JP2008271011A - Radio communication system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radio communication system capable of performing efficiently and rapidly scanning processing in a handover operation even if a mobile terminal conducts radio LAN communication between itself and a base station. <P>SOLUTION: In the radio communication system, base stations 201, 251 and 261 produce beacon signals including at least adjacent channel information which represents channels set in an adjacent base station adjacent to its own station and output the beacon signals. The mobile terminal 101 extracts the adjacent channel information included in the beacon signals. Further, in the handover operation, the mobile terminal 101 tests the reception state of signals from the adjacent base station where a channel according to the extracted adjacent channel information has been set (scanning processing). <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a wireless communication system, and can be applied to, for example, a wireless communication system to which a wireless LAN of the IEEE802.11a / b standard is applied and which has a mobile terminal capable of switching a wireless frequency.

  As a wireless communication system including a plurality of base stations and a mobile terminal capable of communicating with the base station, for example, Patent Document 1 exists.

  The technique according to Patent Document 1 is premised on a system in which data addressed to a mobile terminal is transmitted from a base station in a time division manner. In this technology, a mobile terminal scans a base station channel other than the current connection destination at the timing when there is no data addressed to the mobile station so that received data is not dropped during handover, for example, The reception state at the radio frequency is being tested (hereinafter, the test process is referred to as scanning). As a result of the scan, the mobile terminal switches the channel to a predetermined radio frequency for communication with a more optimal base station.

JP-A-1-218135

  The technique according to Patent Document 1 is premised on a system using a method in which data is transmitted in a time-division manner. Therefore, the technology according to Patent Document 1 cannot be adopted in a communication system that performs transmission / reception of random data, such as a wireless LAN that is a DCF (autonomous distributed control) system. That is, even if the technology according to Patent Document 1 is adopted for the communication system, the mobile terminal cannot measure the scan timing without missing necessary data.

  Moreover, in the technique which concerns on patent document 1, the consideration which avoids generation | occurrence | production of a dead zone when using a radio frequency band with a strong straightness is missing. Here, the dead zone is a zone where radio waves from the base station are blocked by a wall or the like and the mobile terminal cannot communicate with the base station. When the dead zone exists, it causes serious trouble such as sound interruption for a service that requires real-time performance such as voice data.

  Therefore, the present invention can efficiently perform a scan process at the time of handover even when a mobile terminal performs wireless LAN communication with a base station (in other words, the scan process). It is an object of the present invention to provide a wireless communication system. It is another object of the present invention to provide a wireless communication system that avoids the generation of a dead zone in a place with poor visibility and enables communication with high transmission efficiency in a place with good visibility.

  In order to achieve the above object, a radio communication system according to claim 1 according to the present invention includes a plurality of base stations and a mobile terminal that performs radio communication with the base station, and the base station Is a base station side beacon processing unit that generates a beacon signal including at least adjacent channel information indicating a channel set in an adjacent base station adjacent to the own station, and a base that transmits the beacon signal to the mobile terminal. A mobile terminal side beacon that includes a mobile terminal side radio reception unit that receives the beacon signal and that extracts the adjacent channel information included in the beacon signal. The mobile terminal is the adjacent base station in which the channel is set according to the extracted adjacent channel information at the time of handover. Testing the reception state of the signal.

  In the wireless communication system according to claim 1 of the present invention, the base station generates and outputs a beacon signal including at least adjacent channel information indicating a channel set in an adjacent base station adjacent to the base station. The mobile terminal extracts adjacent channel information included in the beacon signal. Further, at the time of handover, the mobile terminal tests a reception state of a signal from an adjacent base station in which a channel according to the extracted adjacent channel information is set (scan process).

  Therefore, even in a wireless communication system that performs random transmission / reception in a wireless LAN or the like, the scan process can be efficiently performed in a short time.

  Hereinafter, the present invention will be specifically described with reference to the drawings showing embodiments thereof.

<Embodiment 1>
Hereinafter, Embodiment 1 of the present invention will be described with reference to FIGS. 1, 2, and 3. FIG. FIG. 1 is a diagram illustrating a configuration of a wireless communication system. FIG. 2 is a diagram showing an example of a usage pattern of a system assumed by the present invention. FIG. 3 is a diagram showing the concept of radio frequency band switching in the present invention. In FIG. 1, only functional blocks are simplified and shown for the sake of clarity. Since the internal configurations of the base stations 201, 251, and 261 are the same, the internal configurations of the base stations 251 and 261 are not shown in FIG.

  As shown in FIG. 1, the radio communication system according to the present invention includes a mobile terminal 101, a plurality of base stations 201, 251, 261, and an upper base station 301. Communication via the wireless LAN 601 is performed between the mobile terminal 101 and each of the base stations 201 251 261. Further, communication via the wired LAN 401 is performed between the base stations 201, 251, 261 and the upper base station 301.

  The upper base station 301 in the present invention can communicate with the base stations 201, 251, and 261 via the wired LAN 401, and the base station information and adjacent channels described later are transmitted to the base stations 201, 251, and 261, respectively. Notify information.

  As shown in FIG. 1, the base stations 201, 251, and 261 in the present invention include a control unit 202, a beacon processing unit 203, and a wireless transmission / reception unit 204.

  The control unit (which can be grasped as a channel information receiving unit) 202 receives the local channel information and the adjacent channel information notified from the upper base station 301 via the wired LAN 401. Here, paying attention to the base station 201, the local station channel information is information indicating a channel set in the base station 201 which is the local station, and the adjacent channel information is an adjacent base station adjacent to the local station 201. 251 is information representing a channel set to 251. The beacon processing unit 203 generates a beacon signal including at least the adjacent channel information as an information element. The wireless transmission / reception unit 204 can set a channel at the time of communication according to the local station channel information notified from the control unit 202 and can transmit the beacon signal and the like to the mobile terminal 101 via the wireless LAN 601.

  As shown in FIG. 1, the mobile terminal 101 according to the present invention includes a radio transmission / reception unit 102, a control unit 103, and a beacon processing unit 104.

  The wireless transmission / reception unit 102 is a part that receives beacon signals and the like transmitted from the base stations 201, 251, and 261 via the wireless LAN 601. The control unit 103 receives the reception frame from the wireless transmission / reception unit 102 and extracts the control frame from the reception frame. Furthermore, the control unit 103 controls connection with the base stations 201, 251, and 261 according to the extracted control frame. The beacon processing unit 104 is arranged in the control unit 103, and extracts an adjacent channel (adjacent channel) from beacon signals transmitted from the base stations 201, 251, and 261. Further, the beacon processing unit 104 instructs the wireless transmission / reception unit 102 on the channel at the time of scanning.

  Here, the IEEE 802.11 standard, which is a well-known wireless LAN technology, is typically applied to the wireless LAN 601.

  Next, the operation of the radio communication system according to the present embodiment will be described with reference to FIG.

  FIG. 2 shows a case where the mobile terminal 101 moves from the radio cell 701 of the base station 201 to the radio cell 703 of the base station 261 via the radio cell 702 of the base station 251. As shown in FIG. 2, it is assumed that the base station 261 is set on the ceiling of a conference room with a screen (a place with poor visibility). On the other hand, it is assumed that the base station 201 and the base station 251 are installed on the ceiling of a floor with good visibility and without obstacles that block radio waves.

  First, in the installation situation, the upper base station 301 performs the following channel information setting process (input).

  In a place with good visibility as described above, a dead zone where the mobile terminal 101 cannot communicate with the base stations 201 and 251 occurs even if the radio frequency band with high straightness is set as the radio communication frequency of the base stations 201 and 251. There is nothing. Accordingly, the upper base station 301 is configured so that a channel of a radio frequency band (for example, IEEE802.11a) having a high degree of straightness and high transmission efficiency (for example, priority is given to the transmission efficiency) is set and assigned to the base stations 201 and 251. The setting of predetermined channel information is input.

  On the other hand, since the base station 261 is set in a place where the line of sight is poor, if the IEEE802.11a is set as the radio communication frequency band for the base station 261, a dead zone is generated in the vicinity of the screen. In places with poor visibility as described above, communication using a radio frequency band (for example, IEEE802.11b) having low diffraction efficiency but having a diffraction effect (prioritizing the diffraction effect) in consideration of the propagation characteristics of radio waves is beneficial. . Accordingly, in order to avoid the occurrence of the dead zone, the upper base station 301 is set with predetermined channel information so that a radio frequency band channel such as IEEE802.11b is set and assigned to the base station 261. Is input.

  Next, when the predetermined channel information as described above is input at the time of system construction, the upper base station 301 performs channel assignment according to the input via the wired LAN 401 to each of the base stations 201 251, 261 is notified. That is, the upper base station 301 notifies the base station 201, 251, 261 of its own channel information. Further, the upper base station 301 notifies the adjacent channel information to the base stations 201, 251, and 261 via the wired LAN 401 according to the input.

  For example, in the case of the configuration of FIG. 2, the base station 201 includes local channel information indicating a channel set in the local station and adjacent channel information indicating a channel set in the adjacent base station (base station 251). Is notified. Also, the base station 251 is notified of own channel information indicating a channel set for the own station and adjacent channel information indicating a channel set for the adjacent base station (base stations 201 and 261). Also, the base station 261 is notified of own channel information indicating a channel set for the own station and adjacent channel information indicating a channel set for the adjacent base station (base station 251).

  As described above, each base station 201, 251, 261 that has received its own channel information and adjacent channel information sets its own channel to a predetermined radio frequency according to its own channel information. Furthermore, each base station 201, 251, 261 sets adjacent channel information as an information element of a beacon signal transmitted from the own station. That is, each base station 201, 251, 261 generates a beacon signal including both its own channel information and adjacent channel information.

  Next, each base station 201, 251, 261 transmits the generated beacon signal to the mobile terminal 101.

  The mobile terminal 101 that has received the beacon signal extracts an adjacent channel from each received beacon signal.

  Now, the mobile terminal 101 belongs to the base station 201 and hands over to the base station 251 while performing communication (for example, a telephone call) in the radio cell 701. At the time of the handover, the mobile terminal 101 has previously extracted adjacent channel information from the beacon signal received from the base station 201, and at the time of the handover, the mobile terminal 101 selects the channel indicated by the extracted adjacent channel information. Scan with priority. That is, at the time of handover, the mobile terminal 101 tests the reception state of a signal from the adjacent base station 251 in which a channel according to the adjacent channel information extracted from the beacon signal of the base station 201 is set (scanning). processing).

  By such an operation, the data communication interruption time due to the scan can be minimized and the handover can be performed efficiently.

  In the technique according to Patent Document 1, it is assumed that the mobile terminal scans at a timing when there is no data addressed to the mobile station so as not to miss the received data, and the base station notifies the timing when there is no data described above. There was a need to do. However, for a system that performs random communication such as a wireless LAN, the conventional technology cannot predict the timing for transmitting data, and may notify the mobile terminal in advance of the timing when there is no received data. Can not.

  However, in the invention according to the present embodiment, since the beacon signal includes adjacent channel information, the mobile terminal 101 receives the beacon signal from the base stations 201, 251, and 261 to which the mobile terminal 101 belongs at an arbitrary timing. Thus, the channel to be scanned can be recognized in advance. For this reason, at the time of handover, the channel in which the connection destination base station exists can be preferentially scanned, so that the communication interruption time due to scanning can be minimized.

  Now, the mobile terminal 101 handed over to the base station 251 further enters the wireless cell 703 of the base station 261 through the conference room screen. The mobile terminal 101 is handed over to the base station 261 when the radio wave reception level from the base station 251 deteriorates due to the screen.

  At the time of the handover, the mobile terminal 101 extracts adjacent channel information from the beacon signal transmitted from the base station 251 when belonging to the base station 251. The adjacent channel information includes information indicating the channel of the base station 261 that is the handover destination.

  As described above, the mobile terminal 101 performs the scanning process according to the channel information extracted from the beacon signal transmitted from the base station 251 during the handover from the base station 251 to the base station 261. Thereby, the handover to the base station 261 can be realized efficiently in a short time.

  Here, in order to avoid the occurrence of a dead zone due to the screen of the conference room, as described above, the radio cell 703 has a low transmission efficiency but has a diffraction effect due to the propagation characteristics of radio waves (for example, IEEE802.11b). Has been generated. Therefore, the mobile terminal 101 can continue communication with the base station 261 without entering the dead zone even in a conference room with screens.

  Next, a radio frequency band switching method of the mobile terminal 101 at the time of handover performed as a result of each scan process will be described with reference to FIG. Here, as described above, the radio frequency band IEEE 802.11a with high transmission efficiency has lower reception sensitivity than the radio frequency band IEEE 802.11b with low transmission efficiency. Therefore, the reception level that can ensure communication quality (a state in which the reception error is within a specified range) needs to be higher in the radio frequency band IEEE 802.11a than in the radio frequency band 802.11b.

  The mobile terminal 101 compares the reception level of the signal (beacon signal, control / management signal, or data frame) transmitted from the base station 201, 251, 261 during the scanning process with a predetermined threshold value set in advance. Then, the reception frequency band is switched (channel switching). In other words, the mobile terminal 101 selects a radio frequency band to be preferentially scanned according to the reception level of signals transmitted from the base stations 201, 251, and 261.

  Here, in consideration of reception sensitivity of each radio frequency band, the mobile terminal 101 is preset with an 11a quality assurance threshold value 502, an 11a out-of-range determination threshold value 504, and an 11b out-of-range determination threshold value 506 (see FIG. 3).

  Here, the 11a quality assurance threshold 502 is a reception level that can ensure a state in which a reception error is within a specified range when the mobile terminal 101 applies IEEE 802.11a as a radio frequency band. The specified range of the reception error is appropriately determined at the time of system construction.

  Further, the 11a out-of-range determination threshold 504 is a reception level for performing out-of-range determination when the mobile terminal 101 applies IEEE 802.11a as a radio frequency band (that is, a reception level at which it is determined that it is difficult to continue communication). ). The reception level is appropriately determined at the time of system construction.

  The 11b out-of-range determination threshold 506 is a reception level at which it is determined that it is difficult to continue communication when the mobile terminal 101 applies IEEE 802.11b as a radio frequency band. The reception level is appropriately determined at the time of system construction.

  In FIG. 3, when the reception level is higher than the 11a quality assurance threshold 502, that is, when the reception level of the signal transmitted from the base station 201, 251, 261 belongs to the 11a priority selection section 501, the mobile terminal 101 The IEEE802.11a frequency band is preferentially scanned during handover.

  For example, in the usage mode of the system shown in FIG. 2, when the mobile terminal 101 belongs to the base station 201, both the radio frequency (IEEE802.11a) frame of the base station 251 and the radio frequency (IEEE802.11b) frame of the base station 261 Can be received. When the reception level of the higher signal at the mobile terminal 101 is larger than the 11a quality assurance threshold 502, the mobile terminal 101 preferentially selects the radio frequency band IEEE 802.11a in the scan process. Furthermore, the mobile terminal 101 recognizes in advance the channel of the base station 251 as the adjacent channel information included in the beacon signal from the base station 201. Therefore, the mobile terminal 101 preferentially scans the channel of the base station 251 in the radio frequency band 802.11a during handover.

  For example, when the mobile terminal 101 does not have prior adjacent channel information and the higher reception level at the mobile terminal 101 of signals from the base stations 201 251 261 is greater than the 11a quality assurance threshold 502 ( When the reception level is within the 11a priority selection section 501), the mobile terminal 101 sequentially scans all channels belonging to the radio frequency band IEEE802.11a at the time of handover.

  Further, it is assumed that the reception level in the mobile terminal 101 belongs to the 11b priority section 503 that is between the 11a quality assurance threshold value 502 and the 11a out-of-service area determination threshold value 504. In this case, since the 11b priority section 503 is equal to or less than the 11a quality assurance threshold 502, the communication quality deteriorates when the radio frequency band of the mobile terminal 101 is set to IEEE802.11a. Therefore, the mobile terminal 101 gives priority to IEEE802.11b as a radio frequency band in the scanning process.

  The 11b priority section 503 corresponds to a radio wave situation in the vicinity of the boundary between the wireless cell 702 and the wireless cell 703 in FIG. 2, that is, in the vicinity of a conference room partition.

  When the mobile terminal 101 is present at the boundary between the wireless cell 702 and the wireless cell 703, the mobile terminal 101 transmits the radio frequency band (IEEE802.11a) frame of the base station 251 and the radio frequency band (IEEE802.11b) frame of the base station 261. Can receive both. When the higher reception level of the mobile terminal 101 is in the 11b priority section 503, the mobile terminal 101 preferentially selects the radio frequency band IEEE802.11b in the scan process at the time of handover.

  In the moving direction of the mobile terminal 101 shown in FIG. 2, the mobile terminal 101 recognizes in advance adjacent channel information included in the beacon signal transmitted from the base station 261 when it belongs to the base station 251 (that is, the base station 261 channels are recognized in advance). Therefore, the mobile terminal 101 preferentially scans channels set in the base station 261 in the radio frequency band 802.11b.

  For example, when the mobile terminal 101 does not have prior adjacent channel information and the reception level at the mobile terminal 101 of the signals from the base stations 201, 251, and 261 belongs to the 11b priority section 503, at the time of handover In addition, the mobile terminal 101 sequentially scans all channels belonging to the radio frequency band IEEE 802.11b. Further, in the scanning process, when the mobile terminal 101 cannot detect the base stations 201, 251, and 261, the mobile terminal 101 next scans all the channels of IEEE802.11a.

  Now, a case is assumed where the higher reception level at the mobile terminal 101 of signals from the base stations 201 251 261 belongs to the 11b section 505. The 11b section 505 is equal to or less than the 11a out-of-range determination threshold 504, and the reception level is higher than the 11b out-of-range determination threshold 506. Therefore, in the above case, when the mobile terminal 101 applies the radio frequency band IEEE 802.11a, communication cannot be continued, but when the radio frequency band IEEE 802.11b is selected, the mobile terminal 101 can communicate. Become.

  The case where the (higher) reception level in the mobile terminal 101 belongs to the 11b section 505 corresponds to the peripheral area of the radio cell 703 in the system usage form example of FIG. In this case, the mobile terminal 101 belonging to the base station 261 sequentially scans all channels of the radio frequency band 802.11b at the time of handover.

  In addition, when the reception level at the mobile terminal 101 of the signal from the base station 201, 251, 261 belongs to the completely out-of-service area 507 that is equal to or less than the 11b out-of-range determination threshold value 506, the mobile terminal 101 transmits the radio frequency band IEEE802.11a and Even if the radio frequency band IEEE802.11b is applied, the mobile terminal 101 cannot secure communication quality with the base stations 201, 251, and 261.

  At the time of handover, the mobile terminal 101 sets (changes) its own channel to a radio frequency at which a signal with the highest reception level can be received as a result of each scan process.

  As described above, according to the radio communication system according to the present embodiment, adjacent channel information is included in beacon signals transmitted from base stations 201 251 261. Then, the mobile terminal 101 can extract adjacent channel information from the beacon signal.

  Therefore, when the mobile terminal 101 receives a beacon signal at an arbitrary timing from the base stations 201, 251, and 261 to which the mobile terminal 101 belongs, the mobile terminal 101 can recognize in advance the channel to be scanned at the time of handover. Therefore, even in a communication system that performs random transmission / reception in a wireless LAN or the like, the scan process can be efficiently performed in a short time.

  In addition, the radio communication system according to the present embodiment includes an upper base station 301 that performs channel assignment to the base stations 201, 251, and 261.

  Therefore, when the number of base stations needs to be increased and the channel assignment of each base station becomes complicated, the upper base station 301 can centrally control the channel assignment in a centralized manner. Therefore, in the above case, the system having the upper base station 301 becomes more effective.

  Further, in the wireless communication system according to the present embodiment, frequency bands are allocated to each base station 201, 251, 261 in consideration of the propagation characteristics of radio waves according to the installation status of the base stations 201, 251, 261. Yes. A radio frequency band to be scanned at the time of handover is selected according to the reception level of signals from the base stations 201, 251, and 261.

  Therefore, it is possible to realize a radio frequency switching system having a feature of enabling communication with high transmission efficiency in a place with a good view and avoiding a dead zone even in a place with a bad view and continuing the communication.

<Embodiment 2>
FIG. 4 is a diagram showing a configuration of the radio communication system according to the present embodiment.

  The wireless communication system shown in FIG. 4 has a functionally equivalent configuration to FIG. 1 described in the first embodiment. However, the configuration differs in the following points between the radio communication system shown in FIG. 4 and the radio communication system shown in FIG.

  That is, the radio communication system according to the present embodiment does not have the upper base station 301. Instead, in the wireless communication system, each base station 201, 251, 261 further includes a channel initial value memory unit 205. In the channel initial value memory unit 205, own channel information and adjacent channel information are stored in advance.

  The configuration other than the above differences is the same as that of the first embodiment. Also, the operation of the radio communication system according to the present embodiment is the same as that of the first embodiment except for the configuration of the above points.

  As described above, in the radio communication system according to the present embodiment, the upper base station 301 is omitted, and each base station 201, 251, 261 has the channel initial value memory unit 205 instead.

  Therefore, the scale of the entire system can be reduced as much as the upper base station 301 can be omitted, and a more inexpensive system can be realized.

  Note that each base station 201, 251, 261 transmits a beacon signal including adjacent channel information to the mobile terminal 101, a configuration in which the mobile terminal 101 extracts from the beacon signal, and when the mobile terminal 101 performs handover. The configuration for recognizing the channel of the adjacent base station in advance is the same between the second embodiment and the first embodiment.

  Therefore, even in a communication system that performs random transmission / reception in a wireless LAN or the like, the scan process can be efficiently performed in a short time.

  Furthermore, also in the radio communication system according to the present embodiment, frequency bands are allocated to each base station 201, 251, 261 in consideration of the propagation characteristics of radio waves according to the installation status of the base stations 201, 251, 261. . Then, the radio frequency band to be scanned at the time of handover is selected in accordance with the reception level of signals from the base stations 201, 251, and 261.

  Therefore, it is possible to realize a radio frequency switching system having a feature of enabling communication with high transmission efficiency in a place with a good view and avoiding a dead zone even in a place with a bad view and continuing the communication.

1 is a diagram showing a configuration of a radio communication system according to Embodiment 1. FIG. It is a figure which shows an example of the utilization form of a system. It is a figure explaining selecting the radio frequency band which should be scanned according to a receiving level and a predetermined threshold. 6 is a diagram illustrating a configuration of a wireless communication system according to a second embodiment. FIG.

Explanation of symbols

  101 mobile terminal, 102 wireless transmission / reception unit (mobile terminal side), 104 beacon processing unit (mobile terminal side), 201, 251, 261 base station, 203 beacon processing unit (base station side), 204 wireless transmission / reception unit (base station side) ), 205 channel initial value memory unit, 301 upper base station, 401 wired LAN, 601 wireless LAN.

Claims (5)

Multiple base stations,
A mobile terminal that performs wireless communication with the base station,
The base station
A base station side beacon processing unit that generates a beacon signal including at least the adjacent channel information indicating a channel set in an adjacent base station adjacent to the own station;
A base station-side radio transmitter for transmitting the beacon signal to the mobile terminal,
The mobile terminal
A mobile terminal-side wireless receiver that receives the beacon signal;
A mobile terminal side beacon processing unit that extracts the adjacent channel information included in the beacon signal;
The mobile terminal
At the time of handover, the reception state of the signal from the adjacent base station in which the channel is set according to the extracted adjacent channel information is tested.
A wireless communication system. An upper base station capable of communicating with the plurality of base stations is further provided,
The base station
A channel information receiving unit for receiving the local station channel information indicating the channel set in the local station and the adjacent channel information transmitted from the upper base station;
The wireless communication system according to claim 1. The base station
The local station channel information indicating the channel set in the local station and the adjacent channel information further include a memory unit that is stored in advance.
The wireless communication system according to claim 1. The mobile terminal
According to the reception level of the signal transmitted from the base station, the radio frequency band to be preferentially tested is selected.
The wireless communication system according to claim 1, wherein the wireless communication system is a wireless communication system. In the base station installed in a place with a good view,
The first radio frequency band giving priority to transmission efficiency is set,
In the base station installed in a place with poor visibility,
A second radio frequency band giving priority to the diffraction effect is set,
The wireless communication system according to claim 1, wherein the wireless communication system is a wireless communication system.

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