KR0152390B1 - Mobile telecommunication system - Google Patents

Abstract

The present invention relates to a path configuration of a multiplexed relay line between a control station and a base station in a mobile communication system and a method of controlling the same. An interconnection network between a control station and a base station configured through a multiplexed relay line controls a plurality of nodes and bridge nodes. A relay network linking a control unit and a base station includes a relay network matching a station network and a base station network, a control station side relay line matching device, a base station side relay line matching device, a control station side relay line matching device and a base station side relay line matching device. In addition to enabling the message path selection, the message transmitted through one relay line link is distributed to multiple links, and is composed of multiple relay lines, thereby frequently transmitting the transmission opportunities for message transmission between the control station and the base station. Reduce latency and reduce message path over the trunk line link. By the normal path for the kids manage the path to enable the message transmission and minimize lost messages.

Description

Multiplexed Relay Line Path Construction and Control Method between Control Station and Base Station in Mobile Communication System

1 is a diagram illustrating an interconnection network between a control station and a base station in a mobile communication system to which the present invention is applied.

2 is a block diagram of a multiple relay line link between a control station and a base station according to the present invention.

3 is a block diagram of a node address characteristic register according to the present invention;

4 is a block diagram of a node characteristic register according to the present invention.

5 is a block diagram of a mask address register according to the present invention.

6 is a configuration diagram of a control station bridge node address and a mask address according to an embodiment of the present invention.

7 is a configuration diagram of a base station bridge node address and a mask address according to an embodiment of the present invention.

8 is an example diagram of node addresses and mask addresses of a control station and a base station bridge node according to an embodiment of the present invention.

9 is alternative path selectivity according to relay line message path failure.

* Explanation of symbols for main parts of the drawings

100: control station 101 ~ 101: control station interconnection network

103 ~ 105: unit communication network 106 ~ 111: base station

112 ~ 117: Relay line link 253: Control station unit communication network

254,256 base station communication network 200 control station side network manager

245,246: Base station side network manager

201 ~ 204: Control station side message path control node

237 ~ 244: Base station side message path control node 205 ~ 212: Control station bridge node

229 ~ 236: base station bridge node

213 ~ 220: Relay line matching device on the control station side

221 ~ 228: Base station side relay line matching device 248,251: Relay line

The present invention relates to a multiplexed relay line configuration between a control station and a base station in a mobile communication system and a method of controlling the same. In particular, a plurality of messages transmitted between a control station and a base station of a mobile communication system are properly distributed through a multiplexed relay line link. The present invention relates to a path configuration of a multiplexed relay line between a control station and a base station in a mobile communication system in which a message can be transmitted through a normal relay line link when a path failure occurs through the relay line.

In general, an interconnection network between a control station and a base station for transmitting and receiving message frames between a control station and a base station in a mobile communication system is performed by a round robin bus arbitration method.

The conventional interconnection structure between the control station and the base station using the round robin bus arbitration method is a bus structure, in which each node rotates in order to transmit message data.

That is, the transmission of the message frame between the control station and the base station is made through one relay line between the control station and the base station. For example, a plurality of nodes in the control station may send a message to a plurality of nodes in the base station. When a message is transmitted to one node providing a message path because the base station transmits the message, the message is transmitted to the base station at a relay line link speed relatively lower than the transmission speed on the bus.

At this time, if the amount of messages transmitted to the base station is not large, there is no delay of the message. However, if the amount of messages transmitted to the base station is large, messages are accumulated in a transmission queue transmitted to the base station, causing a delay in transmission.

In addition, a message received at a control station node through a relay line link from a base station must be transmitted on a bus to be transmitted to a corresponding node inside the control station, where the message transmission on the bus is performed by a round robin transmission. Is sent on the bus and the next message can only be sent once it has been sent to another node.

Therefore, a message queue delay occurs due to waiting for the bus use opportunity, and this message queue delay is not suitable for a system requiring real time voice traffic data transmission.

In addition, due to the delay of the message queue, the transmission time of the message was significantly delayed, and when a failure of the transmission path of the message occurred according to the relay line structure consisting of only one link, it was difficult to reconfigure the normal path that can be replaced. As a result, many messages were lost.

An object of the present invention for solving the above problems is to construct a multiplexed relay line link between a control station and a base station of a mobile communication system and to delay message transmission between a control station and a base station in a mobile communication system through the multiplexed relay line link. The present invention provides a path configuration of a multiplexed relay line and a method for manufacturing the multiplexed relay line in a mobile communication system capable of efficiently performing path control and management of the multiplexed relay line for traffic load balancing.

A feature of the present invention for achieving the above object is that the interconnection network between the control station and the base station is a control station unit network consisting of a plurality of nodes and bridge nodes having a message exchange function, a plurality of nodes having a message exchange function and A base station unit network comprising a bridge node, a multiplexed control station side relay line matching device connected to a bridge node of the control station unit network, a multiplexed base station side relay line matching device connected to a bridge node of a unit network of the base station, and And a relay line for matching the control station side relay line matching device and the base station side relay line matching device.

An additional feature of the present invention is a bridge node according to a structure of a node address of the node for path control of a message and a node property address for distinguishing a property of each node, and a mask address for performing path control and management of a relay line. It is possible to determine the path of the message to properly distribute the message to a plurality of relay lines, and to reconfigure the path for a failed link among the plurality of relay lines.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention;

1 is a diagram illustrating an interconnection network configuration between a control station and a base station in a mobile communication system to which the present invention is applied. The mobile communication system includes a plurality of base stations 106 to 111 according to the capacity of the control station 100 and the mobile subscriber station. The control station 100 of the interconnection network interconnects the unit networks 103 to 105 with the unit networks 103 to 105 to enable efficient configuration of the expansion and contraction of the system according to the capacity. It consists of interconnection network (101-102).

In addition, between the control station interconnection network and the base station interconnection network are interconnected by relay line links 112-117 to efficiently support telecommunications.

FIG. 2 is a block diagram illustrating the configuration of peripheral functional blocks for path control around a multiplexed relay line link between a control station and a base station in the interconnection network between the control station and the base station of FIG. The main components comprise the base station unit communication networks 254 and 255, the control station side relay line matching devices 213 to 220, and the base station side relay line matching devices 221 to 228.

Between the control station side relay line matching devices 213 to 220 and the base station side relay line matching devices 221 to 228 are connected by relay lines 248 and 251 for a relay function.

The control station unit communication network 253 is connected to the network manager 200 for managing the control station interconnection unit network, the node 201 to 204 having a message exchange function, and the control station side connected to the control station call control device and the traffic processing device. It consists of bridge nodes 205-212.

The base station unit communication networks 254 and 256 are network managers 245 and 246 for managing base station interconnection unit networks, nodes 237 to 244 connected to call control units and traffic processing units of base station interconnection networks, and have a message exchange function. It consists of bridge nodes 229-236.

The control station side relay line matching devices 213 to 220 are connected to the bridge nodes 205 to 212 of the control station unit communication network 253 and have a matching function with the relay lines 248 and 251, and the base station side relay line matching device ( 221 to 228 are connected to the bridge nodes 229 to 236 of the base station unit network 254 and 255 and have a matching function with the relay lines 248 and 251.

The bridge nodes 205 to 208, 229 to 232, 209, 212, 233 to 226 and the relay line matching devices 213 to 216, 221 to 224, 217 to 220, 225 to 228 are configured as serial unit links 247, 249, 250 and 252 that provide a message path for transmission of serial messages.

The network managers 200, 245, and 246 perform initialization, state management, and fault management functions of unit network nodes, have various control functions for a plurality of nodes, and in particular, have a path function for a bridge node.

The relay line matching devices 213 to 228 convert a EIA-422 serial HDLC message from a bridge node into transmission data of a relay line or convert the relay line transmission data into an EIA-422 serial message.

3 is a diagram illustrating a register configuration corresponding to the configuration of a node address register according to the present invention, that is, a two-byte destination address scheme of a node for message path control. The node address corresponding to two bytes from bits 15 to 0 is shown in FIG. Bits 15, 14, 13, and 12 (301) of 300 indicate a bit group for division of the control station unit network of FIG. 1, and bits 11 to 8 302 belong to one control station unit network subordinate. Represents a bit group of flags for identifying the base station unit network.

Bit 7 303 is a flag indicating whether or not it is a bridge node. When the value is set to 1, bit 7 303 corresponds to a bridge node.

Bit 6 to bit 0 304 indicate a bit group for distinguishing each node belonging to the unit network, and when used as a bridge node, it is used as a control region for path selection.

4 shows a register of a node characteristic address for distinguishing characteristics of each node according to the present invention. When the value of the characteristic register is 00 in hexadecimal, each node is compared with the current node address of the destination address of the message frame. The message frame is accepted only if the bits have the same value.

In addition, when the value of the characteristic register is 04 of 16, it operates in conjunction with the mask address register.

FIG. 5 shows the configuration of a mask address register according to the present invention, which is valid only when the property register value of FIG. 4 is 04 in hexadecimal, and includes a message frame and each node for a bit set to 1 in the mask address register. When comparing with the unique address, the comparison of the corresponding bit means to ignore.

At this time, the value of the mask address register is received from the network manager.

In the present invention, the relay line path control and management is performed using the characteristics of the mask address register.

Next, a method for path control and management of a relay line of a network flasher for each case will be described based on the multiplexed relay link configuration between the control station and the base station described above, and registers of respective nodes related to message path control. .

Each node shown in FIG. 2 latches each register to a node address and node characteristic value fixed in hardware after an initialization reset.

At this time, the mask address latches the initial value to zero.

The control station and the base station network manager exchange information with each node to analyze the node characteristic address value, and then the analyzed node characteristic address value is set to 1 in bit 7 303 of FIG. If the value of bit 6 to bit 2 of the bit 6 to bit 0 (304) area is all set to 1, it is recognized as a bridge node connected to the relay line matching device.

At this time, as shown in FIG. 2, when the number of relay lines connected to one base station is 4T1 or 4E1, the bridge node address and mask address of the control station are shown in FIG.

That is, bits 15 to 12 (601) are areas representing the corresponding unit networks in the control station, and bits 11 to 8 (602) are areas representing the unit networks of the base station connected to the control station. 1111, each representing a base station unit network.

Bit 7 603 must be set to 1, bit 6 to bit 2 604 can come in any value, but for convenience, set to 1, and bit 1 and bit 0 605 are set according to the message frame. It has four values of 00,01,10,11 to enable route selection to the relay line.

In addition, the mask address associated with the reception of the message frame of the bridge node should be the same as the corresponding bit of the bridge node address in order to transmit a message frame from the control station to the base station located below the control station. The mask bits are not set, whereas bits 7 through 2 (603, 604) represent the characteristics of the bridge node and therefore set the mask bits regardless of the path selection.

That is, bit 1 and bit 0 are related to the path selection and thus receive a frame matching two bit values compared to the message frame.

The control station bridge node mask address indicating the above mask condition is the same as 606 in FIG.

On the other hand, Figure 7 shows the configuration of the base station bridge node address and mask address connected to the upper control station, bit 15 ~ bit 12 (701) shows the corresponding unit network of the upper control station to which the base station belongs, bit 11 Bit 8 702 has a value of 0000 in bits indicating to receive a message destined for the control station.

Bit 7 703 must be set to 1, and bits 6 to 2 704 can come in any value, but are set to 1 for convenience.

Bits 1 and 0 (705) have four values of 00,01,10,11 to enable path selection to four relay lines according to the message frame from the base station to the control station.

The mask address associated with the reception of the message frame of the bridge node should be compared with the message frame destined for the control station from the base station to the message destined for the control station of bits 11 to 8 (702). Because bit 1 and bit 0 for link selection must be compared, reset to 0.

The remaining bits are independent of the path decision, so set them to 1 so that they do not correlate to the corresponding bits in the message frame.

The base station bridge node mask address indicating the above mask condition is the same as 706 of FIG.

Determining the path of a message that can load-balance the appropriate message to multiple relay lines using the bridge node with the above address characteristics, reconfiguring the path to the path control function of the network manager and the failed link among the multiple relay lines The method is as follows.

After each node reset, the node reads its node address and node characteristic values from the outside and latches them in the registers shown in Figs.

At this time, the fixed external address for the control node and the base station for the bridge node should be the value described in Figs. 6 and 7 and the characteristic value should be fixed to the mask mode value.

After the latch operation of the register is completed, the network manager exchanges information on the node address and the characteristic value with all nodes in the unit network, and when the bridge flag bit is set to 1 and the characteristic value has the mask mode value, the network manager For the station bridge node, the mask address value shown in 606 of FIG. 6 is transmitted to the node and latched in the register. For the base station bridge node, the mask address value shown in 706 of FIG. 7 is transmitted and latched in the register.

For example, in FIG. 3, the value of the unit network division bit group 301 of the control unit network 253 of FIG. 2 is 0, and the values of the bek area 302 of the base station network 254, 256 are 1 and respectively. 1111, and when the bit regions 304 of the nodes 201, 201, 203, and 204 of FIG. The addresses of the bridge nodes 229, 230, 231, 232, 233, 234, 235, and 236 may be represented by base station bridge node addresses 809, 810, 811, 812, 813, 814, 815, 816 of FIG.

Next, the transmission flow of the message through the path of the selected message on the multiplexed relay line will be described. A frame destined for the 237 node of the base station among the 201, 202, 203, and 204 nodes of the control station is the base station group 602 of the control station bridge node address of FIG. ) Is 0001 and bit 1 and bit 0 605 are 0 and 0 respectively, and the path is composed of _205_213_221_229_237.

In the same way, the path to the 238 node with 605 bits 0 and 1 is _206_214_222_230_238, the path to the 239 node with 605 bits 1 and 0 is _207_215_223_231_239, and the path to the 240 node with 605 bits 1 and 1 is _208_216_224_232_240 Is done.

Further, the frame directed to node 241 is the control station bridge node of FIG. 7 and is received as a node in which the base station group 702 of the address is 1111 and bit 1 and bit 0 705 are 0 and 0, respectively, and the path is _209_217_225_233_241. do.

In the same way, the path to the 242 node with 705 bits 0 and 1 is _210_218_226_234_242, the path to the 243 node with 705 bits 1 and 0 is _211_219_227_235_243, and the path to 244 latitude with 705 bits 1 and 1 is _212_220_228_236_244 It becomes

Conversely, when a frame is transmitted from a base station node, such as 237,238,239,240, to a 201 node of a control station, it is transmitted through a 299 bridge node, a 230 bridge node as a 202 node, a 231 bridge node as a 203 node, and a 232 bridge node as a 204 node. The frame is transmitted.

When a frame is transmitted from a base station node such as 241,242,243,244 to a 201 node of a control station, it is transmitted through a 232 bridge node, a 202 node is a 234 bridge node, a 203 node is a 235 bridge node, and a 204 node is a 236 bridge node. The frame is sent.

Lastly, as a method for reconstructing a path in the event of a failure of a message path on a relay line, the following description will be given.

If a transmission failure occurs on any bridge node and relay line link during normal frame path selection, the network manager excludes the corresponding bridge node of the failed link from the serviceable target and changes the initial mask address to another bridge node. Allow the frame to be sent.

If a failure occurs in the path 205_213_221_229, the network manager 200 of the corresponding control station and the network manager 245 of the base station set bit 1 of the node mask address of FIG. 6 to 1 to obtain a frame that 205 or 229 should receive. Either 207 or 231 is received, or bit 0 of the node mask address is set to 1 to allow 205 or 229 to receive the frame 206 or 230 should receive.

The values of bits 1 and 0 of the replaceable link to the values of bits 1 and 0 of the node address of the bridge node which failed in this way are shown in FIG. 9.

In FIG. 9, 901 indicates an alternate link and mask value when one link path fails, and 902 indicates a failure when two link paths fail, and 903 indicates that the three link paths fail. Shows the link and mask values.

As described above, the present invention enables not only the message path selection of the multiplexed relay line link between the control station and the base station of the mobile communication system, but also the distribution of messages transmitted through one relay line link to multiple links, and round-robin. In the interconnection network using the bus arbitration method, the queue delay time that can occur when one relay line is used between the control station and the base station for message transmission is composed of several relay lines for message transmission between the control station and the base station. Frequent transmission opportunities reduce transmission delay time and minimize message loss by managing the path to allow the message to travel in the normal path to failures in the message path through the trunk line link.

Claims (10)

A mobile communication system consisting of a control station consisting of a unit communication network and an interconnection network interconnecting the unit networks and enabling message distribution and a plurality of base stations according to the capacity of a mobile subscriber station, the control station interconnecting unit network managing A control station unit communication network connected to the network manager, the control station call control device, and the traffic processing device, the node having a message exchange function and a control node side bridge node; A base station unit communication network comprising a network manager for managing a base station interconnection unit network, a node having a message exchange function and a node having a message exchange function connected to a call control device and a traffic processing unit of the base station interconnection network; A control station side relay line matching device connected to the bridge node of the control unit network; A base station side relay line matching device connected to a bridge node of the base station unit network; And a relay line for matching the control station side relay line matching device and the base station side relay line matching device. The method of claim 1, wherein the node address for determining a unique address of the node providing a path for exchanging messages, the node property address of a predetermined size for determining a property for path control of each node, and the value of the property register are determined. Mobile communication characterized in that the control of the path of the message to properly distribute the message to a plurality of relay lines using a bridge node according to the structure of the mask address of a predetermined size operating in conjunction with the node address register in the mask mode A path control method of a multiplexed relay line between a control station and a base station in a system. 2. The mobile station of claim 1, wherein the control unit is configured with a serial unit link providing a message path for transmission of serial messages between the bridge node of the control unit network and the relay line matching device. How to configure path of multiplexed relay line. 2. The multiplexing between a control station and a base station in a mobile communication system according to claim 1, characterized in that it consists of a serial unit link providing a message path for transmission of serial messages between a bridge node of the base station unit network and a relay line matching device. To configure the route of a routed relay. The control station of claim 1, wherein the relay line matching device converts the serial message from the bridge node into transmission data of the relay line, and converts the relay line transmission data into a serial message. Path construction method of multiplexed relay line between base stations. 3. The node address as claimed in claim 1 or 2, wherein the node address of the node involved in determining the path of the message comprises: a predetermined number of bit groups for distinguishing the control station unit network; A predetermined number of bit groups for identifying base station unit networks belonging to one control station unit network; Multiplexing between a control station and a base station in a mobile communication system comprising a register consisting of a bit group of a flag indicating whether the node is a bridge node or a predetermined number of bit groups for distinguishing each node belonging to a unit network Path configuration and control method thereof. The control station and the base station in the mobile communication system according to claim 1, wherein the node is used as a bridge node when the bit group indicating whether the node of the node is a bridge node is determined as a bridge node. Path construction of multiplexed trunk lines and control method thereof. 3. The mask address of claim 2, wherein the mask address excludes a bit group indicating a control station and a base station to which a message frame is transmitted with respect to the bit group of the bridge node address of claim 7, and a bit group indicating a path for transmitting the message. A path configuration of a multiplexed relay line between a control station and a base station in a mobile communication system, characterized by masking bit groups irrelevant to the determination of the remaining paths. 3. The method of claim 2, wherein the transmission of the message frame between the node of the control station unit network and the node of the base station unit communication network using the bridge node address comprises: a bridge node connected to a node of the control station unit communication network, and a control station side relay line connected to the bridge node. Control station in a mobile communication system comprising a matching device, a base station side relay line matching device connected through a relay line matching with the relay line matching device, and a bridge node connected to a node of a base station unit network connected to the relay line matching device. A method for configuring a path of a multiplexed relay line between a base station and a base station. 10. The method of claim 9, wherein if a transmission failure occurs on any bridge node and the relay line link during the path configuration, the network manager excludes the corresponding bridge node of the failed link from the serviceable target and initializes the initial mask address. The method of claim 7, wherein the message frame is transmitted through another bridge node by changing a value.