KR100266869B1 - Implementation of Adaptive Layer for Multiprotocol Support in Personal Mobile Communication System - Google Patents

Abstract

PURPOSE: A method for implementing an adaptive layer for a multi-protocol support in a PCS(Personal Communication System) is provided to handle an HDLC(High level Data Control) transparent mode and a signaling system No.7 mode supplied in an MK5027 chip, so as to supply a function of a multi-protocol layer2. CONSTITUTION: An adaptive layer between a protocol layer3 and a layer2 discriminates a NO.7 standard of layer3 packet and a layer3 packet using an HDLC(High level Data Control) frame, to transfer control to each layer2 implementation unit. The NO.7 layer2 initializes the interface between the layer3 and layer2, and initializes an MK5027. The layer3 and the layer2 perform communication using a defined primitive. A signal unit received to the layer2 is re-formatted appropriately for a protocol standard using the MK5027. And the re-formatted data are transmitted to each destination.

Description

Implementation of Adaptive Layer for Multiprotocol Support in Personal Mobile Communication System

The present invention relates to a PCS system, and more particularly, to a method for implementing an adaptive layer for multi-protocol layer 2 function between PCX-BSCs.

Looking at the prior art as follows. 1 is a diagram illustrating a data transmission procedure using MK5027 according to the related art.

The software module is responsible for the layer 2 function and the interface with layer 3 of NO.7 signaling between the base station controller (PCS) and the personal communication eXchange (PCX) of the personal communication system (PCS). do.

The function of the NO.7 layer 2 is performed using MK5027 (SGS-Thompson Signaling System # 7 Signaling Link Controller). The MK5027 reads user data received from Layer 3 in a TX buffer and matches a Layer 2 header (BSN: Backward Sequence Number, FSN: Forward Sequence) according to the NO.7 Layer 2 packet format. Export the data to a sub-highway by attaching a Number, Open / Close Flag, or FCS, and remove the NO.7 layer 2 header from the data coming from the sub-highway. After reformatting to the Protocol Signal Unit, it writes to the RX buffer and sends it to Layer 3.

In this case, since the MK5027 chip is set only to the signaling system 7 (NO.7) mode, the protocol using a frame of a format other than the NO.7 layer 2 packet is used. There is a problem that it is difficult to perform layer 2 processing.

The present invention was devised to solve the above problems of the prior art, and the high level data control (HDLC) transparent mode provided in the MK5027 chip to overcome the limitation that only the NO.7 layer 2 signal processing is performed. Multi-Protocol Layer 2 in personal mobile communication systems by implementing an adaptive layer that can handle both Transparent Mode and Signaling System 7 (NO.7) mode It aims to provide) function.

Other objects and advantages of the present invention will become more apparent from the following detailed description of the invention and the accompanying drawings.

1 is a data transmission procedure using MK5027 according to the prior art.

2 is an interface and data transmission procedure between layer 3 and layer 2 including an adaptive layer according to the present invention.

3 is a protocol layer procedure including the adaptive layer according to the present invention.

In order to achieve the above object, according to the present invention, a preferred embodiment of the adaptive layer implementation method for multi-protocol support includes: handing over control to the layer 2 implementation by the adaptive layer; Initializing the layer 2; Communicating between layer 3 -layer 2; Reformatting the signal unit received in the layer 2; And sending it to each destination after the reformatting.

In the present invention, since the processing of the address field and the control field in the HDLC frame is not supported in the MK5027 chip, it is preferable to allow the MK5027 to perform flag and FCS processing through the layer 2 implementation supporting the corresponding processor. Preferably, the adaptive layer transfers control to the layer 2 implementation by discriminating whether it is a layer 3 and a layer 3 using an HDLC frame through a promise identifier. It is preferable to perform chip initialization in accordance with the mode, the packet after the layer 2 initialization is initialized by the adaptive layer is transmitted to the layer 2, the NO.7 layer 2 interface with the layer 3 It is preferable to set a part and initialize the reception buffer and the transmission buffer. Subsequently, it is preferable to set the mode register of MK5027 to SS7 mode, and the NO.7 layer 2 is to drive the chip in SS7 mode by giving a PON primitive with MK5027, and to the NO.7 layer 2 Incoming NO.7 TX user data is preferably stored in a transmission buffer, and the MK5027 reads the data of the transmission buffer, attaches a NO.7 layer 2 header to the data, and transmits the data to a large station. For the RX data received in the 7th layer 2, the MK5027 preferably removes the header of the layer 2, and preferably records the data in a reception buffer so that the MK5027 can be transmitted to the NO.7 layer 3, and the HDLC layer 2 It is preferable to set the interface unit with the HDLC layer 3 and initialize the receive buffer and the transmit buffer, and the HDLC layer 2 is the mode register of the MK5027. Is set to the HDLC transparent mode, and the HDLC layer 2 gives the MK5027 a TRANS primitive to drive the chip in the HDLC mode, and the data received by the HDLC layer 2 is an HDLC layer. After receiving the address field and the sequence number of the large station through the implementation unit, it is preferable to perform FCS and flag processing by the MK5027 and then transmit it to the destination.

Hereinafter, a detailed operation principle of the present invention will be described with reference to the drawings. FIG. 2 is an interface and data transmission procedure between layer 3 and layer 2 including an adaptive layer according to the present invention, and FIG. 3 is a protocol layer structure including an adaptive layer according to the present invention.

The adaptive layer between the protocol layer 3 and the layer 2 distinguishes the layer 3 packet using the NO.7 standard from the layer 3 packet using the HDLC frame and transfers control to each layer 2 implementation.

In the NO.7 layer 2, after initializing the interface between the layer 3 and the layer 2 and initializing the MI5027 chip, the layer 3 and the layer 2 communicate with each other using a defined primitive. The received signal unit is reformatted according to the protocol specification using the MK5027 chip.

After reformatting, the data is transmitted to each destination.

In the case of the HDLC frame, since the processing for the address field control field is not supported by the MK5027 chip, the MK5027 is flagged through the layer 2 implementation supporting the process. ) And FCS (Frame Check Sequence) processing.

The adaptive layer distinguishes between NO.7 layer 3 and layer 3 using an HDLC frame through an identifier identified from the layer 3, and passes control to a corresponding layer 2 implementation. Each layer 2 implementation unit performs chip initialization according to a corresponding mode, and the packet after the layer 2 initialization is transmitted to layer 2 initialized by the adaptive layer.

The NO.7 layer 2 sets up an interface unit with the layer 3 and initializes a receive buffer and a transmit buffer. The mode register of the MK5027 is set to SS7 mode, and the chip is driven in SS7 mode by giving a power on (PON) primitive to the MK5027.

The NO.7 TX user data entering the NO.7 layer 2 is recorded in the transmission buffer, and the MK5027 reads the data from the transmission buffer, attaches the NO.7 layer 2 header, and transmits the data to the power station. The RX data received in the NO.7 layer 2 is recorded in the reception buffer so that the MK5027 can remove the layer 2 header and be transmitted to the layer 3.

The HDLC layer 2 sets an interface unit with the layer 3 and initializes a reception buffer and a transmission buffer. The mode register of the MK5027 is set to the HDLC transparent mode and the MK5027 is given a TRANS (Transparent) primitive to drive the chip in the HDLC mode.

The data received by the HDLC layer 2 is given an address (address field) and a sequence number (control field) of the power station through the HDLC layer 2 implementation unit, and then received by FCS and flag processing by the MK5027 implementation unit. Is sent to

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are only shown in detail in the foregoing detailed description and shown in the following drawings. It is to be understood, however, that the present invention is not limited to the specific forms referred to in the specification, but rather that the invention is intended to cover all modifications, equivalents, and substitutions within the spirit and scope of the invention as defined by the appended claims. It should be understood to include.

According to the present invention configured as described above, by implementing an adaptive layer between the layer 3 and the layer 2 in the interface between the BCS-PCX, it is possible to process not only the NO.7 layer 2 signal but also the HDLC frame.

Claims (16)

The adaptive layer transferring control to the layer 2 implementation; Initializing the layer 2; Communicating between layer 3 -layer 2; Reformatting the signal unit received in the layer 2; And sending the reformatting to each destination after the reformatting. The method of claim 1, wherein the processing of the address field and the control field in the case of an HDLC frame is not supported in the MK5027 chip, thereby allowing the MK5027 to perform flag and FCS processing through the layer 2 implementation supporting the corresponding processor. How to implement an adaptive layer for protocol support. The multi-protocol support according to claim 1, wherein the adaptive layer distinguishes between NO.7 layer 3 and layer 3 using an HDLC frame by using a layer 3 and a promise identifier. How to implement adaptive layer for The method of claim 1, wherein each layer 2 implementation unit performs chip initialization according to a corresponding mode. The method of claim 1, wherein the packet after the layer 2 initialization is initialized by the adaptive layer and transmitted to the layer 2. The method of claim 1, wherein the NO. 7 sets an interface unit with the layer 3 and initializes a reception buffer and a transmission buffer. The method of claim 1, wherein the mode register of the MK5027 is set to SS7 mode. The method of claim 1, wherein the MK5027 is given a PON primitive to drive the chip in SS7 mode. The method of claim 1, wherein the NO.7 TX user data entering the layer 2 is stored in a transmission buffer. The method of claim 1, wherein the MK5027 reads the data in the transmission buffer and attaches a NO.7 Layer 2 header to the data to the power station. The method of claim 1, wherein the MX5027 receives the RX data received by the layer 2, and the MK5027 removes the header of the layer 2. The method of claim 1, wherein the data is written to a receive buffer to be transmitted to the layer 3. 3. The method of claim 2, wherein the HDLC layer 2 sets up an interface unit with the layer 3 and initializes a receive buffer and a transmit buffer. 4. The method of claim 1 or 2, wherein the mode register of the MK5027 is set to the HDLC transparent mode. The method of claim 1 or 2, wherein the MK5027 is given a TRANS primitive to drive the chip in the HDLC mode. The data received by the layer 2 is transmitted to the destination after the FCS, flag processing by the MK5027 after receiving the address field and the sequence number of the power through the HDLC layer 2 implementation unit; How to Implement an Adaptive Layer to Support Multiple Protocols.

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