KR100338557B1 - Vocoding method and apparatus for a performance test of a call processor in a mobile Communication system - Google Patents

Abstract

An apparatus and method for implementing a vocoder for measuring the performance of a call processor in a digital mobile communication system include two IAs, each of which has five OAs interfacing, and each OA is equipped with 12 physical vocoders. The total number of physical vocoders mounted on the board is significantly reduced from 1920 to 120. However, in the CCP, 1920 physical vocoder physical addresses are used as they are, and thus, 16 physical vocoder addresses generated in the CCP are routed to one logical address and mapped to one physical vocoder mounted in the OA. That is, by implementing a virtual mocoder processing function through logical mapping without mounting the maximum physical vocoder that can be accommodated for CCP performance measurement, the cost and time for CCP performance measurement can be significantly reduced.

Description

Vocoder implementation and method for measuring performance of call processor in digital mobile communication system and method therefor {Vocoding method and apparatus for a performance test of a call processor in a mobile communication system}

The present invention relates to an apparatus and method for implementing a vocoder for measuring the performance of a call processing processor in a digital mobile communication system. By replacing a plurality of physical vocoder with a logical vocoder to implement a virtual vocoder, a call control processor: The present invention relates to an apparatus and a method for implementing a vocoder for measuring the performance of a call processor in a digital mobile communication system so that a large cost can be saved when measuring the performance of a CCP.

In general, a digital mobile communication system receives a call setup request from a mobile subscriber or a subscriber such as a public switched telephone network (PSTN), and allocates a channel for call setup. After allocating a call to form a call, and provides a mobile communication service.

When an outgoing call, incoming call, or handoff call is generated from a mobile station (MS), a base transceiver station (BTS) transmits a request for processing such a call to a CCP of a base station controller (BSC). do. In response, the CCP of the control station receives the call processing request and performs the call processing.

Since the CDMA mobile communication system operates in real time and provides a real-time service, when a call processing request occurs, the CCP must perform call processing in real time. Therefore, the CCP should always be operated without interruption.

In order to measure the performance or load of the call processing processor, it is necessary to analyze the type and number of messages received by the CCP and the messages transmitted by the CCP.

1 is a block diagram of a control station and a base station for a call processing of a control station in a general digital mobile communication system. The base station 10 receives a call processing request from a mobile station and transmits it to the control station 20. The base station controller 11 (hereinafter referred to as BCP control processor) of the base station 10 controls signal transmission and reception between the mobile station and the base station 10.

The control station 20 controls the base station 10, receives a call processing request from the base station 10, and sets up a call. The CCP 21, the internal network 22, and the TSB 23 (Tran scoding) Selectoe Bank), and the TSB 23 is composed of a plurality of Interface Assembly (hereinafter referred to as IA) 23a and a plurality of Vocoder Assembly (hereinafter referred to as OA) 23b.

The internal network 22 of the control station 20 connects the base station 10 and the control station 20, and connects the TSB 23 and the CCP 21. Then, the CCP 21 of the control station 20 receives the call processing request message from the base station 10 and performs the call processing.

The TSB 23 also allocates channels under the control of the CCP 21 to perform compression of voice data. At this time, the IA 23a of the TSB 23 performs OA 23b status polling and response to requests from the CCP 21 and performs a voice interface with the mobile station.

The OA 23b of the TSB 23 provides a voice channel with the mobile station, performs call processing and handoff, and performs forward and reverse power control.

A general call processing method using the control station 20 and the base station 10 apparatus will be briefly described with reference to FIG. 2.

2 is a view schematically showing a call processing method in a general digital mobile communication system.

First, when a call setup request is sent from the BCP 11 of the base station 10 to the CCP 21 of the control station 20, the CCP 21 sends a channel allocation request to the TSB 23 to set up this call. send. After receiving the channel allocation request, the IA 23a of the TSB 23 allocates one vocoder among the vocoders mounted on the OA 23b, and then transmits a channel assignment response to the CCP 21.

Upon receiving the channel assignment response, the CCP 21 determines that the channel has been allocated, and transmits a response to call establishment to the BCP 11 of the base station 10. At this time, the CCP 21 performs a call processing operation. When the message is received by the CCP 21, a response message is transmitted to the TSB 23 or the BCP 11 of the base station 10 in response to the message. . Accordingly, the CCP 21 corresponds to one-to-one reception and transmission messages.

In order to measure the performance of the CCP 21 in charge of such call processing, a large number of vocoders are required. In order to accommodate the maximum vocoder, the TSB 23 in the control station 20 must be equipped with a plurality of IAs 23a and OA 23b. For example, suppose that there are 1920 accommodating vocoders per control station 20, 12 vocos per one OA 23b, and one IA 23a manages five OAs 23b. The number of OAs 23b is required to be 160, and the number of IAs 23a is required to be 32. That is, the interface between the IA 23a and the OA 23b is expressed by the following equation.

1920 vocoder = 32 IA interface × 5 OA interface

Therefore, when measuring the CCP performance measurement by the implementation of such vocoder, the TSB block, that is, the IA and OA interfaces should be installed as much as the maximum processing capacity and capacity of the CCP. In this case, since a large number of physical interfaces are required, a large number of personnel and cost are required to measure the CCP performance. It would be very difficult to measure the performance of a CCP with a physical maximum vocoder to measure the performance of the CCP, especially in a laboratory.

Accordingly, the present invention has been made to solve the above-described problems according to the prior art, and an object of the present invention is to implement a virtual vocoder by replacing a large number of physical vocoder with a logical vocoder, thereby reducing a large cost when measuring the performance of a CCP. The present invention provides a vocoder implementation for measuring performance of a call processor in a digital mobile communication system.

Another object of the present invention is to provide a vocoder implementation method corresponding to the operation of the vocoder implementation apparatus.

In the digital mobile communication system according to the present invention for achieving the above object, a feature of the vocoder implementation for measuring the performance of the call processor is a vocoder implementation for measuring the performance of the CCP in the digital mobile communication system, the maximum in the CCP Mapping means for mapping a physical address corresponding to an arbitrary number of vocoders to a logical address according to an arbitrary ratio, and only a physical vocoder corresponding to the ratio so that the physical address is mapped to a logical address at an arbitrary ratio. It consists of a plurality of OAs.

In another aspect of the vocoder implementing apparatus according to the present invention, the ratio of physical addresses to logical addresses mapped in the mapping means is 16: 1, and the OA is 1/16 of the maximum number of physical vocoders that can be accommodated in the CCP. Only the corresponding vocoder is mounted.

In addition, the feature of the vocoder implementation method for measuring the performance of the call processor in the digital mobile communication system according to the present invention is OA equipped with only the vocoder corresponding to 1/16 of the maximum number of physical vocoder maximum acceptable in IA and CCP A method of measuring the performance of a CCP by using the OA, the OA report the physical vocoder status to the CCP via the IA to the maximum acceptable vocoder mounted on the CCP; Designating any one vocoder among the maximum acceptable vocoders in the CCP and transmitting a physical address for the designated one vocoder to the OA via the IA; Routing the physical address for the transmitted one vocoder at a ratio of 16: 1 to map it to any one physical vocoder mounted in the OA.

1 is a block diagram showing a block configuration between a control station and a base station for call processing of a control station in a general digital mobile communication system.

2 is a view schematically showing a call processing method in a general digital mobile communication system;

3 is a diagram illustrating an apparatus for implementing a vocoder for measuring performance of a call processor in a digital mobile communication system according to the present invention;

4 is a flowchart illustrating a vocoder implementation method for measuring performance of a call processor in a digital mobile communication system according to the present invention.

<Explanation of symbols for main parts of drawing>

21: call processing processor 22: LCIN

23: TSB 24: interface assembly

25: Vocoder Assembly

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the vocoder implement apparatus and method for measuring the performance of the call processor in the digital mobile communication system according to the present invention will be described in detail.

3 is a diagram illustrating a vocoder implementing apparatus for performance measurement of a call processor in a digital mobile communication system according to the present invention, and includes a plurality of OAs equipped with a CCP 21, an IA 24, and a plurality of vocoders. 25, 25a) and a Local CDMA Interconnection Network (LCIN) 22 which is responsible for the connection between the CCP 21 and the vocoder mounted in the OA 25, 25a. Here, each of IA0 and IA1 24 is connected to manage five OAs 25 and 25a, and 12 vocoders are mounted to each OA, respectively. That is, IA0 is interfaced with five OA0-0A4 25, respectively, and IA1 is also interfaced with five OA0-0A4 25a, respectively. As a result, the number of vocoders mounted on the entire OAs 25 and 25a is 120, and one IA is interfaced with 60 vocoders.

An apparatus for implementing a vocoder for measuring the performance of a call processor in a digital mobile communication system according to the present invention configured as described above should correspond to one vocoder per 16 vocoders. That is, in order to correspond to 1920 physical vocoders with 120 vocoders according to the related art, 16 logical vocoders must be mapped with one physical vocoder.

In order to map 16 logical vocoders into one physical vocoder, 16 divided addresses must be mapped to 16: 1. This is handled in the IA 24 which governs the OAs 25 and 25a on which the vocoder is mounted.

Since the present invention is an invention for measuring the performance of the CCP 21, the call processing of the CCP 21 should not be affected at all. That is, the CCP 21 should be able to be implemented without any change.

To do this, several physical addresses of the CCP 21 need to be mapped to one logical address. The mapping structure is shown in Table 1 below, and the mapping can be divided into IA mapping and OA mapping.

Physical Logical IA IA # 0 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 OA # 1 3 5 7 9 11 13 15 17 19 21 23 25 27 29 31

The vocoders mounted on the OAs 25 and 25a correspond to 1920 logical vocoders to 120 physical vocoders. The mapping map between the IA 24 and the OAs 25 and 25a and the vocoder is shown in Table 2 below. same.

IA number OA number Vocoder Number Vocoder number to be mapped 0 0 0-11 0 10 20 One 12 to 23 1 11 21 ... 1911 2 24-36 2 12 22 ... 1912 3 36 to 47 3 13 23 ... 1913 4 48-59 4 14 24 ... 1914 One 0 60 to 71 5 15 25 ... 1915 One 72-83 6 16 26 ... 1916 2 84-95 7 17 27 ... 1917 3 96-107 8 18 28 ... 1918 4 108-119 9 19 29 ... 1919

That is, five OAs 25 and 25a are connected to IA0 and IA1 24, and 12 vocoders are mounted to one OA. In addition, 12 vocoders are mapped with 192 physical vocoder addresses. As a result, the 16 physical vocoder addresses allocated by the CCP 21 are mapped to one physical vocoder with one logical address to measure the performance of the CCP 21.

Hereinafter, a vocoder implementation method for measuring the performance of a call processor in a digital mobile communication system according to the present invention will be described step by step with reference to FIG. 4.

4 is a flowchart illustrating a method of implementing a vocoder for measuring the performance of a call processor in a digital mobile communication system.

First, the OAs 25 and 25a report the physical vocoder status to the CCP 21 through the IA 24 as being equipped with 1920 vocoder (S101). Accordingly, the CCP 21 recognizes that the 1920 physical vocoders are mounted on the OAs 25 and 25a.

Subsequently, the CCP 21 designates and assigns any one vocoder among the 1920 vocoders (S102). At this time, the CCP 21 uses the physical address as it is before when assigning and assigning one vocoder among the 1920 vocoder.

Subsequently, the physical address of one of the assigned 1920 vocoders is transmitted to the OAs 15 and 25a through the LCIN 22 and the IA 24. Accordingly, the OAs 25 and 25a process a 16: 1 physical address for the transmitted one vocoder and map it to any one physical vocoder (S103).

Subsequently, the OAs 25 and 25a report to the CCP 21 as if it were normal vocoder processing so that the CCP 21 can continue the call processing (S104).

As a result, an apparatus and method for implementing a vocoder for measuring the performance of a call processor in a digital mobile communication system according to the present invention include two IAs 24, and each IA is interfaced with five OAs. It is equipped with two physical vocoder, which significantly reduces the total number of physical vocoder mounted in the OA from the conventional 1920 to 120. However, in the CCP 21, the 1920 vocoder physical addresses are used as they are, and thus, 16 physical vocoder addresses generated by the CCP 21 are routed to one logical address to one physical vocoder mounted in the OA. To map.

An apparatus and method for implementing a vocoder for measuring the performance of a call processor in a digital mobile communication system according to the present invention as described above are provided with two IAs, and each IA is interfaced with five OAs, and each OA has 12 It is equipped with a physical vocoder, which significantly reduces the total number of physical vocoders mounted in the OA from the conventional 1920 to 120. However, in the CCP, 1920 physical vocoder physical addresses are used as they are, and thus, 16 physical vocoder addresses generated in the CCP are routed to one logical address and mapped to one physical vocoder mounted in the OA. That is, by implementing the virtual mocoder processing function through logical mapping without mounting the maximum physical vocoder that can be accommodated for the CCP performance measurement, the cost and time for the CCP performance measurement can be significantly reduced.

Claims (4)

An apparatus for implementing a vocoder for measuring performance of a call processing processor (CCP) in a digital mobile communication system, Mapping means for mapping a physical address corresponding to the maximum number of vocoders maximum acceptable in the CCP to a logical address according to an arbitrary ratio; An apparatus for implementing a vocoder for measuring a performance of a CCP in a digital mobile communication system, comprising a plurality of vocoder assemblies (OA) equipped with only physical vocoder corresponding to the ratio such that the physical address is mapped to a logical address at an arbitrary ratio. . 2. The apparatus of claim 1, wherein the ratio of physical addresses to logical addresses mapped by the mapping means is 16: 1. The method of claim 1 or 2, wherein the OA is equipped with only a vocoder corresponding to 1/16 of the maximum number of physical vocoders that can be accommodated in the CCP. Vocoder implementation. In the method of measuring the performance of the CCP using a vocoder assembly (OA) equipped with only a vocoder corresponding to 1/16 of the maximum number of physical vocoders that can be accommodated in the interface assembly (IA) and the call processing processor (CCP) , The OA reporting a physical vocoder status to the CCP through the IA as being equipped with the maximum acceptable vocoder in the CCP; Designating any one vocoder among the maximum acceptable vocoders in the CCP and transmitting a physical address for the designated one vocoder to the OA via the IA; Vocoder for measuring the performance of the CCP in a digital mobile communication system, comprising routing the physical address of the transmitted vocoder at a ratio of 16: 1 to any one physical vocoder mounted in the OA. Implementation method.