JP2002208891A - Communication method and mobile station in mobile communication system - Google Patents

Abstract

(57) [Summary] PROBLEM TO BE SOLVED: To allow base station communication and direct communication between mobile stations to be communicated in different frequency bands, and to further establish a boundary between the base station communication frequency band and direct communication between mobile stations. To prevent interference due to leakage power from an adjacent channel when using a frequency adjacent to the carrier frequency as a carrier frequency. SOLUTION: A base station communication and a direct communication between mobile stations are made to communicate in different frequency bands, and a frequency adjacent to a boundary with a base station communication frequency band is used as a carrier frequency in the direct communication between mobile stations. If so, the level of the carrier signal transmitted from the mobile station is detected according to the reception level of the downlink carrier frequency from the base station corresponding to the frequency adjacent to the carrier frequency. Make it smaller. Thereby, malfunction of the base station can be prevented, and signal interference can be prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication method in a mobile communication system, and more particularly to a technique for ensuring high quality communication when performing direct communication between mobile stations in a mobile communication system.

[0002]

2. Description of the Related Art In a mobile communication system, a certain frequency band is allocated for communication, and a plurality of different carrier frequencies are set in the frequency band. Then, the mobile station establishes a line with the base station set in the service area using these carrier frequencies and performs bidirectional communication (base station communication).

FIG. 8 is a block diagram showing a schematic configuration of a general example of a mobile communication system. In FIG. 8, 1 is a base station, 2a, 2b, and 2c are mobile stations existing in the zone of the base station 1, and 3 is a zone constituting a service area of the base station 1.

[0004] By dividing the frequency band of the carrier frequency used in the case of performing base station communication and in the case of performing direct communication between mobile stations, adjacent carrier frequencies are prevented to prevent signal interference. Accordingly, proposals have been made to secure high-quality communication in both base station communication and direct communication between mobile stations.

[0005] Fig. 9 shows a conventional example of a mobile communication system in which the frequency band of the carrier frequency used for performing such base station communication and direct communication between mobile stations is divided. The control channel used for individual connection control is predetermined in this. FIG. 9 is a diagram showing allocation of a carrier frequency for base station communication and a carrier frequency for direct communication between mobile stations in the conventional mobile communication system. In this mobile communication system, f1 to fn are set as a base station communication downlink band (mobile station reception band), and F1 is set as a base station communication uplink band (base station reception band).
1 to Fn are set. Also, f'1 to f'm are set as the direct communication band between mobile stations. Among these bands, the base station communication downlink bands f1 to fn and the mobile station direct communication bands f′1 to f′m are distinguished into adjacent separate bands, and when performing base station communication, the base station communication downlink A carrier frequency is selected from the bands f1 to fn and the base station communication uplink bands F1 to Fn. On the other hand, when performing direct communication between mobile stations, a carrier frequency is selected from the direct communication bands f′1 to f′m between mobile stations. When base station communication is performed in this mobile communication system, a communication operation is performed in the same procedure as that of base station communication in a general mobile communication system.

Next, the operation of direct communication between mobile stations will be described. FIG. 10 is a flowchart for explaining a direct communication operation between mobile stations in the conventional example performed between the mobile stations 2a and 2b shown in FIG. The direct communication between mobile stations in this conventional example is the direct communication between individual mobile stations executed between the mobile station 2a and the mobile station 2b. When the direct communication between mobile stations is started, the control means of the mobile station (referred to as 2a) serving as a calling station performs processing steps (hereinafter simply referred to as steps).
In ST61, a candidate channel is selected from carrier frequencies f'1 to f'm included in the direct communication band between mobile stations. Next, the control means performs carrier detection of the candidate channel (step ST62).
The calling signal is transmitted from the mobile station 2a to the mobile station 2b (step ST63), and a response from the partner mobile station 2b is waited for (step ST64). In the calling operation, a communication channel (for example, a carrier frequency f′i) selected by carrier detection performed in steps ST61 to ST62 is designated.

Mobile station 2b receiving a call from mobile station 2a
In the (calling station), first, a candidate channel is selected from the carrier frequencies f'1 to f'm included in the direct communication band between mobile stations (step ST65). Next, the mobile station 2b
Performs the carrier detection of the candidate channel (step ST66), and upon completion of this process, sends out an incoming call signal (ACK) from the mobile station 2b to the mobile station 2a (step ST67).

On the other hand, in the mobile station 2a, the mobile station 2b
It is checked whether or not ACK has been received (step ST68), and if it has been received, a communication operation is performed (step ST69). On the other hand, in step ST68, A
If CK has not been received, it is checked whether or not the response waiting time has elapsed for a fixed time (step ST70). If not, the processing shifts to the check operation of step ST68, while the response waiting time has elapsed for a fixed time. If so, a busy signal tone is generated (step ST71).

[0009]

However, a mobile communication system of a system that divides a frequency band of a carrier frequency used for performing the above-described base station communication and for performing a direct communication between mobile stations is adopted. However, when direct communication between mobile stations is performed, a frequency (f'1 in the above case) adjacent to a boundary with a frequency band for base station communication is used as a carrier frequency of a communication channel. There is a possibility that carrier frequency interference may occur with the station communication, and there is a problem that interference easily occurs between carrier frequencies and communication quality is degraded.

An object of the present invention is to allow base station communication and direct communication between mobile stations to be communicated in different frequency bands. The purpose of the present invention is to prevent interference caused by leakage power from an adjacent channel when using a frequency adjacent to a channel as a carrier frequency.

[0011]

SUMMARY OF THE INVENTION The present invention relates to a mobile communication system including a base station and a plurality of mobile stations, which is used for communication between mobile stations via a base station (base station communication) and mobile communication. Direct communication between stations (direct communication between mobile stations)
In some cases, while distinguishing the frequency band of the carrier frequency into adjacent different bands, when performing base station communication, a predetermined frequency within the frequency band for base station communication is used as the carrier frequency, while the mobile station is used. In the case where a frequency adjacent to the boundary with the frequency band for base station communication is used as a carrier frequency in direct communication between mobile stations, the carrier frequency of the downlink from the base station corresponding to the frequency adjacent to the used carrier frequency in the mobile station. Detecting the level of the carrier signal transmitted from the mobile station according to the received level of the downlink carrier frequency, preventing malfunction of the base station, Has the effect of preventing interference.

According to the present invention, in a mobile communication system composed of a base station and a plurality of mobile stations, the frequency of a carrier frequency is determined between base station communication via a base station and direct communication between mobile stations. When performing direct communication between mobile stations while distinguishing a band from another adjacent band, a predetermined frequency in a frequency band for base station communication is used as a carrier frequency, and the carrier used in the mobile station is used as the carrier frequency. Detecting the reception level of the downlink carrier frequency from the base station corresponding to the frequency adjacent to the frequency, and reducing the level of the carrier signal transmitted from the mobile station according to the reception level of the downlink carrier frequency; This has the effect of preventing malfunction of the base station and of preventing signal interference.

According to the present invention, when performing base station communication, a predetermined frequency within a frequency band for base station communication is used as a carrier frequency.
In the frequency band for direct communication between mobile stations, a frequency far from the boundary with the frequency band for base station communication is used as a carrier frequency, and between the base station communication and the direct communication between mobile stations, By setting the carrier frequencies to be used farther apart, it is possible to prevent adjacent carrier frequencies and prevent signal interference.

The present invention also provides a mobile station of a mobile communication system having a base station and a mobile station, a radio communication means for performing radio communication, and a control for switching a control channel for executing radio communication. Control channel storage means for setting channel information; reception level detection means for detecting a level of a control channel signal transmitted from a base station; and control means for controlling a radio communication operation. Carrier detection is performed at the time of a call operation by the wireless communication means in direct communication, and if the carrier frequency of the control channel at the time of the call is a frequency adjacent to the boundary with the frequency band for base station communication, transmission is performed from the base station. The level of the control channel signal to be received is detected by the reception level detection means, and the transmission power at the time of calling is controlled to a predetermined value and then the calling is performed. And characterized in bets, it has the effect that it is possible to prevent erroneous operation of the base station, also to prevent interference signals.

[0015]

(Embodiment 1) Embodiments of the present invention will be described below with reference to the drawings. The mobile communication system used as the first embodiment of the present invention is the same as that shown in FIG. That is, this mobile communication system includes a base station 1, mobile stations 2a, 2b, and 2c existing in a zone of the base station 1, and a zone 3 that forms a service area of the base station 1.

FIG. 1 shows mobile stations 2a and 2b used in a mobile communication system according to a first embodiment of the present invention.
FIG. 3 is a block diagram showing a configuration of a mobile station 2c (here, for the sake of explanation, the mobile station 2a is represented). In the mobile station 2a, 22 is a radio receiving circuit for receiving a radio wave from another station 1, 23 is a reception data analyzing means for judging whether or not call data is normal, and 24 is data for generating data for transmission. Transmission data generating means 25, a wireless transmission circuit for wirelessly transmitting transmission data, an antenna 26 for transmitting transmission data wirelessly and receiving data wirelessly, and 27 an audio for extracting an audio signal from the reception data. Decoding means, 28 is a speaker for outputting audio, 29 is audio encoding means for outputting an audio signal, 30 is a microphone for converting audio into an audio signal, 31 is control channel storage means for storing control channel information, 32 is a reception level detecting means for detecting the level of a control channel signal transmitted from the base station 1, 33 is an operation unit for performing various inputs, 34
Is control means for controlling the wireless communication operation of the mobile station 2a, controlling storage, and the like.

Next, the operation of the above embodiment will be described. In this mobile communication system, a carrier frequency for base station communication and a carrier frequency for direct communication between mobile stations are allocated, for example, as shown in FIG. That is, f1 to fn are assigned as base station communication uplink bands (mobile station transmission bands), and F1 to Fn are assigned as base station communication downlink bands (base station transmission bands).
Also, f'1 to f'm are assigned as direct communication bands between mobile stations. Of these bands, base station communication uplink bands f1 to fn and mobile station direct communication bands f′1 to f ′
m is classified into adjacent different bands, and when performing base station communication, a carrier frequency is allocated from base station communication upstream bands f1 to fn and base station communication downstream bands F1 to Fn. On the other hand, when performing direct communication between mobile stations, a carrier frequency is selected from the direct communication bands f′1 to f′m between mobile stations. Further, in this embodiment, it is assumed that the downlink from base station 1 always transmits all slots. When base station communication is performed in this mobile communication system, a communication operation is performed in the same procedure as that of base station communication in a general mobile communication system.

Next, a direct communication operation between mobile stations will be described. FIG. 3 is a flowchart illustrating a direct communication operation between mobile stations performed between mobile stations 2a and 2b shown in FIG. The direct communication between mobile stations in this embodiment is direct communication between individual mobile stations executed between the mobile stations 2a and 2b. When the direct communication between mobile stations is started, the control means 34 of the mobile station (referred to as 2a) serving as a calling station sets a candidate channel in a processing step (hereinafter simply referred to as a step) ST1 to a direct communication band between mobile stations. Is selected from among the carrier frequencies f'1 to f'm included in. Next, the control means 34 performs carrier detection on the candidate channel (step ST2), and then determines whether or not the candidate channel on which carrier detection has been performed is a channel adjacent to the uplink band of the base station 1, that is, the carrier frequency of the candidate channel. Is f'1
Is checked (step ST3).

If it is determined in this check process that the candidate channel is a channel adjacent to the upstream band of the base station 1, carrier detection is performed on a channel adjacent to the base station downstream band (step ST4). In the carrier detection of the channel adjacent to the downstream band, since the candidate channel is a channel adjacent to the upstream band of the base station 1, FIG.
In, the carrier frequency of this channel is f′1, and the carrier frequency of the adjacent channel in the base station uplink band adjacent to this carrier frequency f′1 is fn. The carrier frequency in the downstream band of the base station 1 corresponding to the carrier frequency fn in the base station is Fn. Therefore, in the carrier detection in this step ST4, the reception level detection means 32 causes the carrier frequency F
n reception levels are detected.

Next, the control means 34 checks whether or not the detected reception level is higher than a predetermined threshold value (step ST5). If the reception level is higher than the threshold value, the control means 34 disturbs the base station uplink. A control amount A for not giving is calculated and set (step ST6). The calculation and setting of the control amount A are performed as follows. If the reception level of the adjacent channel is Rcv0 [dBμ] as a result of carrier detection, transmission output control is performed according to the following equation. Pd = {Etm-Etb} + {(Rcv0-ACPR)
− (Ern + 10 · log [10 ^{M / 10} −1])｝ where: <Example> Pd [dB]: Required transmission output reduction (power-down not required for negative numbers) Etm [dBμ]: Mobile station EIRP (Nominal value ) 143 dBμ (1 W) Etb [dBμ]: Base station EIRP (Standard value) 153 dBμ (10 W) ACPR [dB]: Adjacent channel leakage power ratio of mobile station (Nominal value) 45 dB Ern [dBμ]: Base station reception noise level ( Antenna input conversion value) ... internal noise + extraneous noise such as city noise (standard value) -3 dBμ M [dB]: Allowable deterioration margin 1 dB.

Next, following the calculation setting of the control amount A, it is checked whether or not the transmission output control amount A is larger than a predetermined control amount B (step ST7). If the transmission output control amount A is larger than the predetermined control amount B, a busy signal tone is generated (step ST8). On the other hand, if the transmission output control amount A is equal to or less than the predetermined control amount B in step ST7, a call signal is transmitted from the mobile station 2a to the mobile station 2b (step ST9), and the call signal is transmitted from the partner mobile station 2b. Wait for a response (step ST10). In this calling operation, the communication channel (carrier frequency f'1) selected by the carrier detection and the reception level detection executed in steps ST1 to ST6 is designated.

If it is determined in step ST3 that the candidate channel is not a channel adjacent to the upstream band of base station 1, carrier frequency interference is unlikely to occur, and the process directly proceeds to step ST9 to make a call. The operation is performed. Also, when it is determined in the check processing in step ST5 that the detected reception level is not higher than the predetermined threshold,
Since interference of the carrier frequency is unlikely to occur, the process directly proceeds to step ST9 to perform a calling operation. That is, in the check processing in step ST5, when direct communication between mobile stations is performed in a state where the detected reception level is higher than the predetermined threshold, the signal is transmitted to another communication that is performing base station communication on an adjacent channel. Because of the possibility of interference, it is necessary to reduce the transmission output from the mobile station 2a.

Mobile station 2b receiving a call from mobile station 2a
The (calling station) first selects a designated communication channel included in the outgoing call signal (step ST11). Next, the control means 34 of the mobile station 2b performs carrier detection on the communication channel (step ST12), and then determines whether the communication channel on which carrier detection has been performed is a channel adjacent to the uplink band of the base station 1, that is, the communication is performed. It is checked whether the carrier frequency of the channel is f'1 (step ST13).

If it is determined in this check process that the candidate channel is a channel adjacent to the upstream band of base station 1, carrier detection is performed on a channel adjacent to the base station downstream band (step ST14). In the carrier detection of the channel adjacent to the downstream band, since the candidate channel is a channel adjacent to the upstream band of the base station 1, the carrier frequency of this channel is f′1 in FIG. The carrier frequency of the adjacent channel in the base station uplink band adjacent to 1 is fn. The carrier frequency in the downstream band of the base station 1 corresponding to the carrier frequency fn in the base station is Fn. Therefore, in the carrier detection in step ST14, the reception level of carrier frequency Fn is detected by reception level detection means 32.

Next, the control means 34 checks whether or not the detected reception level is higher than a predetermined threshold value (step ST15). If the received level is higher than the threshold value, the control means 34 disturbs the base station uplink. A control amount A not to be given is calculated and set (step ST16), and subsequently, it is checked whether or not the transmission output control amount A is larger than a predetermined control amount B (step ST17). When the transmission output control amount A is larger than the predetermined control amount B, a NACK signal is transmitted to the mobile station 2a. On the other hand, if the transmission output control amount A is equal to or smaller than the predetermined control amount B in step ST17, an incoming call signal (ACK) is transmitted from the mobile station 2b to the mobile station 2a (step ST18).
In the incoming call operation, the communication channel (carrier frequency f′1) selected by the carrier detection and the reception level detection executed in steps ST11 to ST16 is specified.

In the checking process in step ST13, when it is determined that the communication channel is not a channel adjacent to the upstream band of the base station 1, the process directly proceeds to step ST18 because the interference of the carrier frequency is unlikely to occur. The operation is performed. Step ST1
In the checking process in step 5, when it is determined that the detected reception level is not higher than the predetermined threshold value, the process directly proceeds to step ST18 to perform the incoming call operation because the carrier frequency does not easily interfere. That is, in the check processing in step ST15, when the incoming operation of the direct communication between mobile stations is performed in a state where the detected reception level is higher than the predetermined threshold, the incoming signal transmitted from the mobile station 2b becomes adjacent. Since there is a possibility of interfering with other communications that are performing base station communications on the channel, it is necessary to reduce the transmission output of the incoming call signal from the mobile station 2b.

While the mobile station 2b is executing the processing in steps ST11 to ST18, the mobile station 2a is in a state of waiting for a response as described in step ST10. Until the incoming signal from mobile station 2b is received, mobile station 2a checks whether there is a response from mobile station 2b (step ST19). And
If it is determined that there is a response in this check processing, it is checked whether the incoming call signal is ACK or NACK (step ST20), and if it is NACK, a busy signal tone is generated (step ST20). Step ST
8). On the other hand, if it is determined in step ST20 that the received packet is ACK, a communication operation is performed (step ST20).
21). If it is determined in step ST19 whether or not there is a response, if there is no response, it is next checked whether or not a predetermined time has elapsed from the start of the operation (step ST19).
22) If the fixed time has not elapsed, step S is performed again.
Returning to T19, a response waiting check operation is performed.
If the predetermined time has elapsed, it is determined that there is no response from the mobile station 2b, and a busy signal tone is generated (step ST).
8).

(Embodiment 2) FIG. 4 is a block diagram showing a schematic configuration of a mobile communication system according to a second embodiment of the present invention. This diagram also has the same system configuration as FIG. 8, and differs from FIG. 8 in that the mobile station 2b is replaced by the mobile stations 2b-1, 2b-2, 2b-3 (that is, the mobile station 2b Group) has been set up.
According to such an aspect, group communication can be performed in the direct communication operation between mobile stations. Hereinafter, a direct communication operation between mobile stations according to the second embodiment will be described. FIG. 5 is a flowchart illustrating a direct communication operation (group communication operation) between mobile stations performed between the mobile station 2a and the group of the mobile stations 2b illustrated in FIG.

When the direct communication between the mobile stations is started, the control means 34 of the mobile station 2a serving as the calling station performs step ST3.
In 1, a candidate channel is selected from carrier frequencies f ′ 1 to f′m included in the direct communication band between mobile stations.
Next, the control means 34 performs carrier detection on the candidate channel (step ST32), and then determines whether or not the candidate channel is a channel adjacent to the uplink band of the base station 1, that is, if the carrier frequency of the candidate channel is f'1. It is checked whether or not there is (step ST33).

If it is determined in this check process that the candidate channel is a channel adjacent to the upstream band of base station 1, carrier detection is performed on the adjacent channel in the base station downstream band (step ST34). In the carrier detection of the channel adjacent to the downstream band, since the candidate channel is a channel adjacent to the upstream band of the base station 1, the carrier frequency of this channel is f′1 in FIG. The carrier frequency of the adjacent channel in the base station uplink band adjacent to 1 is fn. The carrier frequency in the downstream band of the base station 1 corresponding to the carrier frequency fn in the base station is Fn. Therefore, in the carrier detection in step ST34, the reception level of carrier frequency Fn is detected by reception level detection means 32.

Next, the control means 34 checks whether or not the detected reception level is higher than a predetermined threshold value (step ST35). If the reception level is higher than the threshold value, the control means 34 disturbs the base station uplink. A control amount A not to be given is calculated and set (step ST36). The calculation and setting of the control amount A are performed as follows. If the reception level of the adjacent channel is Rcv0 [dBμ] as a result of carrier detection, transmission output control is performed according to the following equation. Pd = {Etm-Etb} + {(Rcv0-ACPR)
− (Ern + 10 · log [10 ^{M / 10} −1])｝ where: <Example> Pd [dB]: Required transmission power reduction (power down is not required for negative numbers) Etm [dBμ]: Mobile station EIRP (Nominal value 143 dBμ (1 W) Etb [dBμ]: Base station EIRP (standard value) 153 dBμ (10 W) ACPR [dB]: Adjacent channel leakage power ratio of mobile station (nominal value) 45 dB Ern [dBμ]: Base station reception noise level ( Antenna input conversion value) ... internal noise + extraneous noise such as city noise (standard value) -3 dBμ M [dB]: Allowable deterioration margin 1 dB.

Next, following the calculation of the control amount A, it is checked whether or not the transmission output control amount A is larger than a predetermined control amount B (step ST37). And
When the transmission output control amount A is larger than the predetermined control amount B, a busy signal tone is generated (step ST38). On the other hand,
If the transmission output control amount A is equal to or smaller than the predetermined control amount B in step ST37, a call signal is transmitted from the mobile station 2a to the group of mobile stations 2b (step ST39).
The communication operation starts after a lapse of a predetermined time (step ST
40). In this calling operation, the above-mentioned step ST3
The communication channel (carrier frequency f'1) selected by the carrier detection and the reception level detection performed from 1 to step ST36 is designated.

In the checking process in step ST33, if it is determined that the candidate channel is not a channel adjacent to the upstream band of the base station 1, carrier frequency interference is unlikely to occur, and the process directly proceeds to step ST39 to make a call. The operation is performed. Step ST3
In the checking process in step 5, when it is determined that the detected reception level is not higher than the predetermined threshold value, since the interference of the carrier frequency is unlikely to occur, the process directly proceeds to step ST39 to perform the calling operation. That is, in the check processing in step ST35, if the operation of the direct communication between mobile stations is performed in a state where the detected reception level is higher than the predetermined threshold, the signal is transmitted to another base station in the adjacent channel. Since there is a possibility of interfering with the communication, it is necessary to reduce the transmission output from the mobile station 2a.

Mobile station 2b receiving a call from mobile station 2a
In one group (called station), any one of the plurality of mobile stations 2b-1, 2b-2, and 2b-3 (represented by the mobile station 2b-1) constituting the group moves as a representative. It receives a calling signal from the station 2a. That is, mobile station 2
mobile station 2b-1 (the called station) that has received the calling signal from a
In, first, a designated communication channel included in the call signal is selected (step ST51). Next, mobile station 2
The control means 34 of b-1 performs carrier detection of the traffic channel (step ST52), and then determines whether or not the traffic channel on which the carrier detection has been performed is a channel adjacent to the uplink band of the base station 1, that is, whether the traffic channel is It is checked whether the carrier frequency is f'1 (step ST53).

If it is determined in this check process that the candidate channel is a channel adjacent to the upstream band of base station 1, carrier detection is performed on a channel adjacent to the base station downstream band (step ST54). In the carrier detection of the channel adjacent to the downstream band, since the candidate channel is a channel adjacent to the upstream band of the base station 1, the carrier frequency of this channel is f′1 in FIG. The carrier frequency of the adjacent channel in the base station uplink band adjacent to 1 is fn. The carrier frequency in the downstream band of the base station 1 corresponding to the carrier frequency fn in the base station is Fn. Therefore, in the carrier detection in step ST54, the reception level of carrier frequency Fn is detected by reception level detection means 32.

Next, the control means 34 checks whether or not the detected reception level is higher than a predetermined threshold value (step ST55). A control amount A not to be given is calculated and set (step ST56), and subsequently, it is checked whether or not the transmission output control amount A is larger than a predetermined control amount B (step ST57). If the transmission output control amount A is larger than the predetermined control amount B, a direct busy operation is performed (step ST58).
On the other hand, if the transmission output control amount A is equal to or smaller than the predetermined control amount B in step ST57, a direct communication operation is performed (step ST59). In this communication operation, the communication channel (carrier frequency f ′) selected by the carrier detection and the reception level detection executed in steps ST51 to ST56.
1) is designated.

In the checking process in step ST53, when it is determined that the channel is not a channel adjacent to the upstream band of base station 1, direct communication operation is performed because interference of carrier frequency is unlikely (step ST59). . Also, in the checking process in step ST55, when it is determined that the detected reception level is not higher than the predetermined threshold value, the direct communication operation is performed because the carrier frequency does not easily interfere (step ST59). That is, in the check processing in step ST55, when the incoming call operation of the direct communication between mobile stations is performed in a state where the detected reception level is higher than the predetermined threshold value, the incoming call signal transmitted from the mobile station 2b-1 Since there is a possibility of interfering with other communications that are performing base station communications on adjacent channels, it is necessary to reduce the transmission output of the incoming call signal from the mobile station 2b-1.

(Embodiment 3) FIG. 6 illustrates a situation of allocation of a carrier frequency for base station communication and a carrier frequency for direct communication between mobile stations in a mobile communication system according to a third embodiment of the present invention. FIG. This carrier assignment diagram is basically the same as that shown in FIG. In the first embodiment and the second embodiment described above, in a base station and a mobile communication system configured by a plurality of mobile stations, in a case of base station communication,
In the case of direct communication between mobile stations, the frequency band of the carrier frequency is divided into adjacent different bands, and in base station communication, f1 to fn, F1 are used as base station communication uplink and downlink (mobile station transmission and reception bands). To Fn, and the direct communication between mobile stations uses the direct communication bands f′1 to f′m between mobile stations.

In the third embodiment, when direct communication between mobile stations is performed under a configuration in which the frequency band of the carrier frequency is divided into adjacent different bands, the base station communication uplink bands f1 to fn An example of using a predetermined channel is proposed. In the present embodiment, in the operation for performing direct communication between mobile stations, a communication operation is performed according to a flowchart (individual communication) shown in FIG. 3 and a flowchart (group communication) shown in FIG. However, in the selection operation of the candidate channel from step ST1 to step ST2 in FIG. 3, the base station communication uplink band f1
A predetermined channel (for example, fi) is selected from .about.fn. Then, also in this case, the carrier detection and the comparison of the reception level of the adjacent channel from step ST3 to step ST7 in FIG. 3 are performed, and after these processes, the direct communication between the mobile stations is performed. Step ST31 to step ST in FIG.
The same applies to the selection of 32 candidate channels.

In any of the first to third embodiments described above, the control means 34 sets the candidate channel to the direct communication band between mobile stations in the selection operation of the candidate channel from step ST1 to step ST2. When selecting from among the carrier frequencies f′1 to f′m included in the above, if a channel of a frequency other than the carrier frequency f′1 is vacant, an algorithm for preferentially selecting the vacant channel is used. You may have.

FIG. 7 shows a mobile communication system according to the fourth embodiment of the present invention, wherein the above-mentioned carrier frequency f′1 is used.
FIG. 9 is a flowchart for executing an algorithm for preferentially selecting a channel of a frequency other than the carrier frequency f′1 among the frequency channels f′m to f′m. This flow chart is basically the same as the flow chart shown in FIG. 3 except for the operation start part of the calling station. Therefore, only the operation different from that in FIG. 3 will be described.

In FIG. 7, the control means 34 of the calling station comprises:
First, the carrier frequency f'2 is selected from among the carrier frequencies f'2 to f'm (f'1 is later) included in the direct communication band between the mobile stations as the candidate channels (step S).
T23). At this time, a counter is provided in the control means 34 so that carrier frequencies up to f′2, f′3,.
Next, the control means 34 performs carrier detection on the candidate channel (step ST24), and then checks whether or not the level of the candidate channel on which the carrier detection has been performed is below a certain value (step ST25).

If the level of the candidate channel is equal to or less than a predetermined value in this check process, the process shifts to the process of step ST9 in FIG. On the other hand, step ST2
If the level of the candidate channel is not equal to or less than the predetermined value in the check processing of No. 5, it is checked whether or not the counter has exceeded (step ST26). If it is determined in the check processing in step ST26 that the counter has not exceeded, the flow returns to the processing in step ST23, and the carrier frequency f'3 is selected from the carrier frequencies f'3 to f'm. While the state where the level of the candidate channel is not equal to or lower than the fixed value and the state where the counter does not exceed (AND) continue, the control means 34 repeatedly executes the processing from step ST23 to step ST26. When it is determined in the check processing in step ST26 that the counter is over, the carrier frequency f'1 is selected (step ST2).
7) After that, the processing shifts to the processing after step ST4 in FIG.

In this way, in direct communication between mobile stations, candidate channels can be sequentially selected from channels that are not adjacent to the upstream band of base station 1. The opportunity (probability) of using a frequency adjacent to the boundary with the frequency band as the carrier frequency is reduced, and the process immediately proceeds to step ST9 to perform the calling operation, thereby speeding up the calling operation. Can be. Moreover, in the communication, interference due to leakage power from an adjacent channel is less likely to occur, and high-quality communication can be secured.

In the first to third embodiments, interference avoidance in the case where the carrier frequency of direct communication between mobile stations and the carrier frequency of base station communication are adjacent has been described. It is possible to avoid interference not only in the adjacent frequency but also in the next adjacent frequency or the next adjacent frequency and carrier sense by extending the carrier sense to the entire band near the carrier frequency.

[0046]

As described above, according to the present invention,
In a mobile communication system composed of a base station and a plurality of mobile stations, the frequency bands of carrier frequencies are adjacent to each other in the case of communication between mobile stations via a base station and the case of direct communication between mobile stations. When performing base station communication by distinguishing between different bands, a predetermined frequency in the base station communication frequency band is used as a carrier frequency, while the boundary between the base station communication frequency band and the mobile station direct communication is used. When using the frequency adjacent to the carrier frequency as the carrier frequency, the mobile station detects the reception level of the downlink carrier frequency from the base station corresponding to the frequency adjacent to the carrier frequency to be used, and the downlink from the base station. Since the level of the carrier signal transmitted from the mobile station is reduced according to the reception level of the carrier frequency, the level of the other base station communication There is an advantage that it is possible to reduce the effect of signal interference.

Further, under the configuration in which the frequency band of the carrier frequency is divided into adjacent different bands, when performing direct communication between mobile stations, predetermined channels in the upstream bands f1 to fn for base station communication are used. In this case, the mobile station also detects the reception level of the downlink carrier frequency from the base station corresponding to the frequency adjacent to the used carrier frequency in the mobile station, and receives the downlink carrier frequency from the base station. Since the level of the carrier signal transmitted from the mobile station is reduced according to the level, it is possible to obtain the effect of reducing the influence of interference with other communication in base station communication.

Further, in the case of direct communication between mobile stations, a frequency far from the boundary with the frequency band for base station communication in the frequency band for direct communication between mobile stations is preferentially selected as a carrier frequency. In the direct communication between the mobile stations, the calling operation can be performed without detecting the adjacent channel, and the effect of accelerating the calling operation can be obtained.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a mobile station used in a first embodiment of the present invention.

FIG. 2 is a diagram for explaining an allocation state of a carrier frequency for base station communication and a carrier frequency for direct communication between mobile stations in the mobile communication system according to the first embodiment.

FIG. 3 is a flowchart illustrating a direct communication operation (individual communication) between mobile stations according to the first embodiment.

FIG. 4 is a block diagram showing a schematic configuration of a mobile communication system according to a second embodiment of the present invention.

FIG. 5 is a flowchart illustrating a direct communication operation (group communication) between mobile stations according to the second embodiment.

FIG. 6 is a view for explaining an allocation state of a carrier frequency for base station communication and a carrier frequency for direct communication between mobile stations in the mobile communication system according to the third embodiment of the present invention.

FIG. 7 is a flowchart for executing an algorithm for preferentially selecting a channel of a frequency other than the carrier frequency f′1 according to the fourth embodiment of the present invention.

FIG. 8 is a block diagram showing a schematic configuration of a general example of a mobile communication system.

FIG. 9 is a diagram illustrating a setting state of a carrier frequency for base station communication and a carrier frequency for direct communication between mobile stations in a conventional mobile communication system.

FIG. 10 is a flowchart illustrating a direct communication operation between mobile stations in the conventional example.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Base station 2 Mobile station 22 Radio reception circuit 23 Reception data analysis means 24 Transmission data generation means 25 Radio transmission circuit 26 Antenna 27 Reception circuit 28 Receiver 29 Transmission circuit 30 Microphone 31 Control channel storage means 32 Reception level detection means 33 Operation part 34 control means

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[Procedure amendment]

[Submission date] January 25, 2001 (2001.1.2)
5)

[Procedure amendment 1]

[Document name to be amended] Drawing

[Correction target item name] All figures

[Correction method] Change

[Correction contents]

FIG.

FIG. 2

FIG. 4

FIG. 6

FIG. 7

FIG. 8

FIG. 3

FIG. 9

FIG. 5

FIG. 10

 ────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Akitaka Tomamechi 4-3-1 Tsunashimahigashi, Kohoku-ku, Yokohama-shi, Kanagawa F-term (reference) in Matsushita Communication Industrial Co., Ltd. 5K027 AA11 JJ07 5K067 AA03 BB04 EE02 EE10 FF16 GG01 HH22

Claims (4)

[Claims] 1. A mobile communication system comprising a base station and a plurality of mobile stations, wherein communication between mobile stations via a base station (base station communication) and direct communication between mobile stations (mobile) (Direct communication between stations) and the case where the frequency band of the carrier frequency is separated into adjacent bands, and when performing base station communication, a predetermined frequency in the frequency band for base station communication is used as the carrier frequency. When a frequency adjacent to a boundary with a frequency band for base station communication is used as a carrier frequency in direct communication between mobile stations, the base station corresponding to a frequency adjacent to the used carrier frequency in the mobile station is used. Detects the reception level of the downlink carrier frequency from the mobile station, and reduces the level of the carrier signal transmitted from the mobile station according to the reception level of the downlink carrier frequency. A communication method in a mobile communication system. 2. In a mobile communication system including a base station and a plurality of mobile stations, a frequency band of a carrier frequency is used for base station communication via a base station and direct communication between mobile stations. When performing direct communication between mobile stations, a predetermined frequency within a frequency band for base station communication is used as a carrier frequency, and the carrier frequency used in the mobile station is distinguished. Detecting the reception level of the downlink carrier frequency from the base station corresponding to the frequency adjacent to the base station, and reducing the level of the carrier signal transmitted from the mobile station according to the reception level of the downlink carrier frequency. A communication method in a mobile communication system. 3. When performing base station communication, a predetermined frequency within a frequency band for base station communication is used as a carrier frequency, while in direct communication between mobile stations, a frequency for direct communication between mobile stations is used. The communication method in a mobile communication system according to claim 1, wherein a frequency far from a boundary with a frequency band for base station communication in the band is used as a carrier frequency. 4. A mobile station of a mobile communication system including a base station and a mobile station, which is provided with wireless communication means for performing wireless communication and control channel information for switching a control channel for executing wireless communication. Control channel storage means for setting, reception level detection means for detecting a level of a control channel signal transmitted from the base station, and control means for controlling a wireless communication operation, wherein the control means comprises a direct communication between mobile stations. Carrier detection is performed at the time of calling operation by the wireless communication means in the above, and if the carrier frequency of the control channel at the time of calling is a frequency adjacent to the boundary with the frequency band for base station communication, the control transmitted from the base station The level of the channel signal is detected by the reception level detection means, and the transmission is controlled after the transmission power at the time of calling is set to a predetermined value, and then the calling is performed. A mobile station in a mobile communication system that.