JP5287305B2 - Wireless communication system, wireless base station, transmission / reception method, and program - Google Patents

Description

  The present invention relates to a wireless communication technique, and more particularly to a technique in which a plurality of systems share the same frequency band.

  In next-generation wireless communication systems, there is a concern about the depletion of frequency resources as the transmission speed becomes wider and the system diversifies. In recent years, cognitive radio that recognizes the surrounding radio wave environment and the needs of users and performs optimal communication autonomously has been studied, and dynamic spectrum access that secondary uses the frequency allocated to the existing radio system has been studied. It attracts attention from the viewpoint of effective use of frequency resources. In the dynamic spectrum access, the secondary system performs communication using the free spectrum of the spectrum assigned to the primary system of the existing wireless system.

As an example of a radio communication system to which dynamic spectrum access is applied, FIG. 26 shows a mode in which the uplink of the secondary system uses the frequency band assigned to the uplink of the primary system.
The wireless communication system in FIG. 26 includes a primary system 2110 and a secondary system 2120.

The primary system 2110 includes a primary system base station 2111 and a primary system mobile station 2112. The primary system mobile station 2112 transmits data to the primary system base station 2111, and the primary system base station 2111 receives data transmitted from the primary system mobile station 2112.
The secondary system 2120 includes a secondary system base station 2121 and a secondary system mobile station 2122. The secondary system mobile station 2122 transmits data to the secondary system base station 2121, and the secondary system base station 2121 receives data transmitted from the secondary system mobile station 2122.

  As an example of frequency sharing between the primary system and the secondary system, there is a standard IEEE802.22 WRAN (Wireless Regional Area Network) to which dynamic spectrum access is applied. IEEE 802.22 uses the existing primary system in the United States, terrestrial TV broadcasting and wireless microphone frequency bands, so that the secondary system can reduce the free frequency of the primary system so as to avoid interference with the primary system. This is the standard to use.

  As another example of frequency sharing between the primary system and the secondary system, UWB (Ultra Wide Band) is known in which the secondary system performs communication so that interference with the primary system is less than an allowable value. UWB realizes frequency sharing by spreading the transmission data of the secondary system over an extremely wide frequency band and transmitting the transmission power density of the secondary system at a power density smaller than a specified value.

  FIGS. 27A and 27B show examples of frequency sharing between the primary system and the secondary system. 27A and 27B, the horizontal axis represents frequency [Hz], and the vertical axis represents power density [dBm / Hz]. FIG. 27A shows an application example of dynamic spectrum access in which the secondary system performs communication using the free frequency spectrum of the primary system. In this example, the frequency spectrum 2211-1, 2121-2 of the primary system and the frequency spectrum 2212 of the secondary system are frequency shared so as not to overlap.

  FIG. 27B illustrates an example of UWB in which the secondary system performs communication with transmission power limited so that the interference power density to the primary system is less than or equal to an allowable value. In this example, the frequency spectrums 2221-1 and 221-2 of the primary system and the frequency spectrum 2222 of the secondary system are overlapped to share the frequency.

  In the example of FIG. 27A in which frequency sharing is performed so that the frequency spectrum of the primary system and the secondary system do not overlap, a condition in which the mutual interference between the primary system and the secondary system is small, that is, transmission of the secondary system. Even if the frequency spectrum is overlapped with the transmission frequency spectrum of the primary system, the frequency spectrum does not overlap when the interference is small. In addition, frequency sharing was not performed in consideration of interference received by the secondary system. As described above, in the example of FIG. 27A, there is a problem that the secondary system does not make maximum use of the frequency resources of the primary system.

  Further, in the example of FIG. 27B in which the frequency spectrum of the primary system and the secondary system are overlapped and the frequency is shared, there is a problem that the characteristics of the secondary system are significantly deteriorated when the secondary system is not a spread spectrum system. There was a point.

Further, there are techniques disclosed in Patent Document 1, Patent Document 2, Patent Document 3, Patent Document 4, and Patent Document 5 as related to the frequency sharing technology of the primary system and the secondary system.
In the technology disclosed in Patent Document 1, in a frequency coexistence environment in which a plurality of systems communicate in the same frequency band, transmission of a transmission / reception filter is performed based on the amount of interference or the center carrier frequency observed by the communication apparatus in the system. It controls the characteristics.

In the technique disclosed in Patent Document 2, in a frequency operation mode using a plurality of carriers, the base station notifies the mobile station of carrier information with a low degree of congestion.
In the technology disclosed in Patent Document 3, in a communication environment in which bidirectional communication is performed simultaneously in the same band, a base station calculates an eigenvalue of a channel correlation matrix indicating the characteristics of a bidirectional line based on the channel estimation value of its own system. It notifies the mobile station.

The technique disclosed in Patent Literature 4 is a base station that allocates a band to each terminal according to the order of SINR (Single to Interference and Noise Ratio) of each terminal in a communication environment using a plurality of frequency bands. .
The technique disclosed in Patent Document 5 uses the same frequency spectrum between adjacent cells in mobile communication and uniformly controls the transmission power of the frequency spectrum allocated to the mobile station in order to suppress inter-cell interference. is there.

JP 2006-352807 A JP 2007-129588 A JP 2007-267376 A JP 2007-274042 A JP 2006-352380 A

As described above, in the technology of sharing the frequency so that the frequency spectrum of the primary system and the secondary system do not overlap, there is a problem that the secondary system does not make maximum use of the frequency resources of the primary system. .
In addition, in the technology of sharing the frequency by overlapping the frequency spectrum of the primary system and the secondary system, there is a problem that the characteristics of the secondary system are significantly deteriorated when the secondary system is not a spread spectrum system.

In addition, the technique disclosed in Patent Document 1 has a problem in that the communication apparatus cannot control the transmission characteristics of the transmission / reception filter in consideration of the interference that the own system gives to other systems.
In addition, the technique disclosed in Patent Document 2 has a problem that it is not possible to reduce the mutual interference between systems due to the overlap of frequency spectra.

In addition, the techniques disclosed in Patent Literature 3 and Patent Literature 4 have a problem that mutual interference between systems cannot be reduced.
Further, the technique disclosed in Patent Document 5 has a problem that it is difficult to achieve both reduction of interference with other systems and improvement of the throughput of the own system.

  The present invention has been made to solve the above problems, and can improve the throughput of the own system while reducing the mutual interference between the own system and other systems with high accuracy, and maximize the use of frequency resources. An object of the present invention is to provide a wireless communication system, a wireless base station, a transmission / reception method, and a program that can be performed.

により前記スペクトル重複量ＯＦ１を計算することを特徴とするものである。 In a wireless communication system in which a plurality of systems share a frequency, the present invention provides measurement information on the boundary between the system and the secondary system based on a signal from the primary system mobile station and a signal from the secondary system mobile station. Measurement information of the system-to-system boundary between the primary system and the own system based on the signal from the primary system base station, the signal from the primary system mobile station, and the signal from the secondary system mobile station Based on the inter-system boundary measurement information and the inter-system boundary measurement information measured by the primary system base station, a part of the frequency spectrum of the own system is overlapped with the frequency spectrum of the primary system to transmit the signal of the own system. and a secondary system base station which performs the primary system base station, measuring a first system between the boundaries of measuring the system between the boundaries measurement information And a notification means for notifying the secondary system base station of inter-system boundary measurement information measured by the first inter-system boundary measuring means, wherein the secondary system base station is configured to measure the inter-system boundary measurement. Based on second inter-system boundary measuring means for measuring information, inter-system boundary measuring information notified from the second inter-system boundary measuring means, and inter-system boundary measuring information notified from the primary system base station The spectrum overlap amount determining means for determining the spectrum overlap amount of the frequency spectrum of the own system to be overlapped with the frequency spectrum of the primary system, and the spectrum overlap amount notified from the spectrum overlap amount determining means belong to the own system. Base station transmitting means for notifying the next system mobile station, and spectrum notified from the spectrum overlap amount determining means Base station receiving means for receiving a signal transmitted from the secondary system mobile station based on multiple quantities, and the spectrum overlap amount determining means is notified from the second inter-system boundary measuring means. The inter-system boundary measurement information includes the received power density P_MS1 _SBS of the frequency spectrum of the primary system mobile station measured by the second inter-system boundary measuring means and the secondary system movement measured by the second inter-system boundary measuring means. The frequency spectrum of the primary system mobile station measured by the first inter-system boundary measurement means is the received power density S_MS1 _SBS of the frequency spectrum of the station , and the inter-system boundary measurement information notified from the primary system base station Received power density P_MS1 of the secondary system mobile station received by the _PBS and the first inter-system boundary measuring means When the power density is S_MS1 _PBS and the weight addition coefficient is α (0 ≦ α ≦ 1),

The spectral overlap amount OF1 is calculated by the following.

により前記スペクトル重複量ＯＦ１を計算することを特徴とするものである。 In addition, the radio base station of the present invention measures and measures the measurement information of the inter-system boundary between the other system and the own system based on the signal from the mobile station of the other system and the signal from the mobile station of the own system. Based on the inter-system boundary measurement information and the inter-system boundary measurement information measured by the base station of the other system, a part of the frequency spectrum of the own system is overlapped with the frequency spectrum of the other system and signal transmission of the own system is performed. Means for measuring the inter-system boundary measurement information, the inter-system boundary measurement information notified from the inter-system boundary measurement means, and the base station of the other system Based on the inter-system boundary measurement information, the spectrum spectrum of the own system to be overlapped with the frequency spectrum of the other system Spectrum overlap amount determining means for determining the overlap amount, transmitting means for notifying the mobile station of the own system of the spectrum overlap amount notified from the spectrum overlap amount determining means, and spectrum overlap notified from the spectrum overlap amount determining means Receiving means for receiving a signal transmitted from the mobile station of the own system based on the amount, and the spectrum overlap amount determining means is configured to receive the inter-system boundary measurement information notified from the inter-system boundary measuring means. The received power density P_MS1 _SBS of the frequency spectrum of the mobile station of the other system measured by the inter-system boundary measuring means and the received power density S_MS1 _SBS of the frequency spectrum of the mobile station of the own system measured by the inter-system boundary measuring means . The inter-system boundary measurement information notified from the base station of the other system is the other system Is the received power density S_MS1 _PBS another system frequency spectrum of the received power density P_MS1 _PBS and the mobile station of the local system by the base station to measure the other system of the frequency spectrum of the mobile station of the base station measured systems out, weighted sum When the coefficient is α (0 ≦ α ≦ 1),

The spectral overlap amount OF1 is calculated by the following.

により前記スペクトル重複量ＯＦ１を計算することを特徴とするものである。 The present invention also relates to a transmission / reception method in which a plurality of systems share a frequency, in which the primary system base station and the secondary system based on the signal from the primary system mobile station and the signal from the secondary system mobile station. The first measurement step of measuring the measurement information of the inter-system boundary between and the primary system base station notifies the secondary system base station of the inter-system boundary measurement information measured in the first measurement step. A first notification step, and the secondary system base station measures the measurement information of the inter-system boundary between the primary system and the own system based on the signal from the primary system mobile station and the signal from the secondary system mobile station Based on the measured inter-system boundary measurement information and the inter-system boundary measurement information measured by the primary system base station. And a spectrum overlap amount control step for transmitting a signal of the own system by overlapping a part of the frequency spectrum of the own system with the frequency spectrum of the primary system , wherein the spectrum overlap amount control step includes: The system base station automatically overlaps the frequency spectrum of the primary system based on the intersystem boundary measurement information measured in the second measurement step and the intersystem boundary measurement information notified from the primary system base station. A spectrum overlap amount determining step for determining a spectrum overlap amount of a frequency spectrum of the system, and the secondary system base station notifying the secondary system mobile station belonging to the own system of the spectrum overlap amount determined in the spectrum overlap amount determining step. A second notification step, and the secondary system base station Receiving a signal transmitted from the secondary system mobile station based on the spectrum overlap amount determined in the step of determining the overlap amount of spectrum, and the step of determining the spectrum overlap amount in the second measurement step. The measured inter-system boundary measurement information includes the received power density P_MS1 _SBS of the frequency spectrum of the primary system mobile station measured in the second measurement step and the frequency spectrum of the secondary system mobile station measured in the second measurement step. a received power density S_MS1 _SBS, intersystem border measurement information reported from the primary system base station, the received power density P_MS1 _PBS of the frequency spectrum of the first primary system mobile station measured by the measurement step Received power density of the frequency spectrum of the secondary system mobile station measured in the first measurement step _MS1 a _PBS, when the weighting addition coefficient as α (0 ≦ α ≦ 1) ,

The spectral overlap amount OF1 is calculated by the following.

により前記スペクトル重複量ＯＦ１を計算することを特徴とするものである。 Further, the radio base station program of the present invention is a measurement step of measuring measurement information of a boundary between systems of the other system and the own system based on a signal from the mobile station of the other system and a signal from the mobile station of the own system. And based on the measured inter-system boundary measurement information and the inter-system boundary measurement information measured by the base station of the other system, a part of the frequency spectrum of the own system is overlapped with the frequency spectrum of the other system. A spectrum overlap amount control step for performing signal transmission of the system, and the spectrum overlap amount control step is performed between the inter-system boundary measurement information measured in the measurement step and the inter-system notified from the base station of the other system. Based on the boundary measurement information, the frequency of the local system is duplicated in the frequency spectrum of the other system. A spectrum overlap amount determining step for determining the spectrum overlap amount of several spectra, a notification step for notifying the mobile station of the own system of the spectrum overlap amount determined in the spectrum overlap amount determining step, and the spectrum overlap amount determining step A reception step of receiving a signal transmitted from the mobile station of the own system based on a spectrum overlap amount, wherein the spectrum overlap amount determination step includes an inter-system boundary measurement information measured in the measurement step, is the received power density S_MS1 _SBS of the frequency spectrum of the mobile station of the own system measured by the measuring step and the received power density P_MS1 _SBS of the frequency spectrum of the mobile station of other systems measured in step, the notification from the base station of the other system The inter-system boundary measurement information to be Is the received power density S_MS1 _PBS another system frequency spectrum of the received power density P_MS1 _PBS and the mobile station of the local system by the base station to measure the other system of the frequency spectrum of the mobile station of the base station measured systems out, weighted sum When the coefficient is α (0 ≦ α ≦ 1),

The spectral overlap amount OF1 is calculated by the following.

  According to the present invention, a part of the spectrum of the primary system and the secondary system is overlapped under a condition where the mutual interference between the primary system and the secondary system is small, and the amount of spectrum overlap is controlled so that the mutual interference becomes small. By doing so, it is possible to improve the throughput of the secondary system while maintaining the amount of interference with the primary system below the allowable value. Thereby, in this invention, a frequency resource can be utilized to the maximum.

It is a block diagram which shows the structure of the radio | wireless communications system which concerns on the 1st Embodiment of this invention. It is a block diagram which shows the detailed structure of the primary system base station in the radio | wireless communications system which concerns on the 1st Embodiment of this invention. It is a block diagram which shows the detailed structure of the secondary system base station in the radio | wireless communications system which concerns on the 1st Embodiment of this invention. It is a block diagram which shows the detailed structure of the secondary system mobile station in the radio | wireless communications system which concerns on the 1st Embodiment of this invention. It is a flowchart which shows operation | movement of the radio | wireless communications system which concerns on the 1st Embodiment of this invention. It is a figure which shows the relationship between the reception power density in the radio | wireless communications system which concerns on the 1st Embodiment of this invention, and the mutual interference between systems. It is a figure which shows the notification sequence of the information in the radio | wireless communications system which concerns on the 1st Embodiment of this invention. It is a figure which shows the example of the spectrum duplication amount control in the radio | wireless communications system which concerns on the 1st Embodiment of this invention. It is a figure which shows the example of the spectrum duplication amount control in the radio | wireless communications system which concerns on the 1st Embodiment of this invention. It is a block diagram which shows the detailed structure of the secondary system base station in the radio | wireless communications system which concerns on the 2nd Embodiment of this invention. It is a block diagram which shows the detailed structure of the secondary system mobile station in the radio | wireless communications system which concerns on the 2nd Embodiment of this invention. It is a figure which shows the example of the frequency resource arrangement | positioning in the radio | wireless communications system which concerns on the 2nd Embodiment of this invention. It is a figure which shows the example of ranking of the spectrum overlap amount in the 2nd Embodiment of this invention. It is a figure which shows the example of the frequency resource arrangement | positioning in the radio | wireless communications system which concerns on the 3rd Embodiment of this invention. It is a figure which shows the example of ranking of the spectrum duplication amount in the 3rd Embodiment of this invention. It is a figure which shows the example of the frequency resource arrangement | positioning in the radio | wireless communications system which concerns on the 3rd Embodiment of this invention. It is a figure which shows the example of ranking of the spectrum duplication amount in the 3rd Embodiment of this invention. It is a block diagram which shows the detailed structure of the primary system base station in the radio | wireless communications system which concerns on the 4th Embodiment of this invention. It is a figure which shows the notification sequence of the information in the radio | wireless communications system which concerns on the 4th Embodiment of this invention. It is a figure which shows the structure of the radio | wireless communications system which concerns on the 5th Embodiment of this invention. It is a figure which shows the signal which a primary system base station and a secondary system base station make an observation object in the radio | wireless communications system which concerns on the 5th Embodiment of this invention. It is a figure which shows the notification system of the secondary system known signal information and scheduling information between a secondary system base station and a primary system base station in the radio | wireless communications system which concerns on the 5th Embodiment of this invention. It is a flowchart which shows operation | movement of the primary system base station in the radio | wireless communications system which concerns on the 5th Embodiment of this invention. Information notification sequence between the primary system base station and the secondary system base station and between the secondary system base station and the secondary system mobile station in the wireless communication system according to the fifth embodiment of the present invention FIG. Information notification sequence between the primary system base station and the secondary system base station and between the secondary system base station and the secondary system mobile station in the wireless communication system according to the fifth embodiment of the present invention FIG. It is a block diagram which shows one structural example of the radio | wireless communications system to which dynamic spectrum access is applied. It is a figure which shows the frequency sharing example of a primary system and a secondary system.

  FIG. 1 is a block diagram showing a configuration of a radio communication system according to the first embodiment of the present invention. Hereinafter, in the present embodiment, a wireless communication system using a certain frequency band is a primary system, and a wireless communication system sharing at least a part of the frequency band with the primary system is a secondary system. The radio communication system according to the present embodiment is an example in which a primary system and a secondary system share a frequency using an uplink. This wireless communication system includes a primary system base station 101, a secondary system base station 102, a secondary system mobile station 103, and a primary system mobile station 104.

  The primary system base station 101 receives the signal from the primary system mobile station 104 and the signal from the secondary system mobile station 103, and measures the received signal at the boundary between the primary system and the secondary system. The measurement signal is output to the secondary system base station 102 by wire or wireless.

  The secondary system base station 102 receives the signal from the primary system mobile station 104 and the signal from the secondary system mobile station 103, and measures the received signal at the intersystem boundary between the primary system and the secondary system. The amount of spectrum overlap between the primary system and the secondary system is determined in consideration of the measurement signal of the inter-system boundary notified from the primary system base station 101. Here, as the measurement signal at the inter-system boundary, for example, reception power density, channel estimation value, reception power, and electric field strength can be used. The secondary system base station 102 notifies the determined amount of spectrum overlap to the secondary system mobile station 103 via a wireless line.

  Based on the spectrum overlap amount notified from the secondary system base station 102, the secondary system mobile station 103 overlaps the frequency spectrum of the primary system with a part of the frequency spectrum of its own system and outputs a transmission signal.

FIG. 2 shows a detailed configuration of the primary system base station 101 in the wireless communication system of FIG. The primary system base station 101 includes an inter-system boundary received signal measurement unit 1010, a notification unit 1011, a transmission unit 1012, and a reception unit 1013.
Inter-system boundary received signal measurement section 1010 measures the received signal at the inter-system boundary between the own system and the secondary system at its own base station (primary system base station 101), and outputs the measured received signal to notification section 1011. To do.

The notification unit 1011 notifies the secondary system base station 102 of the measured inter-system boundary measurement signal.
The transmitting unit 1012 transmits a signal to the primary system mobile station 104 via a wireless line, and the receiving unit 1013 receives signals from the primary system mobile station 104 and the secondary system mobile station 103 via the wireless line. To do.

FIG. 3 shows a detailed configuration of the secondary system base station 102 in the wireless communication system of FIG. The secondary system base station 102 includes an inter-system boundary received signal measurement unit 1020, a spectrum overlap amount determination unit 1021, a transmission unit 1022, and a reception unit 1023.
Inter-system boundary received signal measuring section 1020 measures the received signal at the inter-system boundary between the primary system and the own system in the own base station (secondary system base station 102), and uses the measured received signal as a spectrum overlap amount determining section. To 1021.

  The spectrum overlap amount determination unit 1021 uses the inter-system boundary measurement signal notified from the inter-system boundary received signal measurement unit 1020 and the inter-system boundary measurement signal notified from the primary system base station 101 to The spectrum overlap amount with the secondary system is determined, and the determined spectrum overlap amount is notified to the transmission unit 1022 and the reception unit 1023.

  The transmitting unit 1022 transmits a signal to the secondary system mobile station 103 via a wireless line within the transmission / reception band of the own system determined by the spectral overlapping amount notified from the spectral overlapping amount determining unit 1021. Specifically, the transmission / reception band control is realized by controlling the filter coefficient of a transmission filter (not shown) in the transmission unit 1022 based on the spectrum overlap amount. Further, the transmission unit 1022 notifies the secondary system mobile station 103 of the spectrum overlap amount notified from the spectrum overlap amount determination unit 1021.

  The reception unit 1023 receives a signal transmitted from the secondary system mobile station 103 within the transmission / reception band of the own system determined by the spectrum overlap amount notified from the spectrum overlap amount determination unit 1021. Specifically, this transmission / reception band control is realized by controlling the filter coefficient of a reception filter (not shown) in the reception unit 1023 based on the amount of spectrum overlap.

FIG. 4 shows a detailed configuration of the secondary system mobile station 103 in the wireless communication system of FIG. The secondary system mobile station 103 includes a receiving unit 1030, a transmitting unit 1031 and a spectrum overlap amount control unit 1032.
The receiving unit 1030 receives a signal from the secondary system base station 102 via a wireless line, and the transmitting unit 1031 transmits a signal to the secondary system base station 102 via a wireless line.

  The spectrum overlap amount control unit 1032 causes the transmission unit 1031 to transmit a signal and the reception unit 1030 to receive the signal within the transmission / reception band of the own system determined by the spectrum overlap amount notified from the secondary system base station 102. Specifically, the transmission / reception band is controlled by controlling the filter coefficient of a transmission filter (not shown) in the transmission unit 1031 and the filter coefficient of a reception filter (not shown) in the reception unit 1030 based on the spectrum overlap amount. This is realized.

FIG. 5 shows the overall operation flow of the wireless communication system of the present embodiment. 5 will be described with reference to the configuration of FIG.
The primary system base station 101 and the secondary system base station 102 receive a known signal or data transmitted from the primary system mobile station 104 (step A01).

The primary system base station 101 and the secondary system base station 102 receive a known signal or data transmitted from the secondary system mobile station 103 using the free frequency spectrum of the primary system (step A02).
The primary system base station 101 and the secondary system base station 102 are based on the signal received from the primary system mobile station 104 and the signal received from the secondary system mobile station 103, respectively. The received signal at the system boundary is measured (step A03).

The secondary system base station 102 determines the spectrum overlap amount based on the inter-system boundary measurement signal notified from the primary system base station 101 and the inter-system boundary measurement signal measured in the own base station, and then determines the determined spectrum overlap. The amount is notified to the secondary system mobile station 103 (step A04).
Based on the spectrum overlap amount notified from the secondary system base station 102, the secondary system mobile station 103 transmits a signal by overlapping the frequency spectrum of the primary system and a part of the frequency spectrum of its own system (step). A05).

  FIG. 6 shows the result of the received power density of the primary system and the received power density of the secondary system in the primary system base station 101, the received power density of the primary system in the secondary system base station 102, and the secondary system It is a figure which shows the relationship between the result of the magnitude of a received power density, and the mutual interference between systems.

  In the primary system base station 101, the received power density of the primary system is larger than the received power density of the secondary system. In the secondary system base station 102, the received power density of the primary system is larger than the received power density of the secondary system. When small, the mutual interference between the primary system and the secondary system becomes small. At this time, if the frequency spectrum of the primary system and the frequency spectrum of the secondary system overlap, the mutual interference between the primary system and the secondary system is small. That is, in this case, the conditions are suitable for spectrum overlap.

  The primary system base station 101 has a lower primary system received power density than the secondary system received power density, and the secondary system base station 102 has a primary system received power density lower than the secondary system received power density. When it is large, the mutual interference between the primary system and the secondary system becomes large. At this time, if the frequency spectrum of the primary system and the frequency spectrum of the secondary system overlap, the mutual interference between the primary system and the secondary system is large. That is, in this case, the condition is not suitable for spectrum overlap.

FIG. 7 shows a notification sequence of information among the primary system base station 101, the secondary system base station 102, and the secondary system mobile station 103 shown in FIG.
The primary system base station 101 notifies the secondary system base station 102 of the inter-system boundary measurement signal 501.
Next, the secondary system base station 102 notifies the secondary system mobile station 103 of the spectrum overlap amount 502.

  FIG. 8A, FIG. 8B, FIG. 9A, and FIG. 9B are diagrams showing examples of spectrum overlap amount control according to the present embodiment, and are the primary system mobile station 104-1. The secondary system mobile station 103 transmits a signal and communicates using the vacant frequency spectrum 602 of the primary system sandwiched between the frequency spectrum 601-1 of the primary system and the frequency spectrum 601-2 of the primary system mobile station 104-2. An example is shown. 8A and 8B, the horizontal axis represents frequency, and the vertical axis represents received power density. 9A and 9B, the horizontal axis represents frequency and the vertical axis represents transmission power density.

FIG. 8A shows that when the primary system base station 101 measures the received power density, the received power density of the primary system mobile station 104-1 is equal to the received power density of the primary system mobile station 104-2. An example is shown in which the received power density of the secondary system mobile station 103 is smaller than the received power density of the primary system mobile stations 104-1 and 104-2. In this example, for the primary system, the secondary system mobile station 103 is an interference source. Here, P_MS1 _PBS is the received power density of the frequency spectrum 601-1 of the primary system mobile station 104-1 measured at the primary system base station 101, and P_MS2 _PBS is the primary system movement measured at the primary system base station 101. The reception power density of the frequency spectrum 601-2 of the station 104-2, S_MS1 _PBS is the reception power density of the frequency spectrum 602 of the secondary system mobile station 103 measured in the primary system base station 101.

FIG. 8B shows that when the secondary system base station 102 measures the received power density, the received power density of the primary system mobile station 104-2 is higher than the received power density of the primary system mobile station 104-1. Largely, an example is shown in which the received power density of the secondary system mobile station 103 is larger than the received power density of the primary system mobile station 104-2. In this example, the primary system mobile stations 104-1 and 104-2 serve as interference sources for the secondary system. Here, P_MS1 _SBS is the received power density of the frequency spectrum 601-1 of the primary system mobile station 104-1 measured at the secondary system base station 102, and P_MS2 _SBS is the primary system mobility measured at the secondary system base station 102. The reception power density of the frequency spectrum 601-2 of the station 104-2, S_MS1 _SBS is the reception power density of the frequency spectrum 602 of the secondary system mobile station 103 measured at the secondary system base station 102.

  FIG. 9A shows an example of spectrum overlap of the secondary system with respect to the primary system. Since the boundary between the frequency spectrum 601-1 of the primary system mobile station 104-1 and the frequency spectrum 602 of the secondary system mobile station 103 has a small mutual interference when the spectrum is overlapped, the amount of spectrum overlap can be increased. .

  The boundary between the frequency spectrum 601-2 of the primary system mobile station 104-2 and the frequency spectrum 602 of the secondary system mobile station 103 is such that mutual interference when the spectrum is overlapped is that of the primary system mobile station 104-1. It becomes larger than the boundary between the frequency spectrum 601-1 and the frequency spectrum 602 of the secondary system mobile station 103. Therefore, the amount of spectrum overlap between the frequency spectrum 601-2 of the primary system mobile station 104-2 and the frequency spectrum 602 of the secondary system mobile station 103 is equal to the frequency spectra 601-1 and 2 of the primary system mobile station 104-1. It is made smaller than the amount of spectrum overlap of the frequency spectrum 602 of the next system mobile station 103.

  Next, a calculation example of the spectrum overlap amount is shown. The amount of spectrum overlap between the frequency spectrum 601-1 of the primary system mobile station 104-1 and the frequency spectrum 602 of the secondary system mobile station 103 is defined as OF1, and the frequency spectrum 601-2 and secondary of the primary system mobile station 104-2 are secondary. If the spectrum overlap amount of the frequency spectrum 602 of the system mobile station 103 is OF2, the spectrum overlap amounts OF1 and OF2 are expressed by, for example, the following equations.

  In Expressions (1) and (2), α (0 ≦ α ≦ 1) is a weight addition coefficient between the reception power density ratio in the primary system base station 101 and the reception power density ratio in the secondary system base station 102. . The larger the weight addition coefficient α, the larger the received power density ratio in the primary system base station 101 is reflected in the spectrum overlap amounts OF1 and OF2, and the smaller the weight addition coefficient α, the more the received power density ratio in the secondary system base station 102 is the spectrum. The overlap amounts OF1 and OF2 are greatly reflected.

The spectrum overlap amount determination unit 1021 of the secondary system base station 102 includes intersystem boundary measurement signals (reception power densities P_MS1 _SBS , P_MS2 _SBS , S_MS1 _SBS ) notified from the intersystem boundary reception signal measurement unit 1020, and the primary system. Using the inter-system boundary measurement signals (reception power density P_MS1 _PBS , P_MS2 _PBS , S_MS1 _PBS ) notified from the base station 101, the primary system mobile station 104-1 Spectrum overlap amount OF1 of frequency spectrum 601-1 and frequency spectrum 602 of secondary system mobile station 103 OF1, spectrum overlap of frequency spectrum 601-2 of primary system mobile station 104-2 and frequency spectrum 602 of secondary system mobile station 103 The quantity OF2 is calculated.

  The transmission unit 1022 of the secondary system base station 102 transmits a signal to the secondary system mobile station 103 within the transmission / reception band of the own system determined by the spectrum overlap amounts OF1 and OF2 notified from the spectrum overlap amount determination unit 1021. Also, the transmission unit 1022 notifies the secondary system mobile station 103 of the spectrum overlap amounts OF1, OF2 notified from the spectrum overlap amount determination unit 1021.

  The spectrum overlap amount control unit 1032 of the secondary system mobile station 103 causes the transmitting unit 1031 to transmit a signal within the transmission / reception band of the own system determined by the spectrum overlap amounts OF1 and OF2 notified from the secondary system base station 102.

  The receiving unit 1023 of the secondary system base station 102 receives a signal transmitted from the secondary system mobile station 103 within the transmission / reception band of the own system determined by the spectrum overlap amount OF1 and OF2 notified from the spectrum overlap amount determination unit 1021. Receive.

  As described above, in the present embodiment, by controlling the amount of spectrum overlap according to the received power density at the inter-system boundary measured by the primary system base station 101 and the secondary system base station 102, When the mutual interference is small, the amount of spectral overlap between systems can be increased. When the mutual interference between systems is large, the amount of spectral overlap between systems can be reduced. The control can be made smaller than the value, and the throughput of the secondary system can be improved.

FIG. 9B shows an example in which transmission power control is performed simultaneously with spectrum duplication control of the secondary system. 9B, the frequency spectrum of the secondary system is overlapped with the frequency spectrum of the primary system according to the amount of spectrum overlap as in FIG. 9A, and the transmission power of the spectrum overlap component of the secondary system is controlled. An example is shown. The control of the amount of spectrum overlap is as described with reference to FIG.
The transmission power density TPD (Transmission Power Density) of the spectrum overlap portion is expressed by either one of Expression (3) or Expression (4), for example.

  Moreover, you may obtain | require the transmission power density TPD of a spectrum overlap part by following Formula.

  In equation (5), α (0 ≦ α ≦ 1) is the received power density ratio between the primary system mobile station 104-1 and the secondary system mobile station 103 in the primary system base station 101, and the primary system base station. 101 is a weighted addition coefficient of the received power density ratio of the primary system mobile station 104-2 and the secondary system mobile station 103 in 101. The larger the weight addition coefficient α is, the larger the reflected power density ratio between the primary system mobile station 104-1 and the secondary system mobile station 103 is reflected in the transmission power density TPD, and the smaller the weight addition coefficient α is, the primary system mobile station 104. -2 and the reception power density ratio of the secondary system mobile station 103 are greatly reflected in the transmission power density TPD.

The spectrum overlap amount determination unit 1021 of the secondary system base station 102 includes a transmission power density determination unit (not shown) therein. The transmission power density determination unit calculates the transmission power density TPD according to any one of Expression (3), Expression (4), and Expression (5).
The transmission unit 1022 of the secondary system base station 102 notifies the secondary system mobile station 103 of the transmission power density TPD notified from the transmission power density determination unit.

  The spectrum overlap amount control unit 1032 of the secondary system mobile station 103 has a transmission power control unit (not shown) therein. The transmission power control unit includes a spectrum overlapping portion with the frequency spectrum 601-1 of the primary system mobile station 104-1 and a frequency spectrum 601-2 of the primary system mobile station 104-2 in the transmission / reception band of the own system. The transmission power of the spectrum overlap portion is controlled according to the transmission power density TPD notified from the secondary system base station 102.

  As described above, in this embodiment, by controlling the transmission power of the spectrum overlap portion of the secondary system, the interference with the primary system can be flexibly compared with the case where the transmission power of the spectrum overlap portion is not controlled. And interference with the primary system can be reduced.

  In the technique disclosed in Patent Document 1, the communication device cannot control the transmission characteristics of the transmission / reception filter in consideration of interference that the own system gives to other systems. On the other hand, in the present embodiment, it is possible to control the transmission / reception band (filter characteristics of the transmission / reception filter) of the secondary system in consideration of interference given to the primary system by the secondary system.

  In addition, the techniques disclosed in Patent Literature 2, Patent Literature 3, and Patent Literature 4 cannot reduce mutual interference between systems. On the other hand, in this embodiment, the amount of spectrum overlap is determined according to the inter-system boundary measurement signal, and the transmission / reception band of the secondary system is controlled based on the amount of spectrum overlap, thereby reducing mutual interference between systems. Can be reduced.

  Further, with the technique disclosed in Patent Document 5, it is difficult to achieve both reduction in interference with other systems and improvement in throughput of the own system. In contrast, in the present embodiment, the transmission power of the overlapping spectrum and the non-overlapping spectrum can be controlled separately, so that the throughput of the secondary system can be improved while suppressing interference with the primary system.

[Second Embodiment]
Next, a second embodiment of the present invention will be described. When applying a roll-off filter in single carrier transmission, improvements in PAPR (Peak to Average Power Ratio), timing error tolerance, and frequency error tolerance can be cited as advantages, but bandwidth efficiency is sacrificed by widening the band. . Therefore, in this embodiment, the transmission spectrum of the secondary system to which roll-off transmission is applied is arranged in the free spectrum of the primary system having a large amount of spectrum overlap at the inter-system boundary.

  Also in the present embodiment, the overall configuration of the wireless communication system and the configuration of the primary system base station 101 are the same as those in the first embodiment, and will be described using the reference numerals in FIG. FIG. 10 is a block diagram showing a detailed configuration of secondary system base station 102 of the present embodiment that performs frequency resource allocation in consideration of the inter-system boundary measurement signal during roll-off transmission.

The secondary system base station 102 of this embodiment includes an inter-system boundary received signal measurement unit 1020, a spectrum overlap amount determination unit 1021, a transmission unit 1022a, a reception unit 1023a, a spectrum overlap amount ranking unit 1024, a frequency And a resource arrangement determining unit 1025.
Since the operations of the inter-system boundary received signal measurement unit 1020, the spectrum overlap amount determination unit 1021, the transmission unit 1022a, and the reception unit 1023a are the same as those in the first embodiment, the spectrum overlap amount ranking unit 1024 and the frequency resource allocation determination The configuration and operation of the unit 1025 will be described.

  The spectrum overlap amount ranking unit 1024 combines and pairs the spectrum overlap amounts notified from the spectrum overlap amount determination unit 1021, and then ranks the paired spectrum overlap amounts. Then, the spectrum overlap amount ranking unit 1024 notifies the frequency resource arrangement determination unit 1025 of the ranking result.

  The frequency resource allocation determination unit 1025 determines the frequency resource allocation of the secondary system based on the ranking result notified from the spectrum overlap amount ranking unit 1024, and transmits the frequency resource allocation information to the transmission unit 1022a and the reception unit 1023a. Output.

FIG. 11 shows a detailed configuration of secondary system mobile station 103 in the wireless communication system of the present embodiment. The secondary system mobile station 103 includes a receiving unit 1030a, a transmitting unit 1031a, and a frequency resource allocation control unit 1033.
The frequency resource allocation control unit 1033 causes the transmission unit 1031a to transmit a signal and the reception unit 1030a to receive the signal within the transmission / reception band of the own system determined by the frequency resource allocation notified from the secondary system base station 102. Specifically, the transmission / reception band control is performed based on the frequency resource arrangement information by controlling the transmission frequency conversion unit and the filter coefficient of the transmission filter (not shown) in the transmission unit 1031a and the reception frequency (not shown) in the reception unit 1030a. This is realized by controlling the filter coefficients of the conversion unit and the reception filter.

  FIG. 12 is a diagram illustrating an example of frequency resource arrangement during transmission to which a roll-off filter is applied. FIG. 12 shows an example in which the frequency spectrum 802 of the secondary system is arranged using the free spectrum of the frequency spectrum 801-1 to 801-4 of the primary system.

  An example of the operation of the spectrum overlap amount ranking unit 1024 will be described with reference to FIGS. 12, 13A, and 13B. Here, an example of ranking the spectral overlap amounts OF1 to OF7 calculated at the system boundary between the primary system and the secondary system is shown. FIG. 12 shows an example in which when there is an empty spectrum between the frequency spectra 801-1 to 801-4 of the primary system, the two spectrum overlap amounts on both sides of this empty spectrum are paired and the spectrum overlap amount is paired. Show. In the example of FIG. 12, the spectrum overlap amounts OF1 and OF2, the spectrum overlap amounts OF3 and OF4, and the spectrum overlap amounts OF5 and OF6 are paired.

  FIG. 13A shows an example in which a multiplication rule is used as a method of ranking the paired spectrum overlap amounts. In the multiplication rule, two paired spectrum overlap amounts are multiplied, and the spectrum overlap amount is ranked based on the multiplied value. In the multiplication rule, when both of the paired spectrum overlap amounts are large, the spectrum overlap amount is ranked higher. In the example of FIG. 13A, the spectral overlap amounts OF3 and OF4 are paired, the spectral overlap amounts OF1 and OF2 are paired, and the spectral overlap amounts OF5 and OF6 are ranked in this order.

  FIG. 13B shows an example in which an addition rule is used as a method for ranking the paired spectrum overlap amounts. In the addition rule, two paired spectrum overlap amounts are added, and the spectrum overlap amount is ranked based on the added value. In the addition rule, even if one of the paired two spectrum overlap amounts is small, the remaining one may be ordered higher when the other one is large. In the example of FIG. 13B, the spectral overlap amounts OF3 and OF4 are paired, the spectral overlap amounts OF1 and OF2 are paired, and the spectral overlap amounts OF5 and OF6 are ranked in this order.

  Thus, the spectrum overlap amount ranking unit 1024 pairs the spectrum overlap amounts, ranks the paired spectrum overlap amounts, and notifies the frequency resource arrangement determination unit 1025 of the rank of the spectrum overlap amount.

  Next, an operation example of the frequency resource arrangement determination unit 1025 will be described. The frequency resource allocation determining unit 1025 refers to the rank of the paired spectrum overlap amount notified from the spectrum overlap amount ranking unit 1024, and sets the higher order spectrum overlap amount pair in the free spectrum of the primary system. The frequency spectrum 802 of the secondary system is arranged in the sandwiched empty spectrum.

  In the examples of FIGS. 12, 13A, and 13B, the multiplication value and the addition value of the spectrum overlap amount calculated from the spectrum overlap amount OF3 and the spectrum overlap amount OF4 are large. Therefore, the frequency resource arrangement determining unit 1025 arranges the frequency spectrum 802 of the secondary system in the free spectrum of the primary system sandwiched between the inter-system boundaries corresponding to the spectrum overlap amount OF3 and the spectrum overlap amount OF4 on the frequency axis. Thus, the frequency resource allocation is determined. The frequency resource arrangement determination unit 1025 notifies the transmission unit 1022 and the reception unit 1023 of the determined frequency resource arrangement.

  The transmission unit 1022a of the secondary system base station 102 transmits a signal to the secondary system mobile station 103 within the transmission / reception band of the own system determined by the frequency resource allocation notified from the frequency resource allocation determination unit 1025. Specifically, the transmission / reception band control is realized by controlling filter coefficients of a transmission frequency conversion unit and a transmission filter (not shown) in the transmission unit 1022a based on the frequency resource arrangement information. In addition, the transmission unit 1022a notifies the secondary system mobile station 103 of the frequency resource allocation notified from the frequency resource allocation determination unit 1025.

  The frequency resource allocation control unit 1033 of the secondary system mobile station 103 causes the transmission unit 1031a to transmit a signal within the transmission / reception band of the own system determined by the frequency resource allocation notified from the secondary system base station 102.

  The receiving unit 1023a of the secondary system base station 102 receives a signal transmitted from the secondary system mobile station 103 within the transmission / reception band of the own system determined by the frequency resource allocation notified from the frequency resource allocation determining unit 1025. Specifically, the transmission / reception band control is realized by controlling filter coefficients of a reception frequency conversion unit and a reception filter (not shown) in the reception unit 1023a based on the frequency resource arrangement information.

  As described above, in the present embodiment, the mutual interference between the frequency spectrum 801-2 and 801-3 of the primary system and the frequency spectrum 802 of the secondary system can be reduced, so that the bandwidth efficiency of the secondary system is sacrificed. It can be made small, and the advantage at the time of roll-off application can be obtained.

  In the technique disclosed in Patent Document 1, the communication device cannot control the transmission characteristics of the transmission / reception filter in consideration of interference that the own system gives to other systems. On the other hand, in this Embodiment, the interference to the primary system by a secondary system can be reduced with high precision by performing frequency resource arrangement | positioning based on the inter-system boundary measurement signal.

[Third Embodiment]
Next, a third embodiment of the present invention will be described. Also in the present embodiment, the overall configuration of the radio communication system and the configuration of the primary system base station 101 are the same as those in the first embodiment, and the configurations of the secondary system base station 102 and the secondary system mobile station 103 are the same. Is the same as that of the second embodiment, and will be described using the reference numerals in FIGS.

  The present embodiment shows another example of the frequency resource arrangement described in the second embodiment. In the present embodiment, as in the second embodiment, the transmission spectrum of the secondary system is arranged in the free spectrum of the primary system where the amount of spectrum overlap at the inter-system boundary is large, and the transmission / reception filter gain of the secondary system By overlapping the spectral components in the region where the frequency is small (the region where the transmission / reception power density is low) overlapping the frequency spectrum of the primary system, the sacrifice of bandwidth efficiency is reduced.

FIG. 14 shows an example of the frequency resource arrangement of the present embodiment. FIG. 14 shows an example in which the frequency spectrum 1002 of the secondary system is decomposed into two blocks, frequency spectra 1002-1 and 1002-2, and the frequencies are arranged.
FIG. 15 shows the rank of the spectral overlap amount in the example of FIG. The spectrum overlap amount ranking unit 1024 of the secondary system base station 102 according to the present embodiment ranks the spectrum overlap amount notified from the spectrum overlap amount determination unit 1021 according to the size thereof.

  In the example of FIG. 15, the spectrum overlap amount OF6 is the largest, and the spectrum overlap amount OF1 is the next largest. Therefore, the frequency resource allocation determining unit 1025 divides the frequency spectrums 1002-1 and 1002 into two blocks into the inter-system boundary corresponding to the spectral overlap amount OF6 and the inter-system boundary corresponding to the spectral overlap amount OF1 on the frequency axis. -2. At that time, the frequency resource allocation determining unit 1025 overlaps the frequency spectrum component in the region where the filter gain of the transmission / reception filter of the own system is small with the frequency spectrum of the primary system corresponding to the spectrum overlap amount OF6, OF1 on the frequency axis. .

  In the example of FIG. 14, the frequency spectrum component on the low frequency side where the filter gain of the transmission / reception filter of the secondary system is small is overlapped with the frequency spectrum of the primary system corresponding to the spectrum overlap amount OF1, and the secondary system. The frequency spectrum component on the high frequency side where the filter gain of the transmission / reception filter is small is overlapped with the frequency spectrum of the primary system corresponding to the spectrum overlap amount OF6.

  Thus, in this embodiment, the frequency spectrum 1001-1 of the primary system mobile station, the frequency spectrum 1002-1 of the secondary system mobile station, the frequency spectrum 1001-4 of the primary system mobile station, and the secondary system mobile station The sacrifice of the frequency band efficiency of the secondary system can be reduced while suppressing the mutual interference of the frequency spectrum 1002-2.

FIG. 16 shows another example of the frequency resource arrangement according to the present embodiment. FIG. 16 shows an example in which the frequency spectrum 1202 of the secondary system is decomposed into three blocks of frequency spectra 1202-1, 1202-2, and 1202-3, and the frequencies are arranged.
FIG. 17 shows the rank of the spectrum overlap amount in the example of FIG.

  In the example of FIG. 17, the spectrum overlap amount OF1 is the largest, and the spectrum overlap amount OF6 is the next largest. Therefore, the frequency resource arrangement determining unit 1025 overlaps the frequency spectrum component in the region where the filter gain of the transmission / reception filter of the own system is small with the frequency spectrum of the primary system corresponding to the spectrum overlap amounts OF1 and OF6 on the frequency axis.

  That is, the frequency resource arrangement determining unit 1025 arranges the frequency spectrum component on the low frequency side where the filter gain of the transmission / reception filter of the secondary system is small in the frequency spectrum of the primary system corresponding to the spectrum overlap amount OF1. As described above, the frequency spectrum 1202-1 of the secondary system is arranged between the frequency spectra 1201-1 and 1201-2 of the primary system. Further, the frequency resource arrangement determining unit 1025 arranges the frequency spectrum component on the high frequency side where the filter gain of the transmission / reception filter of the secondary system is small in the frequency spectrum of the primary system corresponding to the spectrum overlap amount OF6. Thus, the frequency spectrum 1202-3 of the secondary system is arranged between the frequency spectra 1201-3 and 1201-4 of the primary system. Further, the frequency resource arrangement determining unit 1025 arranges the remaining frequency spectrum 1202-2 of the secondary system between the frequency spectra 1201-2 and 1201-3 of the primary system.

  Thus, in this embodiment, the frequency spectrum 1201-1 of the primary system mobile station, the frequency spectrum 1202-1 of the secondary system mobile station, the frequency spectrum 1201-4 of the primary system mobile station, and the secondary system mobile station The sacrifice of the frequency band efficiency of the secondary system can be reduced while suppressing the mutual interference of the frequency spectrum 1202-3.

[Fourth Embodiment]
Next, a fourth embodiment of the present invention will be described. Also in this embodiment, the overall configuration of the wireless communication system is the same as that of the first embodiment, and therefore, description will be made using the reference numerals in FIG.
FIG. 18 shows a detailed configuration of primary system base station 101 in the wireless communication system of the present embodiment. The primary system base station 101 includes an inter-system boundary received signal measurement unit 1010, a notification unit 1011b, a transmission unit 1012, a reception unit 1013, and an interference amount determination unit 1014.

When the primary system base station 101 determines that the interference level is large due to spectrum overlap with the secondary system and the interference level determination unit 1014 cannot satisfy the required quality of the own system, the interference level determination unit 1014 outputs an interference restriction signal.
The notification unit 1011b outputs the interference restriction signal output from the interference amount determination unit 1014 to the secondary system base station 102.
The configurations of the secondary system base station 102 and the secondary system mobile station 103 are the same as those in the first embodiment.

FIG. 19 shows a notification sequence of information among primary system base station 101, secondary system base station 102, and secondary system mobile station 103 in the present embodiment.
As described in the first embodiment, the primary system base station 101 notifies the secondary system base station 102 of the inter-system boundary measurement signal 501, and the secondary system base station 102 moves the secondary system. The station 103 is notified of the spectrum overlap amount 502.

  Next, the interference amount determination unit 1014 of the primary system base station 101 measures the interference amount between the own system and the secondary system. Examples of information indicating the amount of interference include SIR (Signal to Interference Ratio), INR (Interference to Noise Ratio), BER (Bit Error Rate), and throughput degradation. The interference amount determination unit 1014 notifies the secondary system base station 102 of the interference restriction signal 503 when determining that the measured interference amount is larger than the predetermined allowable interference amount and does not satisfy the required quality of the own system.

  When receiving the interference limiting signal 503 from the primary system base station 101, the spectrum overlap amount determination unit 1021 of the secondary system base station 102 sets the spectrum overlap amount so as to reduce the spectrum overlap between the primary system and the secondary system. Redetermine. The transmission unit 1022 of the secondary system base station 102 notifies the secondary system mobile station 103 of the spectrum overlap amount 504 re-determined by the spectrum overlap amount determination unit 1021.

The spectrum duplication amount control unit 1032 of the secondary system mobile station 103 causes the transmission unit 1031 to transmit a signal within the transmission / reception band of the own system determined by the spectrum duplication amount 504 notified from the secondary system base station 102, and the reception unit Let 1030 receive the signal.
The reception unit 1023 of the secondary system base station 102 receives a signal transmitted from the secondary system mobile station 103 within the transmission / reception band of the own system determined by the spectrum overlap amount 504 re-determined by the spectrum overlap amount determination unit 1021. .

  With the above operation, in the present embodiment, when the amount of spectrum overlap between the primary system and the secondary system is excessively set, interference can be controlled from the primary system to the secondary system. The allowable interference amount and required communication quality of the next system can be ensured.

[Fifth Embodiment]
Next, a fifth embodiment of the present invention will be described. FIG. 20 shows the configuration of a wireless communication system in a multi-cell environment according to this embodiment. In the present embodiment, the first to fourth embodiments are applied to a multi-cell environment. In FIG. 20, the wireless communication system includes a primary system 1510, a secondary system 1520, a secondary system 1530, and a secondary system 1540.

The primary system 1510 includes a primary system base station 1511, a primary system mobile station 1512, and a primary system mobile station 1513.
The secondary system 1520 includes a secondary system base station 1521 and a secondary system mobile station 1522.

The secondary system 1530 includes a secondary system base station 1531 and a secondary system mobile station 1532.
The secondary system 1540 includes a secondary system base station 1541.

  In the multi-cell environment, the primary system base station 1511 receives the secondary system mobile station 1522 and the secondary system mobile station 1532 in addition to signals from the primary system mobile station 1512 and the primary system mobile station 1513 that are desired signals. The signal from is received simultaneously. For the primary system base station 1511, signals from the secondary system mobile station 1522 and the secondary system mobile station 1532 become interference signals.

  The secondary system base station 1521 simultaneously receives signals from the primary system mobile station 1512 and the secondary system mobile station 1532 in addition to the desired signal from the secondary system mobile station 1522. For the secondary system base station 1521, signals from the primary system mobile station 1512 and the secondary system mobile station 1532 become interference signals.

  Further, the secondary system base station 1531 simultaneously receives signals from the primary system mobile station 1512 and the secondary system mobile station 1522 in addition to the desired signal from the secondary system mobile station 1532. For the secondary system base station 1531, signals from the primary system mobile station 1512 and the secondary system mobile station 1522 become interference signals.

The prerequisites for operation in a multi-cell environment are shown below.
(A) The secondary system communicates using frequency resources that are not used by the primary system and other secondary systems.
(B) The primary system base station is notified of known signals and scheduling information of all primary system mobile stations and all secondary system mobile stations that should consider interference.
(C) The known signals of all primary system mobile stations and all secondary system mobile stations to be considered for interference are different.
(D) In the processing of the primary system base station, it can be synchronized with the known signal of each secondary system mobile station.

FIG. 21 shows signals to be observed by the primary system base station and the secondary system base station in a multi-cell environment. FIG. 21 shows the presence / absence of signal discrimination between a desired signal to be observed and an interference signal.
The observation target of the own system observed by the primary system base station is a signal from the primary system mobile station. Since the primary system base station also receives signals other than those of the primary system mobile station, it is necessary to determine the signal.

The observation target of the other system observed by the primary system base station is a signal from the secondary system mobile station to be controlled. Since the primary system base station also receives signals other than the secondary system mobile station to be controlled, it is necessary to determine the signal.
The observation target of the own system observed by the secondary system base station is a signal from the secondary system mobile station. In the state where the signal is transmitted from the secondary system mobile station, there is no other received signal, so the secondary system base station does not need to determine the signal.

The observation target of the other system observed by the secondary system base station is all signals in the frequency spectrum adjacent to the frequency spectrum of the own system. Since all the interference components are viewed from the secondary system base station, the secondary system base station does not need to determine the signal.
From the above relationship shown in FIG. 21, in the multi-cell environment, the primary system base station needs to determine the signal from the primary system mobile station and the signal from the secondary system mobile station to be controlled.

  In the following description, it is assumed that a signal is discriminated using a known signal. In order to discriminate the signal using the known signal, each secondary system base station determines the signal from the secondary system mobile station and the secondary system mobile station with respect to the primary system base station. And the scheduling information indicating the frequency resource being used are notified.

FIG. 22 shows a notification sequence of secondary system known signal information and scheduling information between secondary system base stations 1521, 1531, and 1541 and primary system base station 1511.
As shown in FIG. 22, secondary system base stations 1521, 1531, and 1541 notify secondary system known signal information and scheduling information 1701-1, 1701-2, and 1701-3 to primary system base station 1511, respectively. .

  FIG. 23 shows the operation of the primary system base station 1511. The primary system base station 1511 synchronizes its own processing with the signal from each secondary system mobile station based on the scheduling information received from each secondary system base station 1521, 1531, 1541 (step B01).

The primary system base station 1511 discriminates a signal from each secondary system mobile station based on the known signal information received from each secondary system base station 1521, 1531, 1541 (step B02).
The primary system base station 1511 notifies the secondary system base stations 1521, 1531, and 1541 of measurement information after signal discrimination (step B03). Here, the measurement information includes the inter-system boundary measurement signal described in the first embodiment, and the interference limiting signal described in the fourth embodiment.

  FIG. 24 shows information between the primary system base station 1511 and the secondary system base stations 1521 and 1531 and between the secondary system base station 1521 and 1531 and the secondary system mobile stations 1522, 1523, 1532 and 1533. An example of the notification sequence is shown. FIG. 24 shows an example in which the first embodiment is applied to a multi-cell environment.

The primary system base station 1511 notifies inter-system boundary measurement signals 1901-1 and 1901-2 to the secondary system base stations 1521 and 1531, respectively.
The secondary system base station 1521 notifies the secondary system mobile stations 1522 and 1523 of the spectrum duplication amounts 1902-1 and 1902-2, and the secondary system base station 1531 receives the secondary system mobile stations 1532 and 1532, respectively. 1533 is notified of the spectrum overlap amounts 1902-3 and 1902-4.

  FIG. 25 shows information between the primary system base station 1511 and the secondary system base stations 1521 and 1531 and between the secondary system base station 1521 and 1531 and the secondary system mobile stations 1522, 1523, 1532 and 1533. Another example of the notification sequence is shown. FIG. 25 shows an example in which the fourth embodiment is applied to a multi-cell environment.

Primary system base station 1511 notifies inter-system boundary measurement signals 2001-1 and 2001-2 to secondary system base stations 1521 and 1531, respectively.
The secondary system base station 1521 notifies the secondary system mobile stations 1522 and 1523 of the spectrum overlap amounts 2002-1 and 2002-2, and the secondary system base station 1531 receives the secondary system mobile stations 1532 and 1532, respectively. 1533 is notified of the amount of spectrum overlap 2002-5 and 2002-6.

When the primary system base station 1511 determines that the required quality of its own system cannot be satisfied, the primary system base station 1511 outputs interference restriction signals 2003-1 and 2003-2 to the secondary system base stations 1521 and 1531, respectively.
Receiving the interference limiting signal 2003-1, the secondary system base station 1521 notifies the secondary system mobile stations 1522 and 1523 of the re-determined spectrum duplication amounts 2002-3 and 2002-4, respectively. Receiving the interference restriction signal 2003-2, the secondary system base station 1531 notifies the secondary system mobile stations 1532 and 1533 of the re-determined spectrum duplication amounts 2002-7 and 2002-8, respectively.

In the first to fifth embodiments, the primary system and the secondary system are described as different systems. However, the primary system and the secondary system may have the same system configuration. A configuration in which the primary system and the secondary system are the same is also included in the present invention.
In the first to fifth embodiments, the primary system and the secondary system are described as having different priorities. However, the primary system and the secondary system may have the same priority. A configuration in which the primary system and the secondary system have the same priority is also included in the present invention.

  In the first to fifth embodiments, at least some of the configurations of the primary system base station, the primary system mobile station, the secondary system base station, and the secondary system mobile station are respectively a CPU, a storage device, It can be realized by a computer having an external interface and a program for controlling these hardware resources. In each computer constituting the primary system base station, the primary system mobile station, the secondary system base station, and the secondary system mobile station, a program for realizing the transmission / reception method of the present invention includes a flexible disk, a CD- It is provided in a state of being recorded on a recording medium such as a ROM, a DVD-ROM, or a memory card, and stored in a storage device of a computer. The CPU of each computer executes the processing described in the first to fifth embodiments in accordance with a program stored in the storage device.

  The present invention can be applied to a radio communication system in which a plurality of systems share a frequency.

  DESCRIPTION OF SYMBOLS 101 ... Primary system base station, 102 ... Secondary system base station, 103 ... Secondary system mobile station, 104 ... Primary system mobile station, 1010 ... Inter-system boundary received signal measuring unit, 1011, 1011b ... Notification unit, 1012 ... Transmission unit, 1013 ... Reception unit, 1014 ... Interference amount determination unit, 1020 ... Inter-system boundary received signal measurement unit, 1021 ... Spectrum overlap amount determination unit, 1022,1022a ... Transmission unit, 1023,1023a ... Reception unit, 1024 ... Spectrum overlap amount ranking unit, 1025... Frequency resource arrangement determination unit, 1030, 1030a... Reception unit, 1031, 1031a... Transmission unit, 1032... Spectrum overlap amount control unit, 1033. 1511 ... Primary system base station, 1512, 1513 ... Primary system The mobile station, 1520,1530,1540 ... secondary system, 1521,1531,1541 ... secondary system base stations, 1522,1532 ... secondary system mobile station.

Claims (29)

In a wireless communication system in which multiple systems share a frequency,
A primary system base station that measures measurement information of an inter-system boundary between the local system and the secondary system based on a signal from the primary system mobile station and a signal from the secondary system mobile station;
Based on the signal from the primary system mobile station and the signal from the secondary system mobile station, measurement information on the inter-system boundary between the primary system and the own system is measured, and the measured inter-system boundary measurement information and the primary system are measured. A secondary system base station that performs signal transmission of the local system by overlapping a part of the frequency spectrum of the primary system with the frequency spectrum of the primary system based on the inter-system boundary measurement information measured by the base station ;
The primary system base station is
First inter-system boundary measurement means for measuring the inter-system boundary measurement information;
Notification means for notifying the secondary system base station of the inter-system boundary measurement information measured by the first inter-system boundary measurement means;
The secondary system base station
Second inter-system boundary measuring means for measuring the inter-system boundary measurement information;
Based on the inter-system boundary measurement information notified from the second inter-system boundary measurement means and the inter-system boundary measurement information notified from the primary system base station, the local system overlaps the frequency spectrum of the primary system. A spectral overlap amount determining means for determining a spectral overlap amount of the frequency spectrum of
Base station transmitting means for notifying the secondary system mobile station belonging to the own system of the spectrum overlap amount notified from the spectrum overlap amount determining means;
Base station receiving means for receiving a signal transmitted from the secondary system mobile station based on the spectrum overlap amount notified from the spectrum overlap amount determining means,
The spectrum overlap amount determination means receives the frequency spectrum of the primary system mobile station measured by the second inter-system boundary measurement means as the inter-system boundary measurement information notified from the second inter-system boundary measurement means. The received power density S_MS1 _SBS of the frequency spectrum of the secondary system mobile station measured by the power density P_MS1 _SBS and the second inter-system boundary measuring means , and the inter-system boundary measurement information notified from the primary system base station is Reception power density P_MS1 _PBS of the frequency spectrum of the primary system mobile station measured by the first inter-system boundary measuring means and reception of the frequency spectrum of the secondary system mobile station measured by the first inter-system boundary measuring means When the power density is S_MS1 _PBS and the weight addition coefficient is α (0 ≦ α ≦ 1),

The wireless communication system, wherein the spectrum overlap amount OF1 is calculated by: The wireless communication system according to claim 1, wherein
The primary system base station discriminates signals from one or a plurality of primary system mobile stations and signals from one or a plurality of secondary system mobile stations, and determines the inter-system boundary measurement information. A wireless communication system characterized by measuring. The wireless communication system according to claim 1 , wherein
The secondary system mobile station is
Mobile station transmission means for transmitting a signal to the secondary system base station;
Mobile station receiving means for receiving a signal from the secondary system base station;
And a spectrum overlap amount control means for causing the mobile station transmission means to transmit a signal and causing the mobile station reception means to receive a signal based on the spectrum overlap amount notified from the secondary system base station. Wireless communication system. The wireless communication system according to any one of claims 1 to 3 ,
The wireless communication system, wherein the secondary system base station and the secondary system mobile station control a spectrum overlap amount with a frequency spectrum of the primary system by controlling a transmission / reception band of the own system. The wireless communication system according to claim 4 , wherein
The wireless communication system, wherein the secondary system base station and the secondary system mobile station control a transmission / reception band of the own system by controlling a filter coefficient of a transmission / reception filter of the own system. The wireless communication system according to claim 5 , wherein
The wireless communication system, wherein the filter coefficient of the transmission / reception filter is a roll-off rate. The wireless communication system according to claim 1 or 2,
Based on the inter-system boundary measurement information measured by the local station and the inter-system boundary measurement information measured by the primary system base station, the secondary system base station determines the spectrum overlap portion between the local system and the primary system. A wireless communication system comprising means for controlling transmission power. The wireless communication system according to claim 1 , wherein
The secondary system base station further determines its own system based on the inter-system boundary measurement information notified from the second inter-system boundary measurement means and the inter-system boundary measurement information notified from the primary system base station. And a transmission power density determining means for determining a transmission power density of a spectrum overlapping portion of the primary system,
The radio communication system, wherein the base station transmission means of the secondary system base station notifies the secondary system mobile station belonging to the own system of the transmission power density notified from the transmission power density determination means. The wireless communication system according to claim 8 ,
The secondary system mobile station is
Mobile station transmission means for transmitting a signal to the secondary system base station;
Mobile station receiving means for receiving a signal from the secondary system base station;
Based on a spectrum overlap amount notified from the secondary system base station, a spectrum overlap amount control unit that causes the mobile station transmission unit to transmit a signal and causes the mobile station reception unit to receive a signal;
Transmission power control means for controlling the transmission power of the spectrum overlap portion between the own system and the primary system in the transmission / reception band of the own system according to the transmission power density notified from the secondary system base station. A wireless communication system. The wireless communication system according to claim 1 or 2,
The secondary system base station overlaps the frequency spectrum of the primary system based on the inter-system boundary measurement information measured by the local station and the inter-system boundary measurement information measured by the primary system base station. The frequency overlap of the frequency spectrum is determined, the spectrum overlap is ranked, the frequency resource allocation of the own system is determined according to the ranking result, and the signal transmission of the own system is performed based on the determined frequency resource allocation. A wireless communication system comprising means for performing. The wireless communication system according to claim 1 , wherein
The secondary system base station
Further, a spectrum overlap amount ranking means for ranking the spectrum overlap amount notified from the spectrum overlap amount determining means,
Frequency resource allocation determining means for determining the frequency resource allocation of the own system based on the ranking result;
The base station transmission means notifies the secondary system mobile station belonging to the own system of the frequency resource arrangement information notified from the frequency resource arrangement determination means instead of notifying the spectrum overlap amount,
The base station receiving means receives a signal transmitted from the secondary system mobile station based on frequency resource arrangement information notified from the frequency resource arrangement determining means instead of using the spectrum overlap amount. A wireless communication system. The wireless communication system according to claim 11 , wherein
The secondary system mobile station is
Mobile station transmission means for transmitting a signal to the secondary system base station;
Mobile station receiving means for receiving a signal from the secondary system base station;
Frequency resource arrangement control means for causing the mobile station transmission means to transmit a signal and causing the mobile station reception means to receive a signal based on frequency resource arrangement information notified from the secondary system base station. A wireless communication system. The wireless communication system according to claim 1 or 2,
The primary system base station has means for outputting an interference limiting signal to the secondary system base station when it is determined that the required quality of its own system cannot be satisfied,
The wireless communication system, wherein the secondary system base station has means for suppressing and controlling interference from the primary system to the primary system when receiving an interference limiting signal from the primary system base station. The wireless communication system according to claim 1 , wherein
Further, the primary system base station further outputs an interference limiting signal when it determines that the required quality of the own system cannot be satisfied as a result of measuring the amount of interference between the own system and the secondary system. Have
The notification means of the primary system base station outputs the interference limiting signal to the secondary system base station,
The spectrum overlap amount determining means of the secondary system base station receives the interference limiting signal from the primary system base station, and reduces the spectrum overlap amount so as to reduce the spectrum overlap between the primary system and the own system. Re-determined,
The base station transmission means of the secondary system base station notifies the secondary system mobile station belonging to the own system of the spectrum overlap amount re-notified from the spectrum overlap amount determination means,
The base station receiving means of the secondary system base station receives a signal transmitted from the secondary system mobile station based on the spectrum overlap amount re-notified from the spectrum overlap amount determining means. Wireless communication system. The wireless communication system according to claim 1 or 2,
The wireless communication system, wherein the inter-system boundary measurement information is a received power density. The wireless communication system according to claim 1 or 2,
The wireless communication system, wherein the inter-system boundary measurement information is a channel estimation value. Based on the signal from the mobile station of the other system and the signal from the mobile station of the own system, the measurement information of the inter-system boundary between the other system and the own system is measured. Based on the inter-system boundary measurement information measured by the base station, comprising means for transmitting a signal of the own system by overlapping a part of the frequency spectrum of the own system with the frequency spectrum of the other system ,
This means
An inter-system boundary measurement means for measuring the inter-system boundary measurement information;
Based on the inter-system boundary measurement information notified from the inter-system boundary measurement means and the inter-system boundary measurement information notified from the base station of the other system, the frequency spectrum of the own system to be overlapped with the frequency spectrum of the other system. A spectral overlap amount determining means for determining a spectral overlap amount;
Transmitting means for notifying the mobile station of its own system of the spectrum overlap amount notified from this spectrum overlap amount determining means;
Based on the spectrum overlap amount notified from the spectrum overlap amount determining means, the receiver is configured to receive a signal transmitted from the mobile station of the own system,
The spectrum overlap amount determining means includes the inter-system boundary measurement information notified from the inter-system boundary measuring means, the received power density P_MS1 _SBS of the frequency spectrum of the mobile station of another system measured by the inter-system boundary measuring means and the The received power density S_MS1 _SBS of the frequency spectrum of the mobile station of the own system measured by the inter-system boundary measuring means , and the inter-system boundary measurement information notified from the base station of the other system is measured by the base station of the other system was a received power density S_MS1 _PBS of the frequency spectrum of the received power density P_MS1 _PBS and the mobile station of the local system by the base station to measure the other system of the frequency spectrum of the mobile station of the other system, the weighting addition coefficient alpha (0 ≦ When α ≦ 1),

The spectrum overlap amount OF1 is calculated by the radio base station. The radio base station according to claim 17 ,
And means for controlling transmission power of spectrum overlapping portions of the own system and the other system based on the inter-system boundary measurement information measured by the own station and the inter-system boundary measurement information measured by the base station of the other system. A wireless base station characterized by. The radio base station according to claim 17 ,
Further, based on the inter-system boundary measurement information notified from the inter-system boundary measurement means and the inter-system boundary measurement information notified from the base station of the other system, the transmission power of the spectrum overlap portion between the own system and the other system A transmission power density determining means for determining the density;
The radio base station characterized in that the transmission means notifies the mobile station of its own system of the transmission power density notified from the transmission power density determination means. The radio base station according to claim 17 ,
Based on the inter-system boundary measurement information measured by the own station and the inter-system boundary measurement information measured by the base station of the other system, a spectrum overlap amount of the frequency spectrum of the own system to be overlapped with the frequency spectrum of the other system is determined. And means for ranking the spectrum overlap amounts, determining the frequency resource arrangement of the own system according to the ranking result, and performing signal transmission of the own system based on the determined frequency resource arrangement. Radio base station. The base station according to claim 17 ,
Further, a spectrum overlap amount ranking means for ranking the spectrum overlap amount notified from the spectrum overlap amount determining means,
Frequency resource allocation determining means for determining the frequency resource allocation of the own system based on the ranking result;
The transmitting means, instead of notifying the amount of spectrum overlap, notifies the mobile station of its own system frequency resource allocation information notified from the frequency resource allocation determining means,
The receiving means receives a signal transmitted from a mobile station of the own system based on frequency resource arrangement information notified from the frequency resource arrangement determining means instead of using the spectrum overlap amount. Wireless base station. The radio base station according to claim 17 ,
A radio base station comprising means for suppressing and controlling interference to the other system by the own system when an interference limiting signal is received from a base station of the other system. The radio base station according to claim 17 ,
The spectrum overlap amount determination means re-determines the spectrum overlap amount so as to reduce the spectrum overlap between the other system and the own system when an interference limiting signal is received from the base station of the other system,
The transmission means notifies the mobile station of its own system of the spectrum overlap amount re-notified from the spectrum overlap amount determination means,
The radio base station characterized in that the receiving means receives a signal transmitted from a mobile station of the own system based on a spectrum overlap amount re-notified from the spectrum overlap amount determining means. The radio base station according to claim 17 ,
The radio base station, wherein the inter-system boundary measurement information is a received power density. The radio base station according to claim 17 ,
The radio base station, wherein the inter-system boundary measurement information is a channel estimation value. In a transmission / reception method in which multiple systems share a frequency,
A first measurement step in which a primary system base station measures measurement information of an inter-system boundary between its own system and a secondary system based on a signal from a primary system mobile station and a signal from a secondary system mobile station; ,
A first notification step in which the primary system base station notifies the secondary system base station of inter-system boundary measurement information measured in the first measurement step;
A second measurement step in which the secondary system base station measures measurement information of an inter-system boundary between the primary system and the own system based on a signal from the primary system mobile station and a signal from the secondary system mobile station; ,
Based on the measured inter-system boundary measurement information and the inter-system boundary measurement information measured by the primary system base station, the secondary system base station converts a part of the frequency spectrum of the own system to the frequency spectrum of the primary system. And a spectral overlap amount control step for performing signal transmission of the own system in an overlapping manner ,
The spectral overlap amount control step includes:
Based on the inter-system boundary measurement information measured in the second measurement step and the inter-system boundary measurement information notified from the primary system base station, the secondary system base station generates a frequency spectrum of the primary system. A spectral overlap amount determination step for determining a spectral overlap amount of the frequency spectrum of the own system to be overlapped;
A second notification step in which the secondary system base station notifies the secondary system mobile station belonging to the own system of the spectrum overlap amount determined in the spectrum overlap amount determination step;
The secondary system base station receives a signal transmitted from the secondary system mobile station based on the spectrum overlap amount determined in the spectrum overlap amount determination step;
The spectral overlap amount determining step, said inter-system boundary measurement information measured by the second measurement step, the received power density P_MS1 _SBS of the frequency spectrum of the primary system mobile station measured by the second measurement step the The received power density S_MS1 _SBS of the frequency spectrum of the secondary system mobile station measured in the measurement step 2 and the inter-system boundary measurement information notified from the primary system base station was measured in the first measurement step. is the received power density S_MS1 _PBS frequency spectrum of the secondary system mobile station measured by the received power density P_MS1 _PBS of the frequency spectrum of the primary system the mobile station a first measurement step, the weighting addition coefficient α (0 ≦ α ≦ 1)

And calculating the spectrum overlap amount OF1 . The transmission / reception method according to claim 26 ,
The primary system base station discriminates signals from one or a plurality of primary system mobile stations and signals from one or a plurality of secondary system mobile stations, and determines the inter-system boundary measurement information. A transmission / reception method characterized by measuring. The transmission / reception method according to claim 26 ,
Furthermore, the secondary system base station ranks the spectrum overlap amount determined in the spectrum overlap amount determination step, the spectrum overlap amount ranking step,
A frequency resource allocation determination step of determining a frequency resource allocation of the own system based on the ranking result;
In the second notification step, instead of notifying the spectrum duplication amount, the frequency resource allocation information determined in the frequency resource allocation determination step is notified to the secondary system mobile station belonging to the own system,
The reception step receives a signal transmitted from the secondary system mobile station based on the frequency resource allocation information determined in the frequency resource allocation determination step instead of using the spectrum overlap amount. Transmission / reception method. A measurement step of measuring measurement information of an inter-system boundary between the other system and the own system based on a signal from the mobile station of the other system and a signal from the mobile station of the own system;
Based on the measured inter-system boundary measurement information and the inter-system boundary measurement information measured by the base station of the other system, a part of the frequency spectrum of the own system is overlapped with the frequency spectrum of the other system. And causing the computer to execute a spectral overlap amount control step for transmission ,
The spectral overlap amount control step includes:
Based on the inter-system boundary measurement information measured in the measurement step and the inter-system boundary measurement information notified from the base station of the other system, the spectrum overlap amount of the frequency spectrum of the own system to be overlapped with the frequency spectrum of the other system is calculated. A spectral overlap amount determination step to be determined;
A notification step of notifying the mobile station of its own system of the spectrum overlap amount determined in this spectrum overlap amount determination step;
Receiving a signal transmitted from the mobile station of the own system based on the spectrum overlap amount determined in the spectrum overlap amount determination step,
In the spectrum overlap amount determination step, the inter-system boundary measurement information measured in the measurement step includes the received power density P_MS1 _SBS of the frequency spectrum of the mobile station of the other system measured in the measurement step and the own system measured in the measurement step. Is the received power density S_MS1 _SBS of the frequency spectrum of the other mobile station , and the inter-system boundary measurement information notified from the base station of the other system is the frequency spectrum of the mobile station of the other system measured by the base station of the other system. is the received power density S_MS1 _PBS of the frequency spectrum of the received power density P_MS1 _PBS and the mobile station of the local system by the base station to measure the other system, when the weight sum coefficients and α (0 ≦ α ≦ 1) ,

A radio base station program that calculates the spectrum overlap amount OF1 by:

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