The present invention relates to a radio communication apparatus in a radio packet communication system and, more particularly, to a radio communication apparatus in a radio packet communication system constituted by a plurality of radio stations and having a plurality of radio channels (to be simply referred to as channels hereinafter).
A radio LAN system is one of radio packet communication systems that have recently been standardized as systems for implementing high-speed data transmission by radio. In this radio LAN system, a plurality of radio stations form one radio link and share one channel by CSMA/CA (Carrier Sense Multiple Access with Collision Avoidance). In the radio LAN system, if adjacent radio links use the same channel, the throughput decreases due to cochannel interference. Conventionally, in the radio LAN system, as a technique of preventing interference from radio waves forming different radio links, the technique disclosed in Ishi et al., “Proposal of Packet DCA for Radio LAN” (Proceedings of 1996 IEICE Society Conference B-652) (reference 1) is available.
The technique disclosed in this reference 1 is characterized as follows. To prevent interference between one radio station belonging to a given radio link and the other radio station belonging to another radio link in a single radio communication system, each radio station transmits/receives a control packet upon forming a new radio link. When a given radio station receives a control packet from another radio station, the radio station determines that the corresponding channel is used by the other radio station in the same radio communication system, and selects a channel for which a control packet from another radio station is not received, thereby preventing interference with other radio stations in the same radio communication system.
In the radio LAN system, in communication between radio stations belonging to different radio links, when the two radio links are connected to a single wire network via base stations and the like, the radio station on the transmitting side transmits a packet to a base station connected to the radio link to which the self-station belongs, and the base station transfers the packet to a base station connected to the radio link to which the radio station on the receiving side belongs via the wire network. The base station connected to the radio link to which the radio station on the receiving side belongs transmits the packet to the radio station on the receiving side, thereby implementing communication.
In the conventional systems, no consideration is given to communication between radio links using different channels. For this reason, in a radio packet communication system like the radio LAN system described above, communication cannot be efficiently performed.
According to the channel selection method described in reference 1 and the like, different channels are used for adjacent radio links. When two radio stations belonging to the respective radio channels are to communicate with each other, they cannot directly communicate with each other, because they use different channels, regardless of whether they are located at a distance from each other within which direction communication is allowed.
In addition, as described above, although communication can be performed via a wire network in some cases, when, for example, two radio stations belong to radio links to which no base stations are connected or base stations, if any, are connected to different wire networks, the two radio stations cannot communicate with each other. In some cases, therefore, in a radio packet communication system like the radio LAN system described above, even radio stations that are otherwise capable of direction communication cannot communicate with other by using the conventional radio communication apparatus.
In communication via a wire network, as described above, since communication between radio stations and base stations is performed via two radio links, the radio channel usage is twice that for direct communication. Therefore, when radio stations belonging to different radio links communicate with each other, the number of used channels doubles as compared with the case of direct communication.
The present invention has been made in consideration of the above situation, and has as its object to provide a radio communication apparatus in a radio packet communication system, in which when a given radio station belonging to a given radio link transmits a packet to a radio station belonging to a different radio link, if this remote radio station is located at a distance within which direction communication is allowed, the packet is transmitted by using the channel used by the remote radio station to increase the probability of communication between radio stations, and the packet is directly transmitted to the remote radio station to reduce the number of used channels.
In order to achieve the above object, according to the first aspect of the present invention, there is provided a radio communication apparatus in a radio packet communication system, characterized by comprising a section for registering a channel used by a remote radio station, a section for selecting a channel that is registered and used by a destination radio station for a packet to be transmitted, and a section for transmitting/receiving the packet by using the selected channel, wherein if the channel used by the destination radio station for the packet to be transmitted is registered, the packet is transmitted by using the channel used by the destination radio station.
According to the second aspect of the present invention, there is provided a radio communication apparatus in a radio packet communication system, characterized by comprising a section for searching and determining whether a channel used by a destination radio station is registered, wherein if the channel used by the destination radio station for a transmission packet is not registered, the packet is transmitted via a channel used by a self-station.
According to the third aspect of the present invention, there is provided a radio communication apparatus in a radio packet communication system, characterized by comprising a section for notifying that a self-station cannot receive any packet, and a section for notifying that the self-station can receive a packet after a packet is transmitted, wherein a remote radio station can be notified whether the self-station can receive a packet.
According to the fourth aspect of the present invention, there is provided a radio communication apparatus in a radio packet communication system, characterized by comprising a section capable of performing communication by simultaneously using two channels, wherein communications can be simultaneously performed by using the two channels.
According to the fifth aspect of the present invention, there is provided a radio communication apparatus in a radio packet communication system, characterized by comprising a section for searching for a channel used by a destination radio station and registering the found channel, wherein the channel used by the destination radio station for a packet to be transmitted can be known.
According to the sixth aspect of the present invention, there is provided a radio communication apparatus in a radio packet communication system, characterized by comprising a section for searching for a channel by transmitting/receiving a control packet at the time of a channel search, wherein a channel used by a destination radio station for a packet to be transmitted can be known.
According to the respective aspects of the present invention, the following advantages can be obtained.
Since this apparatus has a means for performing direct communication by using a channel used by a destination ration station for a transmission packet, the apparatus can directly communicate with a radio station which belongs to a radio link using a different channel. This makes it possible to reduce the number of used channels and implement efficient communication.
If the channel used by a destination radio station for a transmission packet is not registered, a packet can be transmitted by using the channel used by the self-station as in the conventional radio communication apparatus. Even if, therefore, a channel is not registered, performance equivalent to that of the conventional radio communication apparatus can be provided.
In addition, when the self-station notifies a remote station that it cannot receive any data, the remote station can delay the transmission of a packet. This makes it possible to reduce losses of packets addressed to the self-station while another channel is used.
When this apparatus has a transmission/reception section for receiving a packet addressed to the self-station and a transmission/reception device for transmitting a packet by using another channel, a packet addressed to the self-station can be received while a packet is transmitted by using another channel, thereby reducing packet losses while packets are transmitted by using another channel.
Furthermore, since the channel used by a destination radio channel for a transmission packet can be automatically searched out and registered, even if the channel used by the destination radio channel for a transmission packet is not registered, a packet can be transmitted by using the channel used by the destination radio station.
The above and many other objects, aspects, and advantages of the present invention will be apparent to those skilled in the art by the following detailed description of the preferred embodiments conforming to the principle of the present invention in conjunction with the accompanying drawings.
Several preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings. Assume that in each embodiment, each radio station has a unique address, and a transmission packet as data to be transmitted contains the address of a destination radio station.
When a transmission data signal is input at the time of data transmission, the channel control section 101 notifies the channel registration section 102 of the address signal contained in the transmission data signal by using an address search signal. The channel registration section 102 searches the correspondences between the registered addresses and channels on the basis of the input address signal and notifies the channel control section 101 of the resultant data as an address/channel correspondence signal.
The channel control section 101 notifies the transmission/reception section 103 of a channel control signal on the basis of the input address/channel correspondence signal, and also notifies the transmission/reception section 103 of the transmission data signal.
The transmission/reception section 103 changes the channel on the basis of the channel control signal and transmits the transmission data signal to a radio channel. At the time of data reception, a reception data signal is output from the transmission/reception section 103.
The operation of the first embodiment of the present invention will be described next with reference to
At the time of data transmission, as shown in
If the selected channel is the same channel as that used by the self-station (Y in step 401), the channel control section 101 transmits a packet via the channel set by notifying the transmission/reception section 103 of transmission data (step 404).
If the selected channel differs from the channel used by the self-station after the end of packet transmission (N in step 405), the channel control section 101 notifies the transmission/reception section 103 of the channel used by the self-station to switch the channel in the transmission/reception section to the channel used by the self-station (step 406), and sends a reception start packet to the remote radio station to notify it that the self-station has resumed reception via the self-station channel (step 407).
If the selected self-station channel is the same as that stored in the self-station channel storage section 104 and used by the self-station (Y in step 405), the channel control section 101 neither performs channel switching processing for switching to the self-station channel nor sends a reception start packet.
The operation of the second embodiment of the present invention will be described next with reference to
If the channel selected in step 201 in
In the second embodiment, if the channel selected in step 201 differs from the channel notified by a self-station channel notification signal stored in the self-station channel storage section 104, there is no need to send a reception stop packet to the remote radio station and notify it that the self-station will switch channels. This makes it possible to improve the efficiency of transmission/reception processing.
The channel search processing section 701 searches the correspondences, between addresses and channels which are not registered in the channel registration section 102, on the basis of an input address signal. If there is a radio station that has a corresponding destination address, the channel search processing section 701 selects the corresponding channel number and notifies the channel control section 101 of the number as an address/channel correspondence signal. The channel search processing section 701 also registers the correspondence between the destination address and the selected channel number in the channel registration section 102.
If the channel corresponding to the destination address is not registered, the channel registration section 102 notifies the channel search processing section 701 of the corresponding information by using a channel search signal. Upon reception of the channel search signal, the channel search processing section 701 searches for a channel corresponding to the destination address, and notifies the channel registration section 102 of the search result by using a channel search result signal.
The operation of the third embodiment of the present invention will be described next with reference to
At the time of channel selection, the channel control section 101 searches the correspondences between the registered addresses and channels on the basis of the destination address (step 801). If the corresponding channel is registered (Y in step 802), the channel control section 101 selects the registered channel (step 803). If the corresponding channel is not registered (N in step 802), i=1 is set (step 804).
Assume that in the third embodiment, the total number of channels is N, and the numbers 1 to N are assigned to the respective channels. “i” represents the number of a channel undergoing a search. “x” represents the number of the channel used by the self-station. If a channel undergoing a search differs from the channel used by the self-station (N in step 805), the channel control section 101 searches for a radio station having the destination address (step 806).
If it is determined after the search that there is no radio station having the destination address (N in step 807), and the channel undergoing a search is the one used by the self-station (Y in step 805), the channel control section 101 increments the channel number by one (step 808). If it is determined that “i” is equal to or smaller than N and not all the channels have been searched (Y in step 809), the flow returns to step 805 to search the next channel.
If it is determined on the basis of the result from step 808 that “i” becomes larger than N and all the channels have been searched (N in step 809), the channel control section 101 selects the channel which the self-station is using (step 810). If it is determined on the basis of the search result in step 806 that there is a radio station having the destination address (Y in step 807), the channel control section 101 selects the channel having a channel number “i” (step 811), and registers the correspondence between the destination address and the selected channel “i” in the channel registration section 102 (step 812).
The channel control section 101 then sets “j” representing the number of times of retransmission of a control packet to 0 (step 901), transmits a response request packet to the destination address (step 902), and starts a timer (step 903). The channel control section 101 then waits for the reception of a response packet (step 904) until the timer causes a timeout (step 905). When the timer reaches a predetermined value and causes a timeout (Y in step 905), one added to “j” (step 906).
If it is determined that “j” is equal to or less than M (Y in step 907), the flow returns to step 902 to repeatedly transmit the response request packet. In this case, M is a predetermined upper retransmission count limit value. If “j” exceeds the upper retransmission count limit value (N in step 907), it is determined that there is no radio station corresponding to the destination address (step 909).
If a response packet is received before the timer causes a timeout (Y in step 904), it is determined that there is a radio station corresponding to the destination address (step 908), and the flow advances to steps 811 and 812 in
The fourth embodiment of the present invention is comprised of a channel control section 101, channel registration section 102, transmission/reception section 103, and self-station channel storage section 104 like those in the first embodiment, a self-station channel transmission/reception section 501 and remote channel transmission/reception section 502 like those in the second embodiment, and a channel search processing section 701 like the one in the third embodiment. The channel search processing section 701 performs search processing for a channel corresponding to a destination address by using the remote channel transmission/reception section 502.
The operation of the fourth embodiment of the present invention will be described next with reference to
At the time of a search, first of all, the channel control section 101 switches the channel in the remote channel transmission/reception section 502 (step 602). The channel control section 101 then sets “j” representing a control packet retransmission count to 0 (step 901), transmits a response request packet to the destination address by using the remote channel transmission/reception section 502 (step 1101), and starts a timer (step 903).
The channel control section 101 then waits for the reception of a response packet (step 904) until the timer causes a timeout (step 905). When the timer reaches a predetermined value and causes a timeout (Y in step 905), one is added to “j” (step 906). If it is determined that is equal to or less than M (Y in step 907), the flow returns to step 902 to repeatedly transmit the response request packet.
In this case, M is a predetermined upper retransmission count limit value. If “j” exceeds the upper retransmission count limit value (N in step 907), it is determined there is no radio station corresponding to the destination address (step 909). If a response packet is received before the timer causes a timeout (Y in step 904), it is determined that there is a radio station corresponding to the destination address (step 908).
The above description has only exemplified the preferred embodiments of the present invention, and does not limit the range of the present invention. As is obvious to a person skilled in the art, various changes and modifications to which the invention pertains can be made within the spirit and scope of the invention.
Number | Date | Country | Kind |
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10-205682 | Jul 1998 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP99/03896 | 7/21/1999 | WO | 00 | 1/22/2001 |
Publishing Document | Publishing Date | Country | Kind |
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WO00/05843 | 2/3/2000 | WO | A |
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5715295 | Yamashita | Feb 1998 | A |
5883887 | Take et al. | Mar 1999 | A |
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6459690 | Le Strat et al. | Oct 2002 | B1 |
6563806 | Yano et al. | May 2003 | B1 |
6700875 | Schroeder et al. | Mar 2004 | B1 |
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