines that the terminal is located in the area, the control unit determines a modulation scheme having a lower modulation multi-level number than the modulation scheme in the first transmission parameter as the second transmission parameter. Set as
The base station according to claim 1. When the determination unit determines that the terminal is located in the area, the control unit sets a coding rate lower than the coding rate in the first transmission parameter as the second transmission parameter. ,
The base station according to claim 1. The control unit sets a spreading factor higher than the spreading factor in the first transmission parameter as the second transmission parameter when the judging unit determines that the terminal is located in the area.
The base station according to claim 1. When the determination unit determines that the terminal is located in the area, the control unit determines a transmission power for the terminal based on interference resistance against interference in the radio station of the first communication system. The second transmission power is set to
The base station according to claim 1. The first communication system is a satellite communication system, and the second communication system is a mobile communication system;
The base station according to claim 1. A terminal in a second communication system that uses the same frequency band as the first communication system,
Power control means for increasing the power of the transmission signal transmitted to the base station as the power of the reception signal received from the base station in the second communication system is lower;
When the base station communicates with the terminal using the first transmission parameter and the first transmission power, the terminal is located in an area where the second communication system interferes with the first communication system. A judgment means for judging whether or not to do,
When it is determined that the terminal is located in the area, the power control means sets the power of the transmission signal to the first even if the reception signal is transmitted with power lower than the first transmission power. Set to the power corresponding to the transmission power of
Terminal. A base station transmission control method in a second communication system using the same frequency band as the first communication system,
An area in which the second communication system interferes with the first communication system when the base station communicates with a terminal of the second communication system using the first transmission parameter and the first transmission power. Specific steps to identify;
A determination step of determining whether or not the terminal is located in the area;
When it is determined in the determination step that the terminal is located in the area, a transmission parameter for the terminal is set to a second transmission parameter having higher error tolerance than the first transmission parameter, and transmission to the terminal is performed. A control step of setting power to a second transmission power lower than the first transmission power;
A base station transmission control method comprising: A terminal transmission control method in a second communication system using the same frequency band as the first communication system,
A power control step of increasing the power of the transmission signal transmitted to the base station as the power of the reception signal received from the base station in the second communication system is lower;
When the base station communicates with the terminal using the first transmission parameter and the first transmission power, the terminal is located in an area where the second communication system interferes with the first communication system. A determination step for determining whether or not to perform,
In the power control step, when it is determined that the terminal is located in the area, the power of the transmission signal is set to the first power even if the reception signal is transmitted with power lower than the first transmission power. Set to the power corresponding to the transmission power of
Terminal transmission control method.

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