Patent Application
20120170505
The present invention relates to communications technologies, and in particular, to a method, a device and a system for a relay to establish a connection with a base station.
With the rapid development of high-speed network technologies and multimedia technologies, the wireless network is developed very rapidly. Radio waves have an attenuation problem, and a high working frequency results in very limited coverage of base stations. Therefore, the existing technology adds wireless relays to the network to enlarge the coverage of the system.
A wireless relay communicates with a base station through an air interface, and the base station is called as a serving base station. A base station that is also close to a wireless relay but does not establish a connection with the wireless relay is called as a non-serving base station, as shown in
In the implementation process of the present invention, the inventors find that, a relay in the existing technology needs to communicate with a non-serving base station through an Rn interface and an X2 interface, resulting in double time delay.
Embodiments of the present invention provide a method, a device and a system for a relay to establish a connection with a base station, which are used for a relay to establish a connection with a non-serving base station.
A method for a relay to establish a connection with a base station provided in an embodiment of the present invention includes receiving interface information sent from a serving base station. Resource information is obtained from the interface information. The resource information is used for indicating wireless resources used when the relay communicates with a non-serving base station. A wireless connection is established with the non-serving base station in the wireless resources indicated by the resource information.
A relay provided in an embodiment of the present invention includes a first receiving module, configured to receive interface information sent from a serving base station. A first obtaining module is configured to obtain resource information from the interface information received by the first receiving module, where the resource information is used for indicating wireless resources used when the relay communicates with a non-serving base station. A first establishing module is configured to establish a wireless connection with the non-serving base station in the wireless resources indicated by the resource information obtained by the first obtaining module.
A base station provided in an embodiment of the present invention includes a second sending module, configured to send interface information to a relay, where the interface information includes resource information used for indicating wireless resources used when the relay communicates with a non-serving base station. A third sending module is configured to send the interface information to the non-serving base station, where the interface information includes resource information used for indicating wireless resources used when the non-serving base station communicates with the relay.
A communication system provided in an embodiment of the present invention includes a relay configured to receive interface information sent from a serving base station. Resource information is obtained from the interface information, where the resource information is used for indicating wireless resources used when the relay communicates with a non-serving base station. A wireless connection is established with the non-serving base station in the resources indicated by the resource information. A base station is configured to send interface information to the relay, where the interface information includes the resource information used for indicating the wireless resources used when the relay communicates with the non-serving base station. The interface information is sent to the non-serving base station, where the interface information includes the resource information used for indicating the wireless resources used when the non-serving base station communications with the relay.
According to a method, a device and a system for a relay to establish a connection with a base station provided by the embodiments of the present invention, a connection is established in the foregoing resources finally, by receiving interface information sent from a serving base station, selecting frequency bands or proceeding with the receiving of an uplink polling interval. The technical problem of establishing a wireless connection with an adjacent non-serving base station is resolved, so as to lay a foundation for reducing communication time delay with the adjacent non-serving base station.
In the implementation process of embodiments of the present invention, the inventors find that, a relay often needs to exchange data with an adjacent non-serving base station. However, in the existing technology, no interface (including a wireless interface and a wired interface) exists between a relay and a non-serving base station. Therefore, the forwarding needs to be completed through a serving base station, resulting in the increase of time delay. The increased time delay also influences other performances of a system. For example, in a case of searching for disturbing users, the time delay results in the decrease of throughput.
Step 201: Receive interface information sent from a serving base station.
Step 202: Obtain resource information from the interface information, where the resource information is used for indicating wireless resources used when a relay communicates with a non-serving base station.
Step 203: Establish a wireless connection with the non-serving base station in the resources indicated by the resource information.
The embodiment is applicable to a process in which a relay establishes a connection with an adjacent non-serving base station by using a frequency division method. A relay first receives interface information sent from a serving base station, obtains resource information from the interface information to use the resource information for communicating with a non-serving base station, and finally establishes a connection with the non-serving base station in selected resources. Each step is described in detail in the following.
In the process of establishing a wireless connection between a relay and a non-serving base station, a serving base station sends interface information to the relay, where the interface information may include time domain resources, or frequency domain resources, or both time domain and frequency domain resources. Specifically, when the resources are time domain resources, the serving base station may send time slot information to the relay; when the resources are frequency domain resources, the serving base station may send frequency bands to the relay; when the resources are both time domain and frequency domain resources, the serving base station may send the time domain and frequency domain resources to the relay simultaneously. Methods of obtaining the resource information include: direct parse, generally applied when only a pair of uplink and downlink resources are received; or selecting uplink and downlink resources from a selectable resource set, generally applied when multiple pairs of uplink and downlink resources are received. The serving base station may send, to the relay, signaling of initiating a random access process. If no feedback is given, the non-serving base station may learn a selection result of a UE through monitoring. Finally, the relay establishes a wireless connection with the non-serving base station in the frequency bands. A schematic diagram of the process is shown in
After a connection is established, a relay can send information to a non-serving base station through the connection. For example, if a relay is disturbed by an adjacent non-serving base station, the relay can directly send load indication information to the non-serving base station through the interface to search for disturbing users. Therefore, time delay is reduced by 50% and throughput is increased. For another example, if a UE is switched over from a serving base station to a non-serving base station or in the case of CoMP coordination, a relay can also exchange information with the non-serving base station through the interface, thereby reducing time delay by 50% compared with the existing technology.
The embodiment of the present invention resolves a technical problem of establishing a wireless connection between a relay and an adjacent non-serving base station, and lays a foundation for reducing the communication time delay with the adjacent non-serving base station.
Step 301: Receive interface information sent from a serving base station.
Step 302: Select frequency bands from the foregoing interface information to use the bands for communicating with a non-serving base station.
Step 303: Establish a wireless connection with the non-serving base station in the foregoing frequency bands.
The embodiment is applicable to a process in which a relay establishes a connection with an adjacent non-serving base station by using a frequency division method. A relay first receives interface information sent from a serving base station, then selects uplink and downlink frequency bands from the interface information to use the bands for communicating with a non-serving base station, and finally establishes a connection with the non-serving base station in the selected frequency bands. Each step is described in detail in the following.
In the process of establishing a wireless connection between a relay and a non-serving base station, a serving base station sends interface information to the relay. When the non-serving base station supports the receiving and sending of data in all frequency bands, the interface information may include information A1 about a set of frequency bands that are not used by the foregoing serving base station or a base station around the serving base station, or information A2 about a set of frequency bands that are used by the foregoing serving base station and a base station around the serving base station.
When the non-serving base station supports the receiving and sending of the data only in some frequency bands, the interface information may include information A3 about a set of frequency bands that are not used by the foregoing serving base station or a base station around the serving base station and are supported by the non-serving base station. Specifically, when the non-serving base station supports different frequency bands in uplink and downlink, the A3 set is further required to be divided into two subsets, where A3a is information about a set of frequency bands that are not used by the foregoing serving base station or a base station around the serving base station and are supported by the non-serving base station in the downlink, and A3b is information about a set of frequency bands that are not used by the foregoing serving base station or a base station around the serving base station and are supported by the non-serving base station in the uplink. After receiving the information, the relay selects frequency bands that are suitable to be used by itself.
The selection method is as follows. It is assumed that a set of frequency bands that are supported by the relay and are for transmitting data is a set B (likewise, the relay may possibly support different frequency bands in the uplink and downlink, and then B is divided into two sets. The detailed method of dividing B is similar to that of dividing A3, which will not be described herein again). If the set A1 or A3 is received, a UE selects frequency bands in the intersection of A1 and B or the intersection of A3 and B. If the set A2 is received, the UE selects frequency bands in the intersection of the complementary set of A2 and B. After the selection, the relay may or may not feed back the frequency bands to the serving base station. If the relay feeds back the frequency bands to the serving base station, the serving base station sends, to a neighboring non-serving base station, carrier information selected by the relay. After receiving the information, the non-serving base station feeds back confirmation information. The serving base station may send, to the relay, signaling of initiating a random access process. If the relay does not feed back the frequency bands to the serving base station, the non-serving base station may learn a selection result of the UE through monitoring. Finally, the relay establishes a wireless connection with the non-serving base station in the foregoing frequency bands. A schematic diagram of the process is shown in
After a connection is established, a relay can send information to a non-serving base station through the connection. For example, if a relay is disturbed by an adjacent non-serving base station, the relay can directly send load indication information to the non-serving base station through an interface to search for disturbing users, thereby reducing time delay by 50% and increasing throughput. For another example, if a UE is switched over from a serving base station to a non-serving base station or in the case of CoMP coordination, a relay can also exchange information with the non-serving base station through the interface, thereby reducing time delay by 50% compared with the existing technology.
The embodiment of the present invention resolves the technical problem of establishing a wireless connection between a relay and an adjacent non-serving base station, and lays the foundation for reducing communication time delay with the adjacent non-serving base station.
The embodiment may further include a first feedback module 504, configured to send, to the serving base station, information about the frequency bands selected by the first selecting module. A second receiving module 505 is configured to receive signaling that is of requiring initiating a random access process with the non-serving base station and is sent from the serving base station. A first sending module 506 is configured to send connection establishment completion information to the serving base station.
This embodiment is applicable to the embodiment shown in
This embodiment is applicable to the embodiment shown in
This embodiment is applicable to the embodiment shown in
Step 801: Receive interface information sent from a serving base station.
Step 802: Receive a downlink polling interval that is sent from the serving base station and is used for communicating with a non-serving base station.
Step 803: Establish a wireless connection with the non-serving base station according to the interface information and the downlink polling interval.
The embodiment is applicable to a process in which a relay establishes a connection with an adjacent non-serving base station by using a time division method. A relay first receives interface information sent from a serving base station, then receives a downlink polling interval that is sent from the serving base station and is used for communicating with a non-serving base station, and finally establishes a connection with the non-serving base station in a selected time segment. Each step is described in detail in the following.
In the process of establishing a wireless connection between a relay and a non-serving base station, a serving base station sends interface information to the relay, where the interface information includes an uplink polling interval T2 that is used for communicating with the non-serving base station. After receiving T2, the relay can feed back confirmation information to the serving base station, and then the serving base station sends T2 to the non-serving base station. After receiving the information, the non-serving base station feeds back confirmation information, and attaches, in the confirmation information, its own downlink polling interval T2* used for communicating with the relay. The serving base station sends T2* to the relay. After receiving T2*, the relay may feed back confirmation information to the serving base station. A wireless connection is established according to T2 and T2*. That is, the relay sends information to the non-serving base station at an interval of T2, and the non-serving base station sends information to the relay at an interval of T2*. The information process is shown in
After a connection is established, a relay can send information to a non-serving base station through the connection. For example, if a relay is disturbed by an adjacent non-serving base station, the relay can directly send load indication information to the non-serving base station through an interface to search for disturbing users, thereby reducing time delay by 50% and increasing throughput. For another example, if a UE is switched over from a serving base station to a non-serving base station or in the case of CoMP, a relay can also exchange information with the non-serving base station through the interface, thereby reducing time delay by 50% compared with the existing technology.
The embodiment of the present invention resolves a technical problem of establishing a wireless connection between a relay and an adjacent non-serving base station in another way, and lays a foundation for reducing communication time delay with the adjacent non-serving base station.
The embodiment may further include a second feedback module 1004, configured to feed back confirmation information.
This embodiment is applicable to the embodiment shown in
This embodiment is applicable to the embodiment shown in
This embodiment is applicable to the embodiment shown in
Based on the description of the foregoing embodiments, persons skilled in the art can clearly understand that, the present invention can be implemented through hardware or in a method of software adding a necessary common hardware platform. Based on the understanding, the technical solutions of the present invention may be materialized in the form of a software product, where the software product may be stored in a nonvolatile storage medium (such as a CD-ROM, USB disk and mobile hard disk) and include several commands to enable a computer device (such as a personal computer, server or network device) to implement the method in the foregoing embodiments of the present invention.
Persons skilled in the art can understand that, the accompanying drawings are only schematic diagrams of exemplary embodiments, and the modules or processes in the accompanying drawings are not necessarily required for implementing the present invention.
Persons skilled in the art can understand that, modules in devices in the foregoing embodiments can be distributed in the devices of the embodiments according to the embodiment description, and can also be distributed in one or multiple devices different from the foregoing embodiments. The modules in the foregoing embodiments can be combined into one module or may be divided into multiple submodules.
The serial numbers of the embodiments of the present information are for description only, and should not stand for the priority of the embodiments.
The above embodiments are merely several specific embodiments of the present invention, but not intended to limit the present invention. All other embodiments obtained by persons skilled in the art based on the embodiments of the present invention without creative efforts shall fall within the protection scope of the present invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 200910109250.8 | Jul 2009 | CN | national |
This application is a continuation of International Application No. PCT/CN2010/075469, filed on Jul. 27, 2010, which claims priority to Chinese Patent Application No. 200910109250.8, filed on Jul. 29, 2009, both of which are hereby incorporated by reference in their entireties.
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/CN2010/075469 | Jul 2010 | US |
| Child | 13358196 | US |
