KR100295458B1 - How to change the high level data link control interface time slot bus (HIT_BUS) port on the device control board - Google Patents

Abstract

The present invention relates to a method of changing a high-level data link control (HDLC) interface timeslot bus (HIT_BUS) port of a device control board, wherein the operator is man-to-person without reloading processor load data (PLD) and replacing firmware. By enabling the HIT_BUS port to be changed through mechanical communication (MMC), it reduces the port change time and simplifies the change procedure.

Description

How to change the upper level data link control interface timeslot bus (HIT_KS) port of the device control board

The present invention relates to a method of changing a high level data link control (HDLC) interface timeslot bus (hereinafter referred to as HIT_BUS) port of a device control board. This is a method that allows the operator to change the HIT_BUS port through man-machine communication (hereinafter referred to as MMC) without replacing the (firmware).

In general, the communication between the telephone processor TP and the device control board is performed by the HIT_BUS communication. As illustrated in FIG. 1, the switch board 2 is connected between the telephone processor 1 and the device controller 3. The switch board 2 can adjust the data transmission rate according to the bandwidth of the device. The switch board 2 can be selected in the unit of 128Kbps from 128Kbps to 2.048Mbps.

In addition, four switch boards 2 can be mounted in one telephone processor 1, and one switch board 2 can communicate with 16 devices having 128 Kbps transmission rate. ) Can accommodate up to 64 devices.

In addition, the communication between the telephone processor 1 and the switch board 2 always transmits data regardless of the active-standby state of the switch board 2, so that the telephone can Communication between the processor 1 and the device can transfer data without loss using other paths.

In addition, when a failure occurs in the device, switching between the device controllers 3 or switching of the switch board 2 connected to the failing device controller occurs to isolate the failure.

Therefore, even if a device fails, it does not affect the communication status of other devices sharing the communication path.

In the configuration of the port change process of the conventional HIT_BUS in such a configuration, as shown in FIG. 2, the HIT_BUS communication uses one designated port between the telephone processor 1 and the device control board. The port number assigned to each device control board was recognized and used as a unique value of the corresponding device controller 2.

In this case, if an error occurs in the HIT_BUS port or if the low port is required to be empty due to insufficient communication capacity (128K per channel) when assigning a channel, the port must be changed.

In the related art, a cable is changed between the switch board 2 and the device controller 3 (S1), and then a new PLD is manufactured and reloaded to change the port value due to the changed cable (S2). .

Subsequently, if a new ROM is made to replace the firmware of the device controller of the system and then replaced (S3), the port change is completed.

However, the port change method as described above has a problem in that the firmware of the device controller of the corresponding system needs to be replaced, and the PLD needs to be reloaded to change the port value stored in the PLD of the MP.

SUMMARY OF THE INVENTION In view of the above-described problems as described above, an object of the present invention is to provide a method for changing a physical port number of HIT_BUS, which is a communication channel between a telephone processor and a device control board, by an operator command.

1 is a schematic block diagram illustrating communication between a telephone processor (TP) and a device controller using HIT_BUS in a typical exchange.

2 is a flowchart illustrating a process of changing a HIT_BUS port of a general device control board.

3 is a flow chart showing a HIT_BUS port change process of the device control board according to the present invention.

<Description of Symbols for Major Parts of Drawings>

4: System state control block (SSC) 5: Main processor state handling block (MPSH)

6: phone processor 7: firmware operator

A first step of updating the processor load data (PLD) using human-machine communication (MMC) to achieve the above object;

Performing a physical change of a port to be changed;

And a third process of initializing firmware by using the updated PLD information for use of the changed port.

The above objects, features, and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention allows the HIT_BUS port to be changed to the MMC to prevent reloading of the PLD, and the changed PLD contents are read from the MP to the lower TP when the device control board is initialized to prevent firmware replacement of the device control board. Allows this information to be sent to the device control board.

The above process will be described in detail with reference to the signal flow diagram of FIG. 3.

After the operator changes the HIT_BUS port number of the device that needs to be changed by using the MMC, a firmware information change request is sent to the System Status Control Block (hereinafter referred to as SSC) (4) to update the PLD. When receiving this, the SSC 4 transmits this command to the main processor status handling block (hereinafter referred to as MPSH) 5 of the upper MP on which the device is mounted (T1).

After receiving the firmware information change request, MPSH (5) updates the contents of the PLD storing the firmware information of the system and transmits the updated contents to the SSC (4) through the initialization information change report command.

When the SSC 4 receives the command, it informs the operator that the firmware information has been changed (T2).

The firmware operator 7 then mounts the HIT_BUS cable from the existing telephone processor 6 backboard port, mounts it on the desired port, mounts the HIT_BUS cable on the device control board, and initializes the firmware to be initialized to restart the firmware. Request to the higher phone processor, and the received phone processor requests initialization information to the MPSH 5 of the higher MP (T3).

After receiving the command, the MPSH (5) checks the initialization information of the corresponding firmware and transmits this information to the firmware operator (7) via the telephone processor (6), the firmware operator (7) receives this to initialize the firmware (T4).

As described in detail above, the present invention reduces the port change time and simplifies the procedure by changing the port number of the communication channel between the telephone processor and the device control board using operator commands without reloading the PLD and replacing the firmware. Provide effect.

In addition, a preferred embodiment of the present invention is disclosed for the purpose of illustration, those skilled in the art will be able to make various modifications, changes, additions, etc. within the spirit and scope of the present invention, such modifications and modifications belong to the following claims You will have to look.

Claims (3)

Updating a processor load data (PLD) using human to machine communication (MMC); Performing a physical change of a port to be changed; And a third step of initializing the firmware by using the updated PLD information to use the changed port. 3. A high level data link control interface timeslot bus (HIT_BUS) port change of a device control board is performed. Way. The method of claim 1, The first process includes a first step in which an operator changes a port number of a device that needs to be changed by using an MMC, and then sends a firmware information change request to a system state control block (SSC); A second step of transmitting, by the SSC receiving the request, the request to the main processor status handling block (MPSH) of the upper main processor on which the device is mounted; MPSH, upon receiving the firmware information change request, updates the contents of the PLD storing the firmware information of the corresponding system and transmits the updated contents to the SSC; And receiving the update result by the SSC including a fourth step of notifying the operator of the update result. The method of claim 1, The third process includes a first step of requesting, by a firmware operator, initialization information of firmware to be initialized from a higher level telephone processor; Receiving a request, the telephone processor includes a second step of requesting initialization information to the MPSH of the upper MP; Receiving the request, the MPSH checks the initialization information of the corresponding firmware and transmits the information to the firmware operator via the telephone processor; And a fourth step of initializing the firmware by receiving the initialization information. The method of claim 1, wherein the firmware operator comprises a fourth step of initializing the firmware.