KR20140028708A - Apparatus and method for controlling voice quality based on overload of networks and an user terminal therefor - Google Patents

Abstract

In voice quality control based on an overload according to the present invention, a success rate of a VoLTE voice call is increased and a system load is reduced by adaptively controlling voice quality according to a network state by relatively lowering the quality of a voice call which is serviced to a corresponding mobile terminal if the mobile terminal is located in the overload base station; after it is checked whether a base station with the mobile terminal to request the VoLTE voice call is an overload base station by receiving overload base station list information from a base station load managing apparatus which manages the overload information according to the base station. [Reference numerals] (500) Base station load managing apparatus; (AA) Call; (S18) Load managing by base station; (S32) Set to speech quality SD

Description

Overload-based voice quality control device, mobile terminal and method {APPARATUS AND METHOD FOR CONTROLLING VOICE QUALITY BASED ON OVERLOAD OF NETWORKS AND AN USER TERMINAL THEREFOR}

The present invention relates to voice over LTE (VoLTE) call processing, and in particular, receiving a base station list information from which an overload occurs from a base station load management device managing overload information for each base station, and a mobile terminal requesting a VoLTE voice call is located. After checking whether the base station is a base station in an overloaded state, if the mobile terminal is located in an overloaded base station, the quality of the voice call to the mobile terminal is set relatively low, such as adaptively depending on the network conditions The present invention relates to an overload-based voice quality control device, a mobile terminal, and a method for increasing the success rate of VoLTE voice calls and reducing the system load by allowing voice quality to be adjusted.

3rd Generation Partnership Project (3GPP) mobile communication systems based on Wideband Code Division Multiple Access (WCDMA) radio access technology are widely deployed around the world. HSDPA (High Speed Downlink Packet Access), which can be defined as the first evolutionary phase of WCDMA, provides 3GPP mobile communication system with highly competitive wireless access technology in the mid-term future.

However, as the requirements and expectations of users and operators continue to increase and competition for developing wireless access technologies continues, there is a need to evolve new technologies in 3GPP mobile communication systems in order to gain competitiveness in the future. Reduced cost per bit, increased service availability, the use of flexible frequency bands, simple structure and open interface, and adequate power consumption of the terminal are demanding requirements. In addition, prevention of unnecessary latency at the network node and efficient use of network resources can also promote the technology evolution in 3GPP.

In 3GPP Release 8, a Network Architecture called Evolved Packet Core (EPC) is described as one of mobile communication systems for meeting the above-mentioned requirements. EPC is a set of network nodes for 3GPP LTE (Long Term Evolution) system. The EPC evolves the core network of the existing 3GPP system architecture to support Evolved-UMTS Terrestrial Radio Access Network (E-UTRAN), which is an evolved RAN, And has an efficient network structure that simplifies the network node.

On the other hand, as described above, EPC or LTE, the fourth generation mobile communication, must implement IMS-based VOIP technology to provide voice service, which is the basis of mobile communication service, as a data-only network. The proposed service is called VoLTE (Voice over LTE) service.

The VoLTE voice and video service is a multimedia service that uses a packet bearer on an Evolved Universal Terrestrial Radio Access Network (E-UTRAN) in an LTE / EPC network, and a mobile terminal accesses an LTE / EPC network attaches and updates the subscriber location and status information through the subscriber information authentication step, receives a session setup and a bearer allocation for the multimedia service, and receives a QoS (Quality of Service) level acceptable to the subscriber A multimedia service is provided according to the service.

At this time, in performing the VoLTE voice and video service as described above, the service may be provided with various voice qualities according to the performance of the mobile terminal and the state of the network. That is, for example, a mobile terminal may support various codecs such as 12.65kbps and 23.85kbps in a VoLTE voice call, and is generally set to receive the highest quality service.

However, if the base station where the mobile terminal is located is overloaded according to the network condition, it is necessary to adjust the quality of service received from the mobile terminal in order to increase the success rate of the VoLTE service and to reduce the load of the system. Accordingly, there is no system solution or technology for adaptively adjusting the voice quality of the mobile terminal.

(Patent Literature)

Korean Patent Laid-Open No. 10-2009-0118871 Published Nov. 18, 2009 discloses a method and apparatus for providing a voice call service in a mobile communication system and a technology related to the system.

Accordingly, the present invention receives base station list information from which an overload occurs from a base station load management device managing overload information for each base station, and determines whether the base station in which the mobile station requesting the VoLTE voice call is located is an overloaded base station. After that, if the mobile station is located in an overloaded base station, the quality of the voice call serviced by the mobile terminal is set relatively low, such that the voice quality can be adaptively adjusted according to the network conditions, thereby making the VoLTE voice call a success rate. To provide an overload-based voice quality control device, a mobile terminal and a method to increase the system load and lower the system load.

The present invention described above is an overload-based voice quality control apparatus, comprising: a call processing unit configured to perform a call processing by setting a session to a corresponding mobile terminal when a call request is received from a mobile terminal, and an overload of a base station where the mobile terminal is located when performing the call processing. And a base station information acquisition unit for acquiring information, and a voice quality management unit for changing the voice quality of the mobile terminal according to the overload information when establishing a session with the mobile terminal when the base station in which the mobile terminal is located is overloaded.

The voice quality management unit may control to change the voice quality of the mobile terminal to a relatively low voice quality according to the overload information.

The base station information obtaining unit may receive overload information of the base station from a PCRF on a communication network.

In addition, the overload information of the base station is characterized in that it is included in the AAA (Diameter AA-Answer) message transmitted from the PCRF.

In addition, the overload information of the base station is characterized in that periodically collected from the base station load management device on the communication network and provided to the PCRF.

In addition, as a mobile terminal, the communication unit for transmitting the location information for call connection to the call processing server on the communication network, and receives the overload information of the base station corresponding to the location information from the call processing server, and the call by the call processing server When the voice call with the connected mobile terminal is connected, the codec unit performs a signal processing on the voice signal with a preset voice quality, and controls the codec unit according to the overload information of the base station so that the voice quality is relatively higher than the preset voice quality. And a control unit for changing to low quality.

The control unit may control to perform the call connection with the changed voice quality when a new call connection request is made after the call is terminated.

In addition, as an overload-based voice quality control method, performing a call processing by setting a session to a corresponding mobile terminal when receiving a call request from a mobile terminal, and obtaining overload information of a base station where the mobile terminal is located when performing the call processing. And if the base station where the mobile terminal is located is overloaded, controlling the voice quality of the mobile terminal to be changed according to the overload information when establishing a session with the mobile terminal.

The controlling may include controlling the voice quality of the mobile terminal to be changed to a relatively low voice quality according to the overload information.

The controlling may include adaptively changing and setting the voice quality of the mobile terminal according to the overload when establishing a session with the mobile terminal when the base station where the mobile terminal is located is overloaded.

The present invention also provides an overload-based voice quality control method, comprising: transmitting location information for a call connection to a call processing server on a communication network and receiving overload information of a base station corresponding to the location information from the call processing server; And changing the voice quality of the call to a quality relatively lower than a preset voice quality according to the overload information of the base station.

In addition, in the changing, after the end of the call, the voice quality is changed when a new call connection request is made.

According to the present invention, in the overload-based voice quality control, a base station in which an overload occurs is received from a base station load management device managing overload information for each base station. After checking whether the mobile station is located in the base station under an overload condition, the quality of the voice call serviced by the mobile terminal is set relatively low. By doing so, it is possible to increase the success rate of VoLTE voice calls and to reduce the system load.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram of a heterogeneous mobile communication hybrid service system including a heterogeneous mobile communication hybrid call processing apparatus to which an embodiment of the present invention is applied;
2 is a schematic block diagram of a P-CSCF according to an embodiment of the present invention;
3 is a detailed block diagram of a mobile terminal to which an embodiment of the present invention is applied;
4 is a signal processing flowchart for overload-based adaptive voice quality control according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail the operating principle of the present invention. In the following description of the present invention, when it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intentions or customs of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

FIG. 1 is a configuration diagram of a heterogeneous mobile communication hybrid service system including a heterogeneous mobile communication hybrid call processing apparatus to which an embodiment of the present invention can be applied. FIG. 1 illustrates a case where a WCDMA mobile communication system 100 operates as a legacy network. The WCDMA mobile communication system 100 includes a LTE (Long Term Evolution) mobile communication system 200, But the present invention is not limited to this. For example, other asynchronous mobile communication systems such as GSM (Global System for Mobile) or other synchronous mobile communication systems such as CDMA2000 and the like may be used together with the LTE mobile communication system 200, An example will be described.

The WCDMA mobile communication system 100 includes a Node B 110, an RNC 120, a Mobile Switching Center / Visitor Location Register (MSC / VLR) 130, a CGS 140, (Serving General Packet Radio Service Support Node) 150 and a Gateway General Packet Radio Service Support Node (GGSN) 160.

The Node B 110 and the RNC 120 correspond to a radio access network area and the MSC / VLR 130 and the CGS 140 correspond to a circuit exchange core network. The SGSN 150 and the GGSN 160 exchange packets. Corresponds to the core network.

The NodeB 110 is composed of a plurality of cells, and a plurality of terminal devices can be connected to the cells. The NodeB 110, which is an aggregate of these cells, secures the frequency used for connection with the terminal devices and ensures a stable connection with the terminal devices.

The RNC 120 controls a plurality of NodeBs 110, allocates communication resources to each of the NodeBs 110, and handles functions such as handover.

The MSC / VLR 130 stores visitor location information, receives subscriber profile information, authentication and location related data from the HLR 410, and performs switching control for voice communication.

The CGS 140 serves as a gateway for connecting the WCDMA mobile communication system 100 to the general communication network, and enables communication with other communication systems connected to the general communication network. For example, the CGS 140 serves as a gateway between the circuit network 420 and the MSC / VLR 130 and is connected to the LTE mobile communication system 200 through the IMS 300 connected to the circuit network 420, Thereby enabling circuit communication between the systems 100. This CGS 140 may also be referred to as a GMSC (Gateway MSC) or a gateway exchange.

The SGSN 150 and the GGSN 160 belonging to the packet-switched core network area are connected to an IP network 430 such as the Internet, that is, a packet data network (PDN), to receive a packet- IP-based protocol interworking for matching with

To this end, the SGSN 150 is connected to several RNCs 120 to manage mobility and packet session management of the mobile terminal, establish a PDP context with the GGSN 160, and use protocol data using tunneling. It performs the function of delivering the unit. In addition, SGSN 160 may perform IP routing, and may interact with location registration of the mobile terminal.

The GGSN 160 directly connects to the IP network 430 and acts as a gateway for connecting the IP network 430 and the packet switched (PS) domain of the WCDMA mobile communication system 100. The SGSN 150, And maintains routing information with the external network, and performs tunneling and IP routing functions.

The LTE mobile communication system 200 includes an eNodeB 210, an MME 220, an S-GW 230, a PDN GW 240, and a Policy & Charging Rule Function (PCRF)

The eNodeB 210 is a device that supports next generation technologies and services such as LTE, and functions as radio frequency (RF) transmission of transmission signals, measurement of signal strength and quality of transmission and reception, baseband signal processing, and channel card resource management . The eNodeB 210 ensures a stable connection with a plurality of terminal devices.

The MME 220 manages mobility of a terminal device, and is responsible for session management, idle subscriber management, paging, and subscriber authentication functions. That is, the MME 220 performs control such as processing a control signal when there is a binding request from the terminal device or another network node, for example, from the PDN GW 240 or the S-GW 230, And receives the subscriber profile information, authentication and location-related data from the HLR 410, and controls the setting of an EPS bearer or an IP tunnel, mobility management, and the like Function.

The S-GW 230 is a user plane node that performs session control for processing payload traffic according to a set session. The S-GW 230 interfaces with the eNodeB 210 through an S1-U interface, (Handover) in the communication system 200 and the 3GPP, establishes an ESP bearer (Evolved Packet System bearer) with the PDN GW 240, and delivers PDU (Packet Data Unit) using tunneling.

The PDN GW 240 is a user plane node that assigns an IP address of a terminal device and performs session control in cooperation with an external Internet network and a non-3GPP network. The PDN GW 240 is a user plane node that provides S- And has tunneling and IP routing functions. And delivers the PDU to the S-GW 230 and the external network.

The Smart eNodeB Overload Warning System (SNOW) 500 is a device that manages state information of base station equipment existing in a communication network. The usage rate of base station equipment such as NodeB, eNodeB, etc. It determines whether the base station is overloaded by measuring, manages information on the base station in the overloaded state, and periodically provides the list of base stations in such an overloaded state to the PCRF 250.

The PCRF 250 provides dynamic QoS and billing rules according to the service data flow to perform communication policies and billing processing in the communication network.

In addition, the PCRF 250 receives the overloaded base station list information from the base station load management apparatus 500 according to the overload information-based adaptive VoLTE voice quality adjustment operation according to an embodiment of the present invention, and receives the base station cell information. If the location of the mobile terminal 60 having an effective session by managing the overload for each ID is located in the base station in the overloaded state, the session of the mobile terminal 60 is managed.

The IP Multimedia Subsystem (IMS) 300 includes a Call Session Control Function (CSCF) 310, an Inter-working Media Gateway (IMG) 320, and a Home Location Register (HLR)

CSCF 310 is an infrastructure system that performs call processing and performs basic functions for multimedia session control based on SIP (Session Initiation Protocol). The CSCF 310 handles subscriber registration, authentication, billing, triggering and routing per service, caller location lookup, compression and decompression of SIP messages, and P-CSCF (Proxy_CSCF) 312, I-CSCF ( Interogating-CSCF) and S-CSCF (Serving-CSCF).

The P-CSCF 312 transfers the SIP register message received from the mobile terminal 60 to the I-CSCF with reference to the home domain of the mobile terminal, and the S- obtained from the SIP register processing of the I-CSCF. Manage CSCF addresses. Later, the P-CSCF 312 forwards the SIP call request message received from the mobile terminal 60 to the S-CSCF by referring to the S-CSCF address obtained through the SIP register procedure.

In addition, the P-CSCF 312 is the PCRF 250 in the call processing according to the VoLTE voice call request of the mobile terminal 60 according to the adjustment operation of the adaptive VoLTE voice quality based on the overload information according to an embodiment of the present invention. Receiving information on the overload state of the base station where the mobile terminal 60 is located from the base station where the mobile terminal 60 is located, that is, the information on the base station overload state to the mobile terminal 60 when the eNodeB 210 is overloaded Can be set to control the VoLTE voice quality to a relatively low quality.

In addition, as another control method of voice quality, when the mobile terminal 60 is located in the base station in an overloaded state when a voice call call is connected between the mobile terminals 60, the mobile terminal ( The voice quality of the mobile terminal 60 may be controlled by intervening in the P-CSCF 312 at the time of generating a session for connecting the VoLTE voice calls between the 60 and the low quality voice quality.

That is, when the mobile terminal 60 is located in an overloaded base station, the P-CSCF 312 may perform voice in the opposite mobile terminal when generating a session for call connection between the mobile terminal 60 and the opposite mobile terminal. By manipulating the quality information, the voice quality set between mobile terminals can be controlled to be set to a relatively low voice quality that can cope with overload. For example, even if there are multiple levels of voice quality that can be supported by the other party's mobile terminal, such as HD level or SD level, the mobile device that requested the call as supporting the other party's mobile terminal only supports a relatively low level of voice quality. By providing to the terminal 60, it is possible to control so that the voice quality set between mobile terminals is set to a relatively low voice quality when generating a session for call connection.

The IMG 320 converts signaling and media for interworking with the LTE mobile communication system 200 connected to the CSCF 310 and the WCDMA mobile communication system 100 connected to the circuit network 420.

The HLR 330 is a network node including a data base including subscriber information for a wireless communication system for the WCDMA mobile communication system 100 and / or the LTE mobile communication system 200, Information, authentication, and location-related data.

In the embodiment of FIG. 1, the WCDMA mobile communication system 100 and the LTE mobile communication system 200 operate the HLR 410 in an integrated manner, and the IMS 300 operates the HLR 330 independently , The WCDMA mobile communication system 100 or the LTE mobile communication system 200 may also operate the HLRs independently. In addition, the WCDMA mobile communication system 100, the LTE mobile communication system 200, and the IMS 300 may operate one HLR in an integrated manner.

2 is a schematic block diagram of a P-CSCF 312 according to an embodiment of the present invention. Hereinafter, the operation of each component of the P-CSCF 312 will be described in detail with reference to FIG. 2.

First, the network connection unit 602 interfaces the transmission and reception data between the PDN-GW 240, the PCRF 250, and the P-CSCF 312 in the EPC network.

When the call processing unit 600 receives a call request from the mobile terminal 60, the call processing unit 600 performs a call processing by establishing a session with the mobile terminal 60 in association with an S-CSCF (not shown) in the CSCF 310. do.

The base station information acquisition unit 608 obtains overload information of the base station where the mobile terminal 60 is located, that is, for example, the eNodeB 210, from the PCRF 250 when performing call processing.

That is, the PCRF 250 manages the base station load in the AAA (Diameter AA-Answer) message transmitted to the P-CSCF 312 in response to a dedicated bearer request for the VoLTE session during the call processing for the mobile terminal 60. The mobile terminal 60 provided from the apparatus 500 transmits the information including the overload information of the located base station, and the base station information acquisition unit 608 extracts the base station overload information from the AAA message.

When the base station where the mobile terminal 60 is located is overloaded, the voice quality manager 610 transmits overload information of the base station to the mobile terminal 60 so that the voice quality of the mobile terminal 60 may be adaptively changed according to the overload. To help.

That is, the voice quality management unit 610 refers to the mobile terminal 60 by referring to the overload information of the base station where the mobile terminal 60 is received from the PCRF 250 when processing a call according to the VoLTE voice call request of the mobile terminal 60. When the base station located, i.e., the eNodeB 210 is in an overloaded state, the mobile station 60 may provide information about the overloaded base station state so that the VoLTE voice quality is set to a relatively low quality.

In addition, as another method of voice quality control, the voice quality management unit 610 is overloaded when the mobile terminal 60 is located in an overloaded base station when the voice call is connected using the VoLTE between the mobile terminals 60. In consideration of the above, when a session for connecting VoLTE voice calls between mobile terminals 60 is generated, relatively low quality voice quality is set by directly intervening without providing base station overload information to the mobile station 60. As a result, the voice quality of the mobile terminal 60 can be controlled.

That is, when the mobile terminal 60 is located in an overloaded base station, the voice quality manager 610 may perform a voice that can be performed by the mobile terminal 60 when the session for the call connection between the mobile terminal 60 and the mobile terminal 60 is generated. By manipulating the quality information, the voice quality set between mobile terminals can be controlled to be set to a relatively low voice quality that can cope with overload. For example, even if there are multiple levels of voice quality that can be supported by the other party's mobile terminal, such as HD level or SD level, the mobile device that requested the call as supporting the other party's mobile terminal only supports a relatively low level of voice quality. By providing to the terminal 60, it is possible to control so that the voice quality set between mobile terminals is set to a relatively low voice quality when generating a session for call connection.

The memory unit 604 stores a program for operating the P-CSCF 312. The control unit 606 is the P-CSCF 312 of the network connection unit 602, the call processing unit 600, the base station information acquisition unit 608, the voice quality management unit 610 according to the program stored in the memory unit 604 Control overall operation.

3 shows a detailed block diagram of a mobile terminal 60 capable of adaptive voice quality adjustment based on overload information according to an embodiment of the present invention. Hereinafter, an operation in each block of a mobile terminal that performs adaptive voice quality control based on the overload information will be described in detail with reference to FIG. 3.

First, the key input unit 300 may be composed of a plurality of numeric keys and function keys for various operation requests of the mobile terminal 60, and generates a corresponding key data when the user presses a predetermined key control unit 306 Will output The key input unit 300 as described above has a difference in character arrangement by manufacturer and country. In addition, the key input unit 300 may be displayed on the display unit 304 in a touch screen format whenever necessary by a software method instead of a physical keypad in a smart phone, a tablet PC, or the like. have.

The communication unit 308 transmits location information for call connection to a PCRF or the like on a communication network such as an LTE network or a WCDMA network, and receives overload information of a base station corresponding to the location information from a call processing server such as a P-CSCF 312. do.

The audio unit 310 modulates the voice signal input through the microphone MIC into a wireless signal under the control of the control unit 306, and demodulates the received wireless signal and transmits it to the speaker SPK as a voice signal. In addition, the audio unit 310 may further include a codec unit for processing a voice signal with various voice qualities set by the controller 306 during a voice call.

The key input unit 300 is implemented as a keypad or a touch screen, and generates key data according to a user's input on the keypad or touch screen and outputs the key data to the controller 306.

The display unit 304 displays various information of the mobile terminal 60 under the control of the controller 306, and receives and displays key data generated by the key input unit 300 and various information signals of the controller 306.

The controller 306 controls the overall operation of the mobile terminal 60 according to the operation program stored in the memory unit 302. The operation program as described above connects the display unit 304 and the key input unit 300 as well as the basic operating system required for the operation of the mobile terminal 60, manages input / output of data, or executes the mobile terminal ( It refers to software that is preprogrammed at the time of manufacture to run the internal application of the device.

In addition, in order to control the adaptive VoLTE voice quality based on the overload information according to the embodiment of the present invention, the codec unit is controlled according to the overload information of the base station to change the voice quality to a relatively lower quality than the preset voice quality.

That is, the control unit 306, for example, the codec unit supports two kinds of codecs, such as 12.65kbps, 23.85kbps, for the VoLTE voice call, and also changes the wireless bandwidth to 32kbps or 43.2kbps according to each codec. If possible, when the mobile terminal is located in a base station that is not overloaded, the HD codec of 23.85kbps is controlled to be set.In the case of being located in an overloaded base station, the SD codec of 12.65kbps having a relatively low voice quality is set. It is possible to adjust VoLTE voice quality adaptively based on the overload information, for example, by controlling to be changed and set.

4 illustrates a signal processing flow for adaptive voice quality control based on overload information in a mobile communication network according to an embodiment of the present invention.

First, the base station load management apparatus 500 determines the overload state of the base station by measuring the utilization rate of the base station equipment such as NodeB (110), eNodeB (210), the base station equipment managed in the communication network, the base station information in the overloaded state It is provided to the PCRF 250 (Location Load Notify [info]) (S10). At this time, the base station load management apparatus 500 may provide the base station list (list) that is determined to be overloaded state to the PCRF 250 in a predetermined period.

Then, the PCRF 250 receives the base station list information in an overloaded state and transmits a response (Location Load ACK) for acknowledgment to the base station load management apparatus 500 (S12).

On the other hand, when the mobile terminal 60 is activated from the preservation state, the PDN-GW 240 sends the location information of the mobile terminal 60 through a CCR (Credit Control Request) -U message. In step S14, the PCRF 250 transmits a response to the reception of the CCR-U message to the PDN-GW 250 (S16).

In this case, the CCR-U message includes Cell ID information of the base station in which the mobile terminal 60 is located. Accordingly, the PCRF 250 may identify the base station in which the mobile terminal 60 is located and the base station load management apparatus 500. Referring to the base station list information of the overloaded state provided from the) to determine whether the mobile terminal 60 reporting the location information is located in the base station of the overloaded state.

That is, the PCRF 250 manages an overload for each cell ID of the base station, and when the location of the mobile terminal 60 having a valid session is located in the overloaded base station, Management is performed on the session (S18).

Subsequently, when there is a request for a VoLTE service, for example, by a user using the mobile terminal 60, the SIP requesting the creation of a session for a voice call from the mobile terminal 60 according to a request of, for example, a VoLTE voice call. The INVITE message may be transmitted to the P-CSCF 312 (S20).

Then, the P-CSCF 312 receives a session progress message according to the SIP INVITE message from the S-CSCF (not shown), and after receiving the session progress message, sends a diameter AA-Request (AAR) message to the PCRF 250. (S22).

As described above, when receiving the AAR message from the P-CSCF 312, the PCRF 250 determines the QoS, transmits a Re-Auth-Request (RAR) message to the PDN-GW 240, and responds with the RAA. Receive a (Re-Auth-Answer) message (S24), set a PCC (Policy and Charging Control) rule to be applied to the requested call from the mobile terminal 60, the diameter AAA (Aiameter AA-Answer) ) Message is transmitted to the P-CSCF 312 (S26).

Accordingly, a voice call may be performed between the mobile terminals 60 through, for example, a VoLTE service, and when the call is terminated, a SIP [BYE] message for releasing a session is transmitted from the mobile terminal 60 (S28). , P-CSCF 312 transmits 200 OK in response to SIP [BYE] and releases the session (S30).

Meanwhile, in the present invention, the PCRF 250 checks whether the corresponding mobile terminal 60 is located in the overloaded base station by referring to the base station list information in the overloaded state, and then the base station in which the mobile terminal 60 is located is overloaded. In the above case, the base station in which the mobile station 60 is located is overloaded at the time of transmitting the AAA message in response to the dedicated bearer request for the VoLTE session from the P-CSCF 312 as described above (S26). ).

Then, the P-CSCF 312 informs that the mobile terminal 60 is currently located in the overloaded base station at the time when the SIP 200 OK message is transmitted to the mobile terminal 60 according to the termination of the voice call of the mobile terminal 60. By transmitting (S30) together so that the voice quality set in the mobile terminal can be changed from SD to SD, which is a relatively low quality.

Accordingly, the mobile terminal 60 refers to the overload state information of the base station received from the P-CSCF 312 and subsequently performs the voice quality of the mobile terminal 60 when the voice call is requested using VoLTE. It can be changed to a relatively low quality (S32) to be able to perform a VoLTE voice call in a stable manner.

That is, for example, two types of codecs used in a VoLTE voice call in the mobile terminal 60 are 12.65kbps and 23.85kbps, and the wireless bandwidth may be changed to 32kbps or 43.2kbps according to each codec. have. Therefore, the mobile terminal 60 uses an HD codec of 23.85kbps when it is located at a base station that is not overloaded, and changes to an SD codec of 12.65kbps which is relatively low in voice quality when it is located at an overloaded base station. For example, the VoLTE voice quality can be adaptively adjusted based on the overload information.

In this case, the mobile terminal 60, which has received the overload information of the base station, has been described as an example to adaptively adjust the voice quality, but such control may be performed by the P-CSCF 312.

That is, when the mobile terminal 60 is located in the base station in the overloaded state when the voice call is connected using the VoLTE in the P-CSCF 312, the voice set between the mobile terminals 60 in consideration of the overloaded state of the base station. The voice quality of the mobile terminal 60 may be controlled by creating a session by setting the quality to a relatively low quality.

As described above, in the present invention, in the overload-based voice quality control, the mobile station for receiving a VoLTE voice call is provided by receiving the base station list information from which the overload occurs from the base station load management device managing the overload information for each base station. After checking whether the base station is a base station in an overloaded state, if the mobile terminal is located in an overloaded base station, the quality of the voice call to the mobile terminal is set relatively low, such as adaptively depending on the network conditions Voice quality can be adjusted to increase the success rate of VoLTE voice calls and to reduce system load.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention. Accordingly, the scope of the invention should not be limited by the described embodiments but should be defined by the appended claims.

In the present invention, in the overload-based voice quality control, the base station where the overload occurs is received from the base station load management device managing the overload information for each base station, and the base station where the mobile terminal requesting the VoLTE voice call is located in an overload state. After checking whether the mobile station is located in the base station under an overload condition, the quality of the voice call serviced by the mobile terminal is set relatively low. In order to increase the success rate of the VoLTE voice call and to reduce the system load, it can be applied to the EPC network.

600: call processing unit 602: network connection unit
604: Memory 606: Control
608: base station information acquisition unit 610: voice quality management unit

Claims (11)

A call processing unit for performing call processing by setting a session with a corresponding mobile terminal when receiving a call request from the mobile terminal;
A base station information acquisition unit for acquiring overload information of a base station where the mobile terminal is located when performing the call processing;
The voice quality management unit changes the voice quality of the mobile terminal according to the overload information when establishing a session with the mobile terminal when the base station where the mobile terminal is located is overloaded.
Overload-based voice quality control device comprising a. The method of claim 1,
The voice quality management unit,
Overload-based voice quality control device, characterized in that for controlling to change the voice quality of the mobile terminal to a relatively low voice quality according to the overload information. The method of claim 1,
The base station information acquisition unit,
An overload-based voice quality control apparatus for receiving overload information of the base station from a communication network PCRF. The method of claim 3, wherein
Overload information of the base station,
Overload-based voice quality control device, characterized in that included in the AAA (Diameter AA-Answer) message transmitted from the PCRF. The method of claim 3, wherein
Overload information of the base station,
Overload-based voice quality control device that is periodically collected from the base station load management device on the communication network provided to the PCRF. A communication unit transmitting location information for call connection to a call processing server on a communication network, and receiving overload information of a base station corresponding to the location information from the call processing server;
A codec unit for performing a signal processing on a voice signal with a preset voice quality during a voice call with a mobile terminal connected to the call by the call processing server;
A controller for controlling the codec unit according to the overload information of the base station to change the voice quality to a relatively lower quality than the preset voice quality
A mobile terminal comprising a. The method according to claim 6,
The control unit,
And after the call ends, controlling to perform the call connection with the changed voice quality when a new call connection request is made. When the call request is received from the mobile terminal, establishing a session with the corresponding mobile terminal to perform call processing;
Acquiring overload information of a base station in which the mobile terminal is located when performing the call processing;
If the base station where the mobile terminal is located is overloaded, controlling the voice quality of the mobile terminal to be changed according to the overload information when establishing a session with the mobile terminal;
Overload-based voice quality control method comprising a. The method of claim 8,
Wherein the controlling comprises:
Overload-based voice quality control method characterized in that the control to change the voice quality of the mobile terminal to a relatively low voice quality according to the overload information. Transmitting location information for a call connection to a call processing server on a communication network;
Receiving overload information of a base station corresponding to the location information from the call processing server;
Changing the voice quality of the call to a relatively lower quality than a preset voice quality according to the overload information of the base station
Overload-based voice quality control method comprising a. 11. The method of claim 10,
In the changing step,
Overload-based voice quality control method, characterized in that the voice quality is changed when a new call connection request is made after the call is terminated.

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