KR100734543B1 - Method for managing radio resources and radio system - Google Patents

Abstract

The present invention relates to a radio system and a radio resource management method in the radio system. The method includes receiving wireless capacity information of the wireless cell, receiving transmission capacity information about a transmission network, wherein the transmission network is used to connect a base station of the wireless network to a core network. The method includes determining a transmission capacity limit for the radio cell based on the transmission capacity information; Signaling a transmission capacity limit of the radio cell to the base station; adjusting the wireless communication capacity information at the base station based on the transmission communication capacity limit; Signaling adjusted radio communication capacity information about the radio cell from a base station; And managing radio resources of a wireless network by using the signaled adjusted radio communication capacity information about the radio cell.

Radio system, radio resource management unit, transmission network, transmission resource management unit.

Description

METHOOD FOR MANAGING RADIO RESOURCES AND RADIO SYSTEM}

The present invention relates to a method and a wireless system for managing radio resources in a wireless system.

The number of users and the density of mobile devices are increasing with the increasing demand for the delivery of large amounts of information through wireless communication systems. This raises a stronger need and demand for the communication capacity of the mobile communication system.

Instead of one form of radio access technology, future wireless communication networks may be used for several applications, such as wideband code division multiple access (WCDMA), improved data rates (GSM / EDGE) for wide area systems / wide area development for mobile communications. It has been proposed to use a form of wireless access technology. By using other technologies, the entire network can take advantage of the coverage and capacity characteristics of other technologies. This creates a new demand for the management of network resources. An important requirement is to manage the quality of service (QoS) without wasting resources on the network.

In the near future, wireless communication networks and wireless user equipment will increasingly support Internet Protocol (IP) based technologies. In most fixed networks, the amount of IP traffic has already exceeded the amount of circuit-switched traffic. It has also been proposed that when IP traffic begins to occupy a radio access network (RAN), the network layer can be removed and the cost saved by raw IP processing.

Radio resource management is a critical task for future communication networks, especially for communication networks that use packet switched transport networks with routing functions, such as IP packet based transport networks. IP packet-based transmission takes advantage of the very basic features of IP packets: when user data is divided into packets by means of IP, IP packets contain information about the packet's origin and destination, so that packets can be easily routed. To lose. This makes the IP packet very tolerant of network failures or certain topology changes-problems that are normally solved by external logic circuitry such as protection and management systems in other types of networks. The length of the IP packet is variable, which makes it easy to apply to various types of signaling and user data.

When data is written in IP packet format, the destination address makes a specific routing decision at the router, and the packet travels along the path to the destination. In a circuit switched network, content does not know its destination and the network signals a connection. Network communication capacity is determined by the signaled connection as long as the connection persists. In a packet network, user data is transmitted over a particular link and several successive packets may share the same connection.

Routing was first designed for file transfer, and is therefore essentially optimal for this purpose. The routing described above also works well in real time traffic, such as voice and video telephony, as long as sufficient network communication capacity is available and QoS can be protected.

Problems arise when a communication network becomes congested, for example when part of the communication network is overloaded. Congestion can occur, for example, when routers or other network elements receive data faster than data that can be transmitted from the router. If traffic is allowed to flow freely to the IP forwarding portion of the mobile network, the thin forwarding portion near the base station will be congested, as on the Internet.

 In the prior art, when the destination path is congested, data packets are dropped or retained, for example depending on the capabilities of the router. Packets queued in buffers in the communication system can be dropped to make room for arrival packets. It is possible to prevent new packets from entering the congested portion of the communication system until a room for new data is created. However, this technique causes problems such as poor quality of service and dropped data or delay, which is undesirable in real time telecommunication service, and deviation of delay.

In terms of coverage, it would be necessary to establish a wireless communication capacity that is larger than the transmission communication capacity of the links near the base station. The problem is that from the radio point of view but not from the radio point of view, for example, if handover from one cell to another makes sense, the method will eventually increase the likelihood of congestion. Congestion will be further increased by link failures that reduce transport communication capacity.

Data congestion issues are also introduced in the applicant's previous application (PCT / IB02 / 00919). In this application, the problem is solved by data routing: the congested portion of the communication system is recognized, and data through the congested portion is reduced by data routing through the selected base station. The application manages transport control, for example by monitoring QoS in the transport network, IP data flow through the transport network, and receives an IP transport resource manager (ITRM) that receives surveys indicating in particular traffic congestion from various elements of the network. ). An entity called a Common Resource Management Server (CRMS) is also described in this application, wherein the CRMS is responsible for the management of radio resource control. The CRMS receives periodic load and QoS measurements from each radio cell of the radio network and acts as an advisor to the entity responsible for radio network control functions of the radio access network. The above application introduces a method of information communication between ITMR and CMRS using a message from ITMR to CMRS.

It is an object of the present invention to provide an improved radio resource management method in a wireless system. This is accomplished by a radio resource management method in a wireless system, where the radio resource is used to provide a wireless connection between a user unit and a base station radio cell in a radio network of the radio system, the method comprising: radio communication capacity for a radio cell An information receiving step, a receiving communication capacity information regarding a transmission network, the transmission network is used to connect a base station of a wireless network to a core network, and a transmission communication capacity for a radio cell based on the transmission communication capacity information. Determining a limit, signaling a transmission capacity limit of the radio cell to the base station, adjusting the radio communication capacity information at the base station based on the transmission communication capacity limit, and adjusting the adjusted radio capacity information on the radio cell. Signaling from a base station and a scene relating to a radio cell Using the adjusted radio capacity information includes the step of managing radio resources of the radio network.

The invention also relates to a wireless system: at least one wireless network, the wireless network comprising at least one base station providing a user unit with a radio cell for wireless transmission and reception, wherein the base station of the wireless network is A transmission network providing a connection to a core network of a radio system, a radio resource management unit configured to receive radio communication capacity information about a radio cell, and managing radio resources between a base station and a user unit in the radio network, and a transmission network A transmission resource management unit configured to receive transmission communication capacity information relating to the transmission network resource management unit; Wherein the transmission resource management unit is configured to determine a transmission communication capacity limit for a radio cell based on the transmission communication capacity information, wherein the transmission resource management unit is configured to signal a transmission communication capacity limit of the radio cell to a base station, and the base station Is configured to adjust radio capacity information about the radio cell based on the transmission capacity limit, and the base station is configured to signal the adjusted radio capacity information about the radio cell to the radio resource management unit for use in radio resource management. The radio resource management unit is configured to manage radio resources of the radio network using the signaled adjusted radio communication capacity information about the radio cell.
The invention is also configured to receive radio communication capacity information about the radio cell and at least one base station providing a radio cell for radio transmission and reception to a user unit, the radio managing radio resources between the base station and the user unit. A transmission resource management unit for receiving transmission communication capacity information about the transmission network and managing the transmission network resource in a wireless system including a resource management unit, wherein the transmission resource management unit is based on the transmission communication capacity information. Determine a transmission capacity limit for the radio cell and signal the transmission capacity limit to a base station, whereby the base station adjusts the wireless communication capacity information based on the transmission capacity limit and adjusts the adjustment. Wireless capacity information Signaling to the original management unit, the radio resource management unit manages radio resources of the radio network using the signaled adjusted radio communication capacity information. The invention also relates to a radio resource management unit configured to receive radio communication capacity information about the radio cell, the radio resource management unit managing radio resources between a base station and a user unit within a radio network in a radio system, wherein the radio resource management A unit is configured to manage radio resources of the wireless network using signaled coordination radio capability information about the radio cell, wherein the signaled coordination radio capability information is signaled from a base station and relates to a transmission network of the radio system. Adjusted based on the transmission capacity limit determined based on the transmission capacity information.
The invention also provides a transmission network that provides the base station with a connection to the core network of the wireless system, and a wireless network configured to receive radio communication capacity information about the radio cell to manage radio resources between the base station and the user unit. A radio cell for radio transmission and reception to a user unit in a wireless system, comprising a resource management unit, and further comprising a transmission resource management unit configured to receive transmission communication capacity information about the transmission network and managing the transmission network resources. A base station of a wireless system for providing a wireless communication system, wherein the base station adjusts wireless capacity information about the wireless cell based on a transmission capacity limit determined based on transmission capacity information and signaled from a transmission resource management unit. ; And configure the radio resource management unit with the adjusted radio communication capacity information about the radio cell to manage radio resources using the adjusted radio communication capacity information.
The invention also relates to a base station for providing a radio cell for radio transmission and reception to a user unit: configured to receive radio capacity information about a radio cell, the radio resource between the base station and the user unit in the radio network A radio resource management unit for managing the data; A transmission resource management unit, configured to receive transmission communication capacity information about a transmission network, wherein the transmission resource management unit manages transmission network resources, wherein the transmission resource management unit is based on the transmission communication capacity information. Is configured to determine a limit; The transmission resource management unit is configured to signal a transmission communication capacity limit of the radio cell to the base station; The base station is configured to adjust radio communication capacity information about a radio cell based on the transmission communication capacity limit; The base station is configured to signal the radio resource management unit to use the adjusted radio communication capacity information about the radio cell for radio resource management, wherein the radio resource management unit is signaled adjusted radio communication capacity information about the radio cell. It is configured to manage the radio resources of the wireless network using.

Preferred embodiments of the invention are disclosed in the appended claims.

The method, system, transmission resource management unit, radio resource management unit and base station of the present invention provide several advantages. The present invention manages radio resources of a wireless system, for example, when performing a handover or selection of a target cell. It is possible for the wireless system to consider the transmission load situation. In an embodiment of the present invention, the best handover destination cell is selected from both wireless and transport network perspectives to avoid congestion in both networks.

Another advantage of the present invention is not only to reduce data congestion quickly in congestion situations but also to allow loads to be balanced among radio cells, thereby preventing congestion in advance.

Another advantage of the present invention is that no new interface is required between the transmission resource management unit and the radio resource management unit. The radio resource management unit does not need to know whether the network includes the transmission resource management unit.

In the following, the invention will be described in great detail with reference to the preferred embodiments and the attached drawings.

1 shows an example of a wireless system;

2 shows an example of a general protocol model of a wireless access system;

3 shows another example of a wireless system;

4 shows a flow chart describing a radio resource management method in a wireless system.

According to FIG. 1, a wireless system is described as an example of a system to which embodiments of the present invention can be applied. In FIG. 1, this embodiment is described in a simplified wireless system, where the main parts of the wireless system are: core network (CN) 100, wireless access network 130, 120, 160, and user unit (UE) 170. Include.

Figure 1 illustrates the general structure of an evolving 3G wireless system using interoperation between different technologies and different generations of a radio access network, where second, 2.5 and third generation network elements coexist. In the figure, the second generation wireless system is represented as GSM (wide area system for mobile communication), and the second generation wireless system based on the GSM based wireless system is an EDGE (enhanced data rate for wide area development) technology for increasing the data rate. It can also be used to perform packet transmission in GPRS (Wideband Packet Radio System). The third generation wireless system appears to be a wireless system known under the names of at least IMT-2000 (International Mobile Telecommunications 2000) and UMTS (General Mobile Telecommunications System).

The base station subsystem (BSS) 160 based on GSM consists of a base station controller (BSC) 166 and a transmit / receive base station (BTS) 162, 164. The base station controller 166 controls the transmission and reception base stations 162 and 164. The interface 106 between the core network 100 and the BSS 166 is called A. The interface between the BSC 166 and the BTSs 162, 164 is called A-bis. In principle, the devices that perform the radio paths and their functions should be located inside the management devices inside the transmit and receive base stations 162 and 164 and the base station controller 166. The practice deviates essentially from this principle.

The UMTS radio access network (UTRAN) 130 is comprised of a radio network subsystem 140. Each Radio Network Subsystem (RNS) 140 is comprised of a Radio Network Controller (RNC) 146 and Node Bs 142 and 144. Node B is a rather shortened concept, often replaced by a 'base station'. The interface between other Radio Network Subsystems (RNS) 140 is called lur. The interface 108 between the core network 100 and the UTRAN 130 is called lu. The interface between the RNC 146 and the Node Bs 142 and 144 is called lub. In terms of functionality, the radio network controller 146 roughly corresponds to the base station controller 166 of the GSM system and the Node Bs 142, 144 correspond to the base stations 162, 164 of the GSM system. A solution is also possible where the same device also functions as a base station and a Node B, ie where the device can simultaneously perform TDMA (time division multiple access) and WCDMA air interface.

The wireless system will use an IP technology based radio access network, namely IP RAN (Internet Protocol Radio Access Network, IP Radio Access Network) 120. 1 illustrates the role of IP RAN 120 used in an example of a radio access network (RAN) in which a present embodiment may be applied in a wireless system. The IP RAN 120 is a radio access network platform based on IP-technology, and the BSS (BSS) used in more general radio network access technologies and networks-UTRAN (UMTS radio access network) and GSM (wide area system for mobile communication) Interoperability with base station subsystems) or GERAN (GSM EDGE Radio Access Network).

IP RAN 120 may be briefly described with the following entity groups shown in FIG. 1: IP RAN such as IP Base Station (IP BTS) 126, RNGW (Radio Access Network Gateway, RAN Gateway) 121. Gateway; CSGW (line switched gateway) 123 and RNAS (radio access network server, RAN access server) 127, and IP public server not shown in FIG. 1 for clarity. The IP RAN also includes other elements, such as a router, which is also not shown in FIG.

In the IP RAN 120, most of the functions of the centralized controllers RNC146 and BSC166 move to the IP base station 126. In particular, all air interface protocols terminate at IP base station 126. Entities outside of IP base station 126 are required, for example, to perform common configuration and some radio resource (RR) functions, or to interact with common radio access networks or base station subsystems or gateways to the core network 100. do.

1 shows the coverage area, or cell, of a base station of another radio access network. Cells 143 and 145 represent the coverage areas of Node Bs 142 and 144, and cells 163 and 165 represent the coverage areas of base stations 162 and 164. As illustrated in FIG. 1, one NodeB 142, 144, or a base station 162, 164 serves one cell or, in the case of a base station, several cells that may be divided cells. The coverage area of the IP base station (IP BTS) 126 appears in a plurality of cells (124, 125, 128, 129) in the figure, but the IT BTS will also cover only one cell.

The user unit 170 shown in FIG. 1 is preferably applicable to both 2G and 3G systems and includes at least one transceiver for establishing a wireless connection to the radio access network 120. In general, user unit 170 is a mobile station and further includes an antenna, a user interface and a battery. Today, various kinds of user units 170 are available, such as units installed in automobiles or portable units, and the user units 170 may also have characteristics similar to those of personal computers or portable computers. The user unit 170 is connected to a wireless system via a base station of a radio access network, such as an IP RAN, to allow a user of the user unit to access the core network of the communication system.

2, a general protocol model for IP RAN is described. As depicted in FIG. 2, IP RAN internal functions and protocols may be classified into three different layers: radio network layer (RNL) 200, transport network layer 210 and operation and maintenance (Q & M). Policy Management Layer 220. As in FIG. 2, the protocol stack diagram generally further includes two planes, the control plane 202 and the user plane 212. 2 shows an application protocol 204 and a data stream 214 at the wireless network layer 200 and a signaling bearer 206, a transport network control protocol 208, a data bearer 216 and 224 and an IP at the transport network layer 210. Layer 205 is also shown application 222 in Q & M and policy management layers. The control plane 202 transmits signaling information, and the user plane 212 transmits all transmission and reception information by the user. The wireless network layer 200 includes all functions and protocols or cellular specific protocols related to wireless, ie, RAN. The transport network layer 210 represents a standard transport technique selected for use in an IP RAN. The transport network layer 210 in the IP RAN has a wider scope than in the UTRAN and is intended to provide only signaling bearers and data bearers and to control the establishment of user plane connections. The transport layer 210 is shared to the core network 100 (shown in FIG. 1). The operation and maintenance and policy management layer 220 handles network operation and maintenance and network policy management. Each layer may be described as a logical entity. Physical structures and physical network elements include one or more logical entities for each layer. More information about wireless telecommunication systems can be found in the literature and standards in the field.

3 illustrates a method of managing radio resources in a wireless system. The embodiment is described in a simplified wireless system, using an IP RAN based system as an example. However, embodiments are not limited to these systems by way of example and those skilled in the art will be able to apply the solution to other wireless systems or combinations thereof having the present essential features.

The radio system of FIG. 3 comprises a radio access network (RAN), in this case an IP RAN 120, but the radio access network may also be another packet switched network with routing function. The wireless system may be, for example, a virtual private network (VPN).

The wireless system includes at least a first user unit 370. In FIG. 3, a second user unit 372 is also shown. The IP RAN 120 of FIG. 3 includes a wireless network 324 and a transport network 322. As shown in FIG. 1, the logical function of the wireless network 324 provides the user unit 170 with wireless cells 124, 125, 128, 129 for wireless transmission and reception. Logical functions of the transport network 322 provide wireless cells 124, 125, 128, 129 with a connection to the core network 100.

Wireless network 324 includes base stations (BTS) 326,328, which in this case are IP base stations. The first base station 326 provides a wireless connection 307 to the first user unit 370 to enable connection to the wireless system. The second user unit 372 is also connected to the wireless network 324 via a first base station 326 that provides a wireless connection 306 to the user unit 372.

In a wireless system, the radio cells generated by the base stations generally overlap in a range to provide broad coverage. In existing wireless systems, wireless telecommunication connections are established by a user unit and a base station that communicate with each other on a wireless connection. That is, a call or data transmission connection between other user terminals is made through the base station. This is illustrated by the wireless connections 306, 307, 308 in FIG. 3. In particular, FIG. 3 shows a first base station 326 via a wireless connection where a user unit 370 that may have mobility, while measuring the common pilot of the first base station and the second base station for the possibility of handover. Shows the situation of communicating with. In the general situation where the user unit wireless connection moves from the first base station to the second base station, the new connection has better quality when there is no communication capacity in the new cell. Channel and cell handover enables continuity of wireless connections when the user terminal moves or the physical wireless channel changes as a function of time.

The core network 100 includes other generations of core networks such as 2G core network 332, 3G core network 334, 3G packet core network 336 and 2G packet core network 338.

IP RAN 120 also includes a radio access network gateway, which is an access point of the IP RAN from the core network and other radio access networks. Radio access network gateways include: CSGW (line switched gateway, CS gateway) 123, RNGW (radio access network gateway, RAN gateway) 121, and RNAS (radio access network server, RAN access server) 127 (FIG. Shown in 1). The transport network 322 is connected to the CSGW 123 via a connection 314 and to the RNGW 121 via a connection 315. In the example in FIG. 3, connections 314 and 315 are performed with IP connections, but their implementations are not limited to IP; Other suitable techniques can be used.

The 2G core network 332 includes a 2G mobile station controller (2G MSC) 323 connected to the CSGW 123 via interface A. The 3G core network 334 includes a 3G mobile station controller (3G MSC) 325 connected to the CSGW 123 via a lu-CS interface. The 3G packet core network 336 is connected to the RNGW 121 via a lu-PS interface. The 2G packet core network 338 is connected to the transport network 322 via a Gb / lP interface. In FIG. 3 the radio system also includes a radio resource management unit 301 which manages radio resources between a base station and a user unit in the radio network. The radio resource management unit 301 is configured to receive radio communication capacity information. The radio communication capacity information may be represented as a cell load of a radio cell. In the example of FIG. 3, the radio resource management unit 301 may be performed by one of the RAN public servers, an entity named a common resource management server (CRMS). However, performance of the implementation is not limited to CRMS, and the radio resource management unit 301 may be any entity configured to receive radio communication capacity information about the radio network 324.

The wireless system of FIG. 3 also includes a transmission resource management unit 300 that manages transmission network resources. The transmission resource management unit 300 is configured to receive transmission load information about the transmission network 322 to be available to a radio cell. In the example of FIG. 3, the transmission resource management unit 300 is performed by an entity called an IP transmission resource manager (ITRM). The ITRM belongs to the transport network 322 logical structure and manages and monitors resources that pass through the access portion of the IP transport network rather than the core network. However, the implementation of this embodiment is not limited to ITRM, and the transmission resource management unit 300 may be any entity configured to measure the transmission load of the transmission network 322.

The transmission resource management unit 300 receives a report and a survey indicating the transmission communication capacity of the transmission network. The transmission communication capacity may be indicated by a transmission load. The transmission resource management unit 300 may determine the traffic communication capacity limit for each radio cell 124, 125, 128, 129 based on the transmission communication capacity information received from the transmission network 322. The traffic capacity limit determined by the transmission resource management unit 300 for each base station 326,328 is the upper limit of user traffic for the gateway destined for the core network. The traffic capacity limit can also be the upper limit of user traffic from any base station to another base station, generally an adjacent base station.

The transmission resource management unit 300 signals each base station a transmission communication capacity limit of the radio cell.

The base station 326,328 then adjusts the wireless capacity information for the radio cell based on the transmission capacity limit. The base stations 326 and 328 signal the adjusted radio communication capacity information to the radio resource management unit 301. The radio communication capacity information reflecting the cell load is adjusted to reflect the transmission load of the transmission network.

The radio resource management unit 301 uses the adjusted radio capacity information to manage the radio resource-for example, to reorder the handover list.

The base stations 326 and 328 may use the transmission communication capacity limit to adjust the effective wireless communication capacity of the radio cell. The base stations 326 and 328 may use this information when receiving new connection requests such as, for example, the introduction of a handover or an initial connection.

The radio information management unit 301 may tune cell connection parameters to balance between cells. The radio resource management unit 301 may consider the transmission load of the transmission network in auto-tuning, in addition to the load of the radio interface indicated in the radio communication capacity information received by the radio resource management unit 301 from the radio cells. . Therefore, in addition to reducing congestion in a congestion situation that has already occurred, it is possible to avoid congestion in a wireless system in advance.

Use an example to make the embodiment of FIG. 3 more clear. The transmission resource management unit 300 is connected to the transmission network 322 via a connection 316 and receives information about the transmission communication capacity of the transmission network, for example, the connections 313, 314, 315, 317 and 318. Connections 314 and 315 directed to CSGW 123 and RNGW 121, and connections 317 and 318 coming from base station 328 and 326 are part of transmission network 322. Connections between base stations, such as connections 318, 313, 317 between BTS 326 and BTS 328 also belong to transport network 322. The radio resource management unit 301 receives information regarding wireless communication capacities of the BTS 326 and the BTS 328 via the connection 312, which information may be received from a wireless interface, such as wireless connections 307, 306, and 308. Reflect the load. If a high transmission load is detected at the connection 313, 314, 315, 317 or 318, the transmission resource management unit 300 uses the connection 311 to communicate with the BTS 326 and the BTS 328 via the connection 318, 313, 317, 314 or 315. Instruct the requesting user to reduce the amount of communication it may allow. At the same time, the information that the radio resource management unit 301 receives from the BTS 326 or the BTS 328 via the connection 312 is such that the BTS 326,328 reflects the command received from the transmission resource management unit 300. It is adjusted automatically. Then all the components, the BTSs 326 and 328, the transmission resource management unit 300 and the radio resource management unit 301 are without any direct connection between the transmission resource management unit 300 and the radio resource management unit 301. Operate according to consistent capacity information. If the transmission load at the connection 318, 313, 317, 314, or 315 is reduced back to a normal state, the transmission resource management unit 300 instructs the BTS 326,328 to put all the air interface communication capacity in use; This is also automatically recognized in the radio resource management unit 301.

Therefore, the gist of the embodiment shown in the example is a transmission reflecting the transmission communication capacity and the load situation in the transmission network 322, for example, when a handover or connection request arrives at each base station from the anchor point of the handover. Dynamically adjusting the radio capacity information, which is used by the BTSs 326 and 328 as radio communication capacity information about the radio cell reported to the radio resource management unit 301 in more detail, based on the communication capacity limit.

The radio communication capacity information signaled from the BTS to the radio resource management unit may be indicated by the cell load of the radio cell. In general, the wireless capacity information includes information on the maximum effective communication capacity of the cell and parameters indicating current load information expressed as a percentage of the maximum communication capacity, for example. Alternatively, the wireless capacity information may include a parameter that reflects the effective wireless capacity.

The functions disclosed may be performed in other parts of the wireless system by software means—generally as a processor and software thereof—although various hardware solutions may be implemented, such as circuits composed of logic elements or one or more custom semiconductor ASICs. Mixing of these other implementations can also be performed. When selecting a method of implementation, one of ordinary skill in the art will consider the requirements placed on the size and power consumption of the device, the required process communication capacity, the cost of production, and the yield. Referring to the flowchart of FIG. 4, a method of managing radio resources in a wireless system is illustrated. The radio resource is used to provide a radio connection between the user unit and each base station of a radio cell within the radio network of the radio system.

At method start 400, wireless capacity information is received 402 indicating a cell load of a valid wireless cell for a user unit.

Transmission capacity information regarding a valid transmission network is received for the wireless cell, which is used to connect the base station of the wireless network to the core network (404).

A transmission capacity limit for the radio cell is determined 406 based on the transmission capacity information.

The transmission capacity limit of the radio cell is signaled 408 to each base station of the radio cell.

The wireless capacity information is adjusted at the base station based on the received transmission capacity limit (410).

The adjusted radio capacity information of the radio cell is signaled from the base station to be used for radio resource management of the radio network (412).

The radio resource of the wireless network is managed 414 using the signaled coordinated radio capacity information of the radio cell.

Termination of Method 416.

The disclosed method is performed by the disclosed wireless system as well as other types of wireless systems may be used.

According to the method, the effective wireless communication capacity of the radio cell can be adjusted based on the received transmission communication capacity limit.

In the method, the wireless communication capacity information may be indicated by the cell load of the wireless cell. The transmission communication capacity information may be represented as a transmission load of the transmission network.

In an embodiment of the method, the radio capacity information indicates a current and maximum cell load of the radio cell.

In another embodiment of the method, the wireless capacity information indicates a current cell load and an effective wireless communication capacity of the wireless cell.

In an embodiment of the method, the transmission capacity information indicates a transmission load of a connection from one base station of the wireless network to another base station of the wireless network.

In an embodiment of the method, the adjusted radio capacity information of the radio cell is signaled from the base station to a radio resource management unit to be used for radio resource management. In an embodiment, the adjusted radio communication capacity information of the radio cell is signaled from the base station to a common radio resource management server.

In an embodiment of the method, the transmission capacity limit of the radio cell is determined in the transmission resource management unit. In an embodiment, the transmission capacity limit of the radio cell is determined in the Internet Protocol Transport Resource Manager.

In an embodiment of the method, a handover list is organized based on the adjusted radio capacity information of the radio cell.

In an embodiment of the method, the adjusted radio capacity information about the radio cell is used when processing a base station grant request.

In an embodiment of the method, the adjusted radio capacity information about the radio cell is used when processing a handover request.

Although the present invention has been described with reference to the accompanying drawings, it is apparent that the present invention is not limited thereto and may be modified in various ways within the scope of the invention as set forth in the appended claims.

Claims (28)

A method of managing radio resources in a wireless system, the radio resources providing a wireless connection between a wireless cell of a base station and a user unit in a wireless network of the wireless system, Receiving (402) wireless communication capacity information about the wireless cell; Receiving (404) transmission capacity information about a transmission network used to connect a base station of the wireless network to a core network; Determining a transmission capacity limit for the radio cell based on the transmission capacity information (406); Signaling (408) the transmission capacity limit of the radio cell to the base station; Adjusting (410) the wireless communication capacity information at the base station based on the transmission communication capacity limit; Signaling (412) the adjusted wireless communication capacity information about the radio cell from the base station; And managing (414) a radio resource of the wireless network using the signaled adjusted radio capacity information about the radio cell. The method of claim 1, And adjusting the effective wireless communication capacity of the wireless cell based on the received transmission communication capacity limit. The method of claim 1, The wireless capacity information includes: a current cell load and a maximum wireless communication capacity of the wireless cell; A current cell load and an effective wireless communication capacity of the wireless cell; A transport load of the transport network; And at least one element selected from the group consisting of a transmission load of a connection from one base station of the wireless network to another base station of the wireless network. The method of claim 1, Signal (412) from the base station to a radio resource management unit to use the adjusted radio capacity information about the radio cell to be used for radio resource management. The method of claim 1, And signaling (412) from the base station to a common radio resource management server so that the adjusted radio capacity information about the radio cell is used for radio resource management. The method of claim 1, And determining (406) the transmission capacity limit of the radio cell in a transmission resource management unit. The method of claim 1, The radio resource management method of the wireless system, characterized in that for determining the transmission capacity limit of the radio cell in the Internet Protocol transmission resource manager. The method of claim 1, And organizing a handover list based on the adjusted radio communication capacity information about the radio cell. The method of claim 1, And wherein the adjusted radio capacity information about the radio cell is used to process a base station grant request. The method of claim 1, And wherein the adjusted radio capacity information about the radio cell is used to process a handover request. One or more wireless networks 324 including one or more base stations 326 that provide wireless cells 124, 125, 128, 129 to the user unit 370 for wireless transmission and reception; A transmission network (322) for providing a connection to the core network of the wireless system to the base station of the wireless network; A radio resource management unit 301 configured to receive radio communication capacity information about the radio cells 124, 125, 128, 129 and managing radio resources between the base station 326, 328 and the user unit 370 in the radio network 324. )and; In a wireless system, configured to receive transmission communication capacity information about the transmission network 322, and comprising a transmission resource management unit 300 for managing the transmission network resource, The transmission resource management unit (300) is configured to determine a transmission communication capacity limit for a radio cell based on the transmission communication capacity information; The transmission resource management unit (300) is configured to signal the transmission communication capacity limit of the radio cell to the base station (326); The base station (326) is configured to adjust the wireless communication capacity information about the wireless cell based on the transmission communication capacity limit; The base station 326 is configured to signal to the radio resource management unit 301 the adjusted radio communication capacity information about the radio cell for use in managing radio resources; The radio resource management unit (301) is configured to manage radio resources of the radio network (324) using the signaled adjusted radio capacity information about the radio cell. The method of claim 11, wherein The effective wireless communication capacity of the wireless cell is adjusted based on the received transmission communication capacity limit. The method of claim 11, wherein The wireless capacity information includes: current cell load and maximum wireless communication capacity of the wireless cells 124, 125, 128, 129; Current cell load and effective wireless communication capacity of the wireless cells (124, 125, 128, 129); A transmission load of the transmission network 322; And at least one element selected from the group consisting of transmission loads of connections from one base station (326) of the wireless network to another base station (328) of the wireless network (324). The method of claim 11, wherein And the base station (326) is configured to signal the adjusted radio communication capacity information of the radio cell to a common radio resource management server (301) for use in radio resource management. The method of claim 11, wherein A handover list is organized based on the adjusted wireless capacity information about the wireless cell (124, 125, 128, 129). The method of claim 11, wherein And the coordinated wireless capacity information about the wireless cell (124, 125, 128, 129) is used when processing a base station grant request. The method of claim 11, wherein And the adjusted wireless capacity information about the wireless cell (124, 125, 128, 129) is used when processing a handover request. The method of claim 11, wherein The base station (326) is configured to adjust the effective wireless communication capacity of the radio cell based on the transmission communication capacity limit. The method of claim 11, wherein The transmission resource management unit (300) is a wireless system, characterized in that the Internet protocol transmission resource manager. The method of claim 11, wherein And said radio resource management unit (301) is a common radio resource management server. The method of claim 11, wherein The radio resource management unit (301) is configured to organize a handover list based on the adjusted radio communication capacity information about the radio cell. One or more base stations for providing a radio cell for radio transmission and reception to a user unit and a radio resource management unit configured to manage radio resources between the base station and the user unit and to receive radio capacity information about the radio cell; A wireless resource system comprising: a transmission resource management unit for managing transmission network resources and receiving transmission communication capacity information about the transmission network, The transmission resource management unit is configured to determine a transmission communication capacity limit for a radio cell based on the transmission communication capacity information and to signal the transmission communication capacity limit to a base station, whereby the base station limits the transmission communication capacity limit. Adjust the wireless capacity information based on the signal and signal the adjusted wireless capacity information to the radio resource management unit so that the radio resource management unit uses the signaled adjusted radio capacity information to determine the radio resource of the wireless network. A transmission resource management unit, characterized in that for managing. A radio resource management unit configured to receive radio communication capacity information about a radio cell, the radio resource management unit managing radio resources between a base station and a user unit within a radio network in a radio system, The radio resource management unit is configured to manage radio resources of the radio network using signaled adjusted radio communication capacity information about the radio cell, The signaled adjusted wireless capacity information is signaled from a base station And the signaled adjusted radio communication capacity information is adjusted based on a transmission communication capacity limit determined based on the transmission communication capacity information about the transmission network of the radio system. A transmission network providing a base station with a connection to a core network of a wireless system; A radio resource management unit, configured to receive radio communication capacity information about the radio cell, the radio resource management unit managing radio resources between the base station and the user unit; A base station of a wireless system for providing a wireless cell for wireless transmission and reception to a user unit in a wireless system, further comprising a transmission resource management unit configured to receive transmission communication capacity information about the transmission network and managing the transmission network resource. To The base station adjusts wireless communication capacity information about the radio cell based on the transmission communication capacity limit determined based on the transmission communication capacity information and signaled from the transmission resource management unit; And signaling the adjusted radio communication capacity information about the radio cell to the radio resource management unit to manage radio resources using the adjusted radio communication capacity information. The method of claim 24, And the base station comprises the radio resource management unit. The method of claim 24, And the base station includes the transmission resource management unit. Provide a user cell with a radio cell for radio transmission and reception: A radio resource management unit (301) configured to receive radio communication capacity information about the radio cell, the radio resource management unit (301) managing radio resources between the base station and a user unit in the radio network (324); A base station, configured to receive transmission communication capacity information about the transmission network 322, comprising a transmission resource management unit 300 for managing transmission network resources, The transmission resource management unit (300) is configured to determine a transmission communication capacity limit for a radio cell based on the transmission communication capacity information; The transmission resource management unit (300) is configured to signal a transmission communication capacity limit for the radio cell to the base station; The base station is configured to adjust radio communication capacity information about the radio cell based on the transmission communication capacity limit; The base station is configured to signal the radio resource management unit (301) to use the adjusted radio communication capacity information about the radio cell for radio resource management; And And the radio resource management unit (301) is configured to manage radio resources of the radio network (324) by using signaled adjusted radio communication capacity information about the radio cell. delete

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