RU2496260C2 - Method, base station controller and base station subsystem for monitoring quality of service - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: while service data is switched, the base station controller (BSC) establishes a first real-time transport protocol (RTP) link and a first real-time transport control protocol (RTCP) link with a base transceiver station (BTS); the BSC determines whether both communication parties are served by the same BTS, and if yes, the BTS directly transfers the service data, otherwise the BSC controls the two BTS which correspond to both communication parties to establish a second RTP link and a second RTCP link between the two BTS and controls the service data to be switched from the first RTP link to the second RTP link; the BSC receives control information relating to the quality of service and generated and transmitted by the BTS and monitors the quality of service according to the control information.

EFFECT: external control of local switching.

10 cl, 6 dwg

Description

FIELD OF TECHNOLOGY

The present invention generally relates to third-party monitoring of local switching of mobile services based on the IP Abis interface and, in particular, to a method, a base station controller and a base station subsystem for monitoring quality of service.

BACKGROUND

The GSM network (Global System for Mobile Communications, a global system of mobile communications) is a communication system that is most widely used in the field of mobile communications. The wireless access network device of this system is usually called the Base Station System (BSS). The BSS system performs the following functions on a GSM network. On the one hand, the BSS system connects to a mobile station (MS, Mobile Station) through a wireless network and transmits and receives wireless signals, and also controls wireless resources. On the other hand, the BSS system connects to the Mobile Switching Center (MSC) or to the MSC server to perform functions such as establishing Communication Connections between MS stations or between the MS station and a user of a fixed network, as well as delivering system and user information .

Figure 1 shows the structural diagram of a typical BSS system, which contains two logical nodes: the base station controller (BSC, Base Station Controller) and the base transceiver station (BTS, Base Transceiver Station). The communication interface between the BSC and the BTS is called the Abis interface and is used to support remote communication between the BSC and the BTS. Typically, the Abis interface supports a digital transmission line with standard pulse code modulation (PCM) and a transmission rate of 2.048 Mbps or 64 Kbps, which carries voice or service data channels.

Recently, when introducing soft switching technology into the core network, the architecture of the switching network based on the IP protocol (Internet Protocol) is gradually being formed. At the same time, the Abis interface based on the IP protocol transmission mode has higher transmission efficiency and flexibility compared to the traditional Abis interface based on the PCM transmission line. The IP-based Abis interface is referred to as IP Abis for short. The structure of the BSS system and the external interface based on the IP Abis interface are shown in FIG. 2, with the two sides connected to the IP Abis interface still being the BTS and the BSC.

In the prior art, the switching part in the process of providing voice services or packet data can be implemented in various blocks. In accordance with traditional technology, voice / packet data switching is performed on the CN (Core Network) and voice service is provided by the MSC, while packet data is processed on the SGSN / GGSN (Serving GPRS (General Packet Radio Service) Support Node serving the GPRS support node (general packet radio service) / GGSN (Gateway GPRS Support Node, GPRS support gateway node). Recently, to reduce the delay in servicing and conserving CN resources, a method is proposed for performing local switching in the BSC controller, which consists in the fact that if the core network determines the presence of two user devices that need to communicate with each other in the coverage area of one BSC controller, then this core network informs the BSC controller about the need to transmit local switching information; if a party proposes to perform local switching in the BTS, that is, if both communicating parties are served by the same base station or different base stations of the same BSC, or different base stations of different BSC controllers, a channel for local switching can be established user plane data between two base stations (a service channel for voice / data transmission between two base stations is established), since two base stations can receive an IP address and the port number from each other, and after the channel is established, there is no user plane data (upstream and downstream) between the base station and the BSC controller, and voice / packet data uplink and downlink are transmitted between the two base stations and are completely transparent to the core network , then the core network resources and Abis interface resources can be saved, especially in the transmission medium via the Abis IP interface or satellite transmission, which can effectively reduce the occupied frequency band and increase l quality of service when transmitting voice / packet data.

After the Abis interface becomes completely IP-based, the data of this interface is transmitted via a general purpose network, which results in jitter, delay and packet loss during packet data transfer, which can affect the quality of service QoS (Quality of Service). To effectively evaluate this adverse effect, the BSC needs to monitor the performance of the voice / data service channel in real time. In the traditional switching mode or in the local BSC switching mode, the BSC controller can easily control in real time, for example, if user data is transmitted via the Abis interface using the RTP / RTCP protocol, the BSC controller can control the quality of any user communication line by receiving a message RTCP periodically transmitted by the BTS. However, if local switching is performed in the BTS, and user data is no longer transferred between the BSC and the BTS, then the BSC will not be able to control the quality of the user communication line in real time, and in this case, a technical solution is needed to implement third-party control of local switching.

SUMMARY OF THE INVENTION

According to the present invention, there is provided a method, a base station controller and a base station subsystem for quality of service control, which enable the BSC to perform real-time quality of service control for local switching based on the BTS.

The technical scheme of the present invention is implemented as follows.

The quality of service control method used in the local switching process based on the base transceiver station (BTS) includes:

when switching these services, the installation of the controller of the base station (BSC) of the first communication line of the real-time transport protocol (RTP) and the first communication line of the real-time transmission control protocol (RTCP) between the BSC and the BTS;

determining by the BSC controller whether both interacting parties are served by the same BTS, and, if so, directly redirecting these services to this BTS, otherwise controlling the BSC by two BTSs corresponding to the two interacting parties to establish a second communication line RTP and a second RTCP communication link between two BTS stations and managing service data to be switched from the first RTP communication line to the second RTP communication line for transmission,

receiving by the BSC controller control information related to the quality of service, which is generated and transmitted by the BTS, and monitoring the quality of service in accordance with this control information.

Preferably, the quality of service control information is transmitted by the BTS to the BSC via the first RTCP communication line as an RTCP message.

Preferably, control information related to quality of service is transmitted by the BTS to the BSC as a message.

Preferably, before the step for the BSC to receive control information related to the quality of service that is generated and transmitted by the BTS, the method includes

release by the BSC of the first RTP link and the first RTCP link.

The base station controller (BSC) contains:

a communication link establishing unit configured to establish a first communication link of a real-time transport protocol (RTP) and a first communication line of a real-time transmission control protocol (RTCP) between the BSC and the base transceiver station (BTS) when switching services data;

a determining unit configured to determine whether both interacting parties are served by the same BTS;

a control unit configured to control two BTS stations corresponding to both interacting parties to establish a second RTP communication line and a second RTCP communication line between the two BTS stations and with the ability to control service data to be switched from the first RTP communication line to the second RTP communication line for transmission, in case the determination unit determines that both communicating parties do not belong to the same BTS station, and

a control unit configured to receive control information related to the quality of service, which is generated and transmitted by the BTS, and with the ability to control the quality of service in accordance with this control information.

Preferably, the quality of service control information is transmitted by the BTS to the BSC via the first RTCP communication line as an RTCP message.

Preferably, control information related to quality of service is transmitted by the BTS to the BSC as a message.

Preferably, the base station controller (BSC) comprises a connection release unit configured to release the first RTP communication line and the first RTCP communication line.

The base station subsystem includes a base station controller (BSC) and a base transceiver station (BTS), while the BSC controller contains:

a communication link establishing unit configured to establish a first communication line of a real-time transport protocol (RTP) and a first communication line of a real-time transmission control protocol (RTCP) between the BSC and the BTS when switching these services;

a determining unit configured to determine whether both interacting parties are served by the same BTS;

a control unit configured to control two BTS stations corresponding to both interacting parties to establish a second RTP communication line and a second RTCP communication line between the two BTS stations and with the ability to control service data to be switched from the first RTP communication line to the second RTP communication line for transmission, in case the determination unit determines that both communicating parties do not belong to the same BTS station, and

a control unit configured to receive control information related to the quality of service, which is generated and transmitted by the BTS, and with the ability to control the quality of service in accordance with this control information.

Preferably, said BSC controller comprises:

a connection release unit configured to release the first RTP communication line and the first RTCP communication line.

The technical scheme of the present invention allows to effectively implement the quality of service control carried out by the BSC controller in real time by transmitting control information related to the quality of service by the BTS to the BSC controller, thereby eliminating the disadvantage that the BSC controller is currently unable to control the quality of service in real time during the local switching process based on the BTS station.

BRIEF DESCRIPTION OF THE DRAWINGS

For a clearer description of examples of implementation of the present invention or technical scheme of the prior art, the following briefly describes the drawings illustrating embodiments of the present invention or a description of the prior art. It is obvious that the presented drawings serve only as some examples of the implementation of the present invention, and a specialist can get other examples in accordance with them without performing creative work.

Figure 1 shows a diagram of the structure and interface of a BSS system of the prior art.

Figure 2 shows a diagram of the structure and interface of a BSS system based on the IP Abis interface.

3, in accordance with an embodiment of the present invention, there is shown a flowchart of transmitting quality of service control information to the BSC controller in the form of an RTCP message.

4, in accordance with an embodiment of the present invention, a flowchart of a process for transmitting quality of service related control information to the BSC as a message is shown.

5 is a flowchart of a first example of a quality of service monitoring method in accordance with the present invention.

6 is a flowchart of a second example of a quality of service monitoring method in accordance with the present invention.

PREFERRED EMBODIMENTS OF THE PRESENT INVENTION

The main idea of the present invention is as follows. If a service is provided and a local switching process based on the use of the BTS station is established, and the two communicating parties belong to different BTS stations, the BSC establishes the RTP / RTCP communication channel between the BTS stations for the two communicating parties, and user data is sent directly between BTS stations in the form of an IP / UDP / RTP message, that is, the message is composed of an IP header, a UDP header (User Data Protocol), an RTF header, and an RTP payload. In this case, control information related to the quality of service may be transmitted between the BTS and the BSC as an IP / UDP / RTP message, or the BTS may directly transmit control information related to the quality of service to the BSC periodically as a message. If two interacting parties are served by the same BTS, user data is sent directly by the BTS, and the BSC is not involved in the transmission of user data; however, the transmission of control information related to the quality of service can also be performed in two modes, that is, the BSC establishes the RTCP communication channel via the Abis interface for each of the two interacting parties, and control information related to the quality of service can be transmitted between the BTS station and the BSC controller in the form of an IP / UDP / RTP message, or the BTS can directly periodically transmit control information in the form of a message to the BSC controller.

More specifically, in order for the BSC to be able to monitor quality of service in real time, the present invention proposes two solutions:

first solution: when the service is provided, the BSC establishes the RTP / RTCP communication channel between the BSC and the BTS via the Abis interface for each of the two communicating parties, and if, after establishing the local switching process based on the BTS, the two communicating parties are served by different BTS stations, then the BSC controller establishes the RTP / RTCP communication channel between the BTS stations for the two interacting parties, while holding the established RTP / RTCP communication channel between the BSC controller and the BTS. If during the communication process two interacting parties are served by different BTS stations, then the RTP message is sent between the BTS stations, and the RTCP message is generated by the station and transmitted by the BTS to the BSC; if two interacting parties are served by the same BTS, then the BTS directly sends user data and at the same time generates an RTCP message and transmits it to the BSC. Thus, since the quality of service is monitored by the BSC, the BSC does not need to send the RTCP message to the BTS, but only allocates the Abis interface resources needed to transmit the uplink RTCP messages for the service. Therefore, this solution not only allows local switching of user data, saves the bandwidth of the Abis interface and reduces communication delay, but also allows the BSC controller to implement real-time quality control of service.

The second solution: when providing the service, the BSC establishes the RTP / RTCP communication channel between the BSC and the BTS via the Abis interface for each of the two interacting parties, and if, after the local switching process is established on the basis of the BTS, the two interacting parties are served by different BTS stations, then the BSC controller establishes the RTP / RTCP communication channel between the BTS stations for the two communicating parties, while freeing up the established RTP / RTCP communication channel between the BSC controller and the BTS. If in the process of communication two interacting parties are served by different BTS stations, the RTP / RTCP message is sent between the BTS stations, and at the same time, the BTS station transmits the contents of the received RTCP messages, which must be transmitted to the BSC as a message; if two interacting parties are served by the same BTS, the BTS sends the user data directly and at the same time sends control information related to the quality of service to the BSC.

Below with reference to the drawings, in which examples of the implementation of the present invention are presented, technical schemes of embodiments of the present invention are described clearly and in detail. Obviously, only part of the possible examples are described below. All other examples obtained by a person skilled in the art based on the examples given without performing creative work are within the scope of the present invention.

5 is a flowchart of a first example of a quality of service control method in accordance with the present invention, including the following steps.

In step S501, the BSC sets up the first RTP / RTCP communication line with the BTS.

When switching these services, the BSC establishes the first real-time transport protocol (RTP) communication link / first real-time transmission control protocol (RTCP) communication link between it and the BTS.

In step S502, the BSC determines whether two interacting parties are served by the same BTS, and if so, proceeds to step S503, otherwise, proceeds to step S504.

In step S503, the BTS station directly transmits the service data, after which proceeds to step S505.

In step S504, the BSC controls the two cooperating BTSs to establish a second RTP / RTCP link between them, and then proceeds to step S505.

The BSC controller controls two BTS stations corresponding to both interacting parties to establish a second RTP communication line and a second RTCP communication line between the two BTS stations, and also controls service data to be switched from the first RTP communication line to the second RTP communication line for transmission.

In step S505, the BTS transmits control information related to the quality of service to the BSC through the first RTCP communication line in the form of an RTCP message.

According to the present invention, the control information related to the quality of service includes the number of received messages, the number of received bytes, the number of transmitted messages, the number of transmitted bytes over a certain period of time, delay, phase jitter, etc.

In step S506, the BSC receives the quality of service control information transmitted by the BTS and performs quality control of the service in accordance with this control information.

FIG. 6 is a flowchart of a second example of a quality of service control method in accordance with the present invention, including the following steps.

In step S601, the BSC sets up the first RTP / RTCP link with the BTS.

When switching these services, the BSC establishes the first real-time transport protocol (RTP) communication link / first real-time transmission control protocol (RTCP) communication link between it and the BTS.

In step S602, the BSC determines whether two interacting parties are served by the same BTS, and if so, proceeds to step S603, otherwise, proceeds to step S604.

In step S603, the BTS station directly transmits the service data, and then proceeds to step S605.

In step S604, the BSC controls the two cooperating BTSs to establish a second RTP / RTCP link between them, and then proceeds to step S605.

The BSC controller controls two BTS stations corresponding to both interacting parties to establish a second RTP communication line and a second RTCP communication line between the two BTS stations, and also controls service data to be switched from the first RTP communication line to the second RTP communication line for transmission.

In step S605, the BSC releases the first RTP / RTCP link, and then proceeds to step S606.

In step S606, the BTS transmits control information related to the quality of service to the BSC controller as a message.

Step S606 may also be performed before step S605, that is, the present invention does not specify the order of steps S605 and S606.

In step S607, the BSC receives the quality of service control information transmitted by the BTS and performs quality control of the service in accordance with this control information.

According to the present invention, the control information related to the quality of service includes the number of received messages, the number of received bytes, the number of transmitted messages, the number of transmitted bytes over a certain period of time, delay, phase jitter, etc.

This example differs from the first example in that in the first example, the BTS sends control information related to the quality of service to the BSC through the first RTCP communication line in the form of an RTCP message, while in the second example, the BSC releases the first RTP communication line / RTCP, and quality of service control information is transmitted by the BTS to the BSC as a message.

For a clearer description of the present invention, the technical scheme of the invention is described in more detail below by the example of a voice service.

FIG. 3, in accordance with an embodiment of the present invention, shows a flow diagram of a process for transmitting quality of service control information to the BSC as an RTCP message. It should be noted that figure 3 mainly shows the sides MS1 and BTS1, and since the sides BTS2 and MS2 correspond to the sides MS1 and BTS1, the procedures associated with the sides BTS2 and MS2 are not shown in the drawing for clarity.

Control plane:

S101: one of two interacting parties, for example, a mobile phone (MS1), requests a channel from a BSC.

S102: if resources are available, the BSC distributes the dedicated control channel for the mobile phone, and the mobile phone normally accesses the dedicated control channel allocated by the BSC.

S103: after the mobile phone normally accesses the dedicated control channel allocated by the BSC, the BSC continues to distribute the service channel for the mobile phone, and in the process of activating the channel for the BTS, transmits the IP address and port number of the opposite end of the voice communication line The RTP / RTCP you want to install, with the BTS dynamically activating one RTP voice line and one RTCP communication line according to the IP address and port number of the opposite end.

S104: after successfully activating the RTP / RTCP link and the physical channel, the BTS informs the BSC of the completion of channel activation.

S105: after the mobile phone normally accesses the service channel, the MSC sends a connection message to the mobile phone.

S106: after receiving a connection message from the network side, the mobile phone responds with a confirmation of the connection.

S107: if the BSC detects that local switching can be performed while processing the current call, it transmits a local RTP / RTCP link establishment message to two corresponding BTSs (including BTS1 and BTS2), the message containing the IP address and port number the opposite end to which you want to connect using the BTS.

S108: after receiving the local RTP / RTCP link setup message, the BTS establishes one new RTP link and one new RTCP link in accordance with the IP address and port number of the opposite end transmitted in the message.

S109: after establishing an RTP / RTCP link with the opposite end, the BTS sends a link establishment completion message to the BSC.

S110: after receiving the RTP / RTCP local link establishment completion message from the two BTS stations, the BSC sends the local switching link establishment completion message to the BTS station, and the local switching link establishment is completed.

Service Plane:

S201: before the start of the call, two BTS stations establish, respectively, one RTP / RTCP communication line with the BSC controller, and voice data is still transmitted on the RTP communication line established when the channel was activated, while the RTCP message is periodically transmitted to the BSC controller, and after receiving RTSC messages in real time determine the quality of service and display the result in the background with the BSC.

S202: after receiving the RTP / RTCP link setup message for local switching of the BSC, the BTSs begin the process of establishing a single RTP / RTCP link between them.

S203: after successfully establishing an RTP / RTCP link between two BTSs, uplink and downlink voice data is received simultaneously on the new RTP link and on the original RTP link before receiving the response message of the completion of establishing the local switching link transmitted by the BSC controller, and The RTCP message is forwarded only via the RTCP link between the BSC and the BTS.

S204: after receiving the response message of the completion of the establishment of the local switching communication line transmitted by the BSC, the voice data is completely switched to the new RTP communication line, and from then on, the voice data is transmitted only between two BTS stations, and not through the BSC controller and the MSC center. Since real-time monitoring of the quality of service is performed by the BSC, although the RTCP message is still being sent over the old RTCP communication line, at that moment only the BTS sends the RTCP message to the BSC, and the BSC does not need to send the RTCP message to the BTS. After receiving the RTCP message, the BSC determines the level of quality of service in real time and displays the result in the background.

In this example, the BSC needs to establish two pairs of RTP / RTCP communication lines (in this case, a pair of communication lines includes an RTP communication line and an RTCP communication line) for a user who uses local switching to implement voice services, while one pair of communication lines is established between BTS stations and the BSC controller, and another pair of communication lines is established between the two BTS stations involved in the communication. However, from the previous description it can be concluded that BTS stations use only the RTP communication line between themselves, and the RTCP communication line, although installed, is not used; likewise, the BSC and the BTS use only the RTCP communication link and do not use the RTP communication link. In accordance with the protocol requirements, it is important to allocate a pair of adjacent port numbers (the RTP link uses an even port number, and the RTCP link uses an odd port number that is one more than the RTP link port number) for RTP / RTCP in the process of establishing a link RTP / RTCP, and even if only the RTP communication line is set, the port number adjacent to the RTP port number (greater than the RTP port number by 1) cannot be used by other RTP communication lines, and in this respect, despite the fact that install additional th communication line, in fact, only the port number is stored, and the network bandwidth is not used, since they do not transmit data over the communication line.

The present scheme allows the BSC to monitor the quality of service in real time by holding the Abis RTP / RTCP link and, since the RTCP messages are much smaller than the RTP messages, they will not occupy a large portion of the Abis interface bandwidth.

4, in accordance with an embodiment of the present invention, there is shown a flow diagram of a message transmission of quality of service related control information to the BSC. It should be noted that FIG. 4 mainly shows the sides MS1 and BTS1, and since the sides BTS2 and MS2 correspond to the sides MS1 and BTS1, some of the procedures associated with the sides BTS2 and MS2 are not shown.

Control plane:

S301: one of two interacting parties, for example, a mobile phone (MS1), requests a channel from a BSC.

S302: if resources are available, the BSC distributes a dedicated control channel to the mobile phone.

S303: after the mobile phone normally accesses the dedicated control channel allocated by the BSC, the BSC continues to distribute the service channel for the mobile phone and, in the process of activating the channel for the BTS, transmits the IP address and port number of the opposite end of the RTP voice line / RTCP that you want to install, while the BTS dynamically activates a pair of voice communication lines RTP / RTCP according to the IP address and port number of the opposite end.

S304: after successfully activating the RTP / RTCP communication link and the physical channel, the BTS informs the BSC of the completion of channel activation.

S305: after the mobile phone normally accesses the service channel, the MSC sends one connection message to the mobile phone.

S306: after receiving a connection message from the MSC, the mobile phone responds by sending one connection confirmation.

S307: if the BSC controller detects that local switching can be performed for the pair of parties involved in the call, it transmits a local RTP / RTCP link establishment message to two corresponding BTS stations (including BTS1 and BTS2), the message contains The IP address and port number of the opposite end to which you want to connect using the BTS.

S308: after receiving the local RTP / RTCP link establishment message, the BTS establishes a pair of new RTP / RTCP links in accordance with the IP address and port number of the opposite end transmitted in the message.

S309: after the establishment of the RTP / RTCP link between the BTSs, the BTS transmits to the BSC controller a completion message of the linking establishment.

S310: after receiving the local RTP link completion message from the two BTS stations, the BSC releases the original RTP / RTCP link of the two BTS stations, and this message contains the IP address and port number of the opposite end.

S311: after receiving the RTP / RTCP link release message, the BTS releases the corresponding local RTP / RTCP link according to the IP address and port number of the opposite end contained in the message and transmits a release confirmation message to the BSC.

Service Plane:

S401: before the call starts, two BTS stations establish a pair of RTP / RTCP communication lines with the BSC controller, respectively, and voice data is still transmitted on the RTP communication line established when the channel was activated, while the RTCP message is periodically transmitted to the BSC controller, and after receiving RTCP messages are determined by the BSC to determine the quality of service in real time and display it in the background.

S402: after receiving the RTP / RTCP link establishment message for local switching transmitted by the BSC controller, the two BTS stations begin the process of establishing the pair of RTP / RTCP link lines between them.

S403: after successfully establishing RTP / RTCP communication links between two BTSs, the BSC is waiting for the RSC / RTCP to release the control message about the release of the original RTP / RTCP communication link, and at this point the voice data of the uplink and downlink is received simultaneously on the new RTP communication line and on the original RTP communication lines The RTCP message is also simultaneously transmitted over the new and old RTCP links.

S404: after receiving the RSC / RTCP source line release message sent by the BSC, the voice data is fully switched to the new RTP communication line, the original RTP communication line is released, and from that moment only voice data is transmitted between two BTS stations, and not through the BSC controller and MSC center. At the same time, the RTCP message is fully switched to the new communication line and the original RTCP communication line is released.

S405: two BTS stations periodically transmit control information related to quality of service to the BSC controller, the control information being extracted from an RTCP message transmitted and received by the BTS. After receiving the quality of service related control information transmitted by the BTS, the BSC will record this control information and display it in the background.

The technical scheme of the present invention allows to effectively implement the quality of service control carried out by the BSC controller in real time by transmitting control information related to the quality of service from the BTS to the BSC controller, thereby eliminating the disadvantage that the controller is currently The BSC is not able to monitor the quality of service in real time during the local switching process performed by the BTS.

The present invention also discloses a base station controller (BSC) comprising:

a communication link establishment unit used to establish a first communication link of a real-time transport protocol (RTP) and a first communication link of a real-time transmission control protocol (RTCP) between the BSC and the base transceiver station (BTS) when switching data services;

a determination unit used to determine whether both interacting parties are served by the same BTS;

a control unit used to control two cooperating BTS stations to establish a second RTP communication line and a second RTCP communication line between the two BTS stations and to manage service data to be switched from the first RTP communication line to the second RTP communication line for transmission, in the case if the determination unit determines that both interacting parties do not belong to the same BTS;

a control unit used to receive control information related to the quality of service, which is generated and transmitted by the BTS, and control the quality of service in accordance with this control information.

In this case, the control information related to the quality of service is transmitted by the BTS to the BSC through the first RTCP communication line in the form of an RTCP message.

According to another example of the present invention, the base station controller (BSC) also comprises:

a link release unit used to release the first RTP link and the first RTCP link.

At the same time, control information related to the quality of service is transmitted by the BTS to the BSC controller in the form of a message.

The present invention also discloses a base station subsystem including a base station controller (BSC) and a base transceiver station (BTS), wherein the BSC controller comprises:

a communication link establishment unit used to establish a first communication link of a real-time transport protocol (RTP) and a first communication link of a real-time transmission control protocol (RTCP) between the BSC and the BTS when switching these services;

a determination unit used to determine whether both interacting parties are served by the same BTS;

a control unit used to control two cooperating BTS stations to establish a second RTP communication line and a second RTCP communication line between the two BTS stations and to manage service data to be switched from the first RTP communication line to the second RTP communication line for transmission, in the case if the determination unit determines that both interacting parties do not belong to the same BTS;

a control unit used to receive control information related to the quality of service, which is generated and transmitted by the BTS; and QoS in accordance with this management information.

In this case, the control information related to the quality of service is transmitted by the BTS to the BSC through the first RTCP communication line in the form of an RTCP message.

In another example, a base station subsystem according to the present invention, the BSC also includes:

a link release unit used to release the first RTP link and the first RTCP link.

At the same time, control information related to the quality of service is transmitted by the BTS to the BSC controller in the form of a message.

The process and principles of operation of the BSC controller and the base station subsystem were described in detail in the section containing examples of the method, therefore, they are not described below to reduce the amount of text, and refer to the corresponding section of the description of examples of the method for familiarization with them.

One skilled in the art will appreciate that all steps or part of the steps for implementing the above examples of the method can be performed by controlling the appropriate hardware using the program, and that the program can be stored on a computer-readable storage medium, and when the program is executed, the steps are implemented as described above in the examples of the method. As a storage medium, a disk, an optical disk, read-only memory (ROM, Read-Only Memory) or random access memory (RAM, Random Access Memory), etc. can be used. In various examples of the method disclosed in the present invention, the sequence number of each step is not intended to specify the order in which the steps are taken, and a specialist to change the order of steps without performing creative work is also within the scope of the present invention.

The above are only preferred embodiments of the present invention, which are not intended to limit the present invention, and any modifications, equivalent replacements and improvements made within the spirit and principles of the present invention are included in the scope of the present invention.

Industrial applicability

The technical scheme of the present invention allows to effectively implement the quality of service control carried out by the BSC controller in real time by transmitting control information related to the quality of service from the BTS to the BSC controller, thereby eliminating the disadvantage that the controller is currently The BSC is not able to monitor the quality of service in real time during the local switching process performed by the BTS.

Claims (10)

1. The method of monitoring the quality of service used in the process of local switching based on the base transceiver station (BTS), including:
when switching these services, the controller setting the base station (BSC) of the first communication line of the real-time transport protocol (RTP) and the first communication line of the real-time transmission control protocol (RTCP) between the base station controller and the base transceiver station;
determining by the controller of the base station whether both interacting parties are served by the same base transceiver station, and, if so, directly redirecting these services to the base transceiver station, otherwise control the base station controller with two base transceiver stations corresponding to the two interacting parties, to establish a second RTP communication line and a second RTCP communication line between two base transceiver stations and managing data services, p by switching from the first RTP communication line to the second RTP communication line for transmission,
reception by the controller of the base station of control information related to the quality of service, which is generated and transmitted by the base transceiver station, and quality control of service in accordance with this control information. 2. The method according to claim 1, characterized in that the control information related to the quality of service is transmitted by the base transceiver station to the base station controller via the first RTCP communication line in the form of an RTCP message. 3. The method according to claim 1, characterized in that the control information related to the quality of service is transmitted by the base transceiver station to the base station controller in the form of a message. 4. The method according to claim 3, also including, before the step, the controller receives the base station control information related to the quality of service, which is generated and transmitted by the base transceiver station,
release by the base station controller of the first RTP communication line and the first RTCP communication line. 5. A base station controller comprising:
a communication line establishing unit configured to establish a first communication line of a real-time transport protocol (RTP) and a first communication line of a real-time transmission control protocol (RTCP) between the base station controller and the base transceiver station when switching these services;
a determining unit, configured to determine whether both interacting parties are served by the same base transceiver station;
a control unit configured to control two base transceiver stations corresponding to both cooperating parties to establish a second RTP communication line and a second RTCP communication line between the two base transceiver stations and to control service data to be switched from the first RTP communication line to the second line RTP communications for transmission, if the determination unit determines that both communicating parties do not belong to the same base transceiver station, and
a control unit configured to receive control information related to the quality of service, which is generated and transmitted by the base transceiver station, and with the ability to control the quality of service in accordance with this control information. 6. The base station controller according to claim 5, characterized in that the control information related to the quality of service is transmitted by the base transceiver station to the base station controller via the first RTCP communication line in the form of an RTCP message. 7. The base station controller according to claim 5, characterized in that the control information related to the quality of service is transmitted by the base transceiver station to the base station controller in the form of a message. 8. The base station controller of claim 7, comprising a connection release unit configured to release the first RTP communication line and the first RTCP communication line. 9. A base station subsystem including a base station controller and a base transceiver station, wherein the base station controller comprises:
a communication line establishing unit configured to establish a first communication line of a real-time transport protocol (RTP) and a first communication line of a real-time transmission control protocol (RTCP) between the base station controller and the base transceiver station when switching these services;
a determining unit, configured to determine whether both interacting parties are served by the same base transceiver station;
a control unit configured to control two base transceiver stations corresponding to both cooperating parties to establish a second RTP communication line and a second RTCP communication line between the two base transceiver stations and to control service data to be switched from the first RTP communication line to the second line RTP communications for transmission, if the determination unit determines that both communicating parties do not belong to the same base transceiver station, and
a control unit configured to receive control information related to the quality of service, which is generated and transmitted by the base transceiver station, and with the ability to control the quality of service in accordance with this control information. 10. The base station subsystem according to claim 9, characterized in that the base station controller comprises:
a connection release unit configured to release the first RTP communication line and the first RTCP communication line.

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