KR20070008315A - Device and method for examining a trouble of most network - Google Patents

Abstract

A device and a method for diagnosing the MOST(Media Oriented System Transport) network are provided to correctly check a failed position inside the MOST network by installing a diagnosis device to the inside of the MOST network in case that failure such as rink break is generated in the MOST network. An optical connector connection part(100) receives light output from a unit operated by switching into a master mode owing to the failure of the MOST network. A MOST transceiver(102) records a node position address newly assigned by the light inputted to the optical connector connection part. A controller(104) reads and displays the node position address recorded in the MOST transceiver to a display part(106).

Description

Device and method for examining a trouble of MOST network

1 is a view schematically showing a conventional MOST network.

2 is a view schematically showing a MOST network having a failure diagnosis apparatus according to the present invention.

3 is a view schematically showing a failure diagnosis apparatus of the MOST network according to the present invention.

4 is a flowchart sequentially showing a failure diagnosis method of the MOST network according to the present invention.

The present invention relates to a device for diagnosing a failure of a MOST network and a diagnosis method thereof, and more particularly, to record a node location address newly allocated according to the MOST network protocol when a failure such as a ring break occurs in the MOST network. In addition, the present invention relates to a fault diagnosis device of a MOST system and a diagnosis method thereof, by including a fault diagnosis device implemented in a MOST network to display a recorded node location address.

In recent years, automobiles consisting of more than 30,000 parts have moved away from the previous simple parts assembly level, and the parts work organically with each other, and due to the tendency of electronics and information, various kinds of electronic devices such as audio, AV, DVD, navigation, telematics terminals, etc. Significantly increased the mounting caused a number of problems.

The wires in the car, which have expanded to about 300 strands, are a big problem in the design and assembly process of the car. A new concept that has been attracting attention to this problem is the Driver Information System (DIS).

The driver information system is a system that can fully control various devices such as steering wheel, door, window and mirror and check the operation status with only one monitor in the car. To this end, the introduction of ergonomic design and the implementation of the HMI (Human Machine Interface) concept makes cars more humanized than ever before.

This driver information system is built on the in-vehicle network system that is currently active. The network technology already used transmits and receives a small amount of communication information through the control area network (CAN) and the local interconnect network (LIN), which is a vehicle device control protocol, but DIS can transmit a large amount of multimedia data at high speed through optical fiber. Based on the MOST network (Media Oriented Systems Transport), a multimedia device network, various products and devices in the car are connected and controlled.

Here, MOST network is a network technology that can transmit large-capacity multimedia data through high-speed communication of 24.5Mbps through optical fiber, which is one of DIS's core technologies, and is a network protocol for operating multimedia devices such as audio and video in cars at high speed. .

The MOST network connects a variety of multimedia devices to a single network in a ring structure, which is simple in structure, requires only optical fiber and power lines, and is easy to design and maintain, expands devices and devices, and provides a large amount of data at high speed. As described above, since the optical fiber is used, reliability and stability are excellent, and various types of data such as audio, video, data packets, and control signals can be simultaneously transmitted.

And, as shown in Fig. 1, the MOST network first emits light in order to synchronize the entire MOST network from the head unit 1, and by this light, the other units of the MOST network, that is, the radio tuner 2, In the register of the MOST transceiver of the amplifier 3 and the DVD player 4, the node position address starting from the head unit 1 is recorded. For example, the node 10 is stored in the transceiver 10 of the head unit 1. The node address of 0x401 is recorded in the transceiver 20 of the radio tuner 2, 0x402 is recorded in the transceiver 30 of the amplifier 3, and the transceiver of the DVD player 4 is started. At 40, a node position address of 0x403 is recorded.

In the above, when it is confirmed that the light emitted from the head unit 1 turns back into the head unit 1, the MOST network operates normally, which is called a locked state.

On the other hand, when the units (1, 2, 3, 4) constituting the MOST network is broken or the optical cable is broken, the light emitted from the head unit 1 does not return to the head unit 1 again. This is called an unlocked state or a ring break.

In such an unlock or ring brake, the Ring Break Diagnosis is activated according to the MOST protocol. When the light sent from the head unit 1 does not enter the units 2, 3, and 4 constituting the MOST network, The units 2, 3, and 4 are switched to a master mode capable of emitting light and emit light by themselves. The new node location address is assigned.

For example, when a ring brake occurs between the amplifier 2 and the DVD player 4, no light enters the DVD player 4, and if such a state continues for a predetermined time, the DVD player 4 is started. In accordance with the MOST protocol, a new node location address is assigned to each unit (1, 2, 3, 4).

That is, a node position address of 0x400 is assigned to the DVD player 4 switched to the master mode, 0x401 to the head unit 1, 0x402 to the radio tuner 2, and 0x403 to the amplifier 3.

In this way, the assigned address is recorded in the registers of the MOST transceivers 10, 20, 30, 40 and 102 of each unit 2, 3 and 4 including the head unit 1.

However, the conventional fault diagnosis function operating in the MOST network does not provide information on the location where the ring brake is generated, so that it is not easy to find and repair or replace a damaged cable or a defective unit on the MOST network.

The present invention was created to solve the above problems, and when a failure such as a ring break occurs in the MOST network, the node position address newly recorded according to the MOST network protocol is recorded, and the recorded node position is recorded. It is an object of the present invention to provide a fault diagnosis device of a MOST system and a diagnosis method thereof, by which a fault diagnosis device implemented to display an address is provided in a MOST network so that a location of a fault within a MOST network can be accurately identified.

In order to achieve the above object, the present invention provides an optical connector connecting portion for receiving the light emitted from the unit operating by switching to the master mode by the failure of the MOST network; It provides a fault diagnosis apparatus of the MOST network including a MOST transceiver that records a node position address newly allocated by the light coming into the optical connector connection, and a control unit for reading and displaying the node position address recorded in the MOST transceiver. .

On the other hand, in the failure diagnosis method of the MOST network of the present invention, when a unit in which no light is incident from the head unit due to a failure of the MOST network is switched to the master mode, the light is emitted from the unit switched to the master mode to diagnose the failure on the MOST network. A first step of newly assigning a node position address to the device, and a second step of reading and displaying the newly assigned node position address to the fault diagnosis apparatus so as to identify a unit where no light is incident through the node position address. Including fault diagnosis device of MOST network to include.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Advantages and features of the present invention, and a method of achieving the same will be apparent with reference to the embodiments described below in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but can be embodied in various forms beyond the embodiments. In addition, like reference numerals refer to like elements throughout the specification.

FIG. 2 is a diagram schematically illustrating a MOST network having a fault diagnosis apparatus according to the present invention, and FIG. 3 is a view schematically showing a fault diagnosis apparatus according to the present invention.

As shown in FIG. 2, the MOST network of the present invention includes a head unit 1 for emitting light to synchronize the MOST network and a plurality of units 2, 3, and 4 for receiving light sent from the head unit 1. )

Here, in the MOST network, the unit consists of a single unit such as a radio tuner (2), an amplifier (3) and a DVD player (4) and the like, and receives the light sent from the head unit (1), and assigns the assigned node position address to each of them. Write to the registers of the MOST transceivers of the units 2, 3 and 4.

In addition, the failure diagnosis apparatus 10 is provided at a predetermined position on the MOST network. The failure diagnosis apparatus 10 according to the embodiment of the present invention is located between the radio tuner 2 and the amplifier 3.

As shown in FIG. 3, in the failure diagnosis apparatus 10 as described above, a failure occurs on the MOST network so that light is not incident from the head unit 1 to receive the light emitted from the unit that is switched to the master mode. It includes an optical connector connection portion 100 connected to the optical cable.

In addition, the failure diagnosis apparatus 10 includes a MOST transceiver 102 having a register for recording a node position address newly allocated based on a unit previously switched to the master mode by the light entering the optical connector connection unit 100. do.

In addition, the failure diagnosis apparatus 10 of the present invention includes a display unit 106 and outputs a node position address read from the MOST transceiver 102 by the control unit 104.

The failure diagnosis method of the MOST network having such a configuration will be described with reference to FIG. 4.

When a ring break occurs due to breakage of the optical cable of the MOST network or failure of the units 2, 3 and 4, the light from the head unit 1 does not enter a predetermined unit of the MOST network.

That is, as shown in FIG. 4, when a ring break occurs between the amplifier 3 and the DVD player 4, the light emitted from the head unit 1 is blocked by the ring break and is not incident on the DVD player 4. (S10)

As such, if the state in which light is not incident on the DVD player 4 for a predetermined time continues, the DVD player 4 is converted to the master mode and outputs the light (S20).

Previously, the light emitted from the DVD player 4 converted to the master mode is sequentially passed through the head unit 1, the radio tuner 2, the failure diagnosis apparatus 10, and the amplifier 3 and assigned a new node position address. For example, the head unit (1), the radio tuner (2), through which the light passes sequentially, starting from the step of assigning a node position address of 0x400 to the DVD player 4 which is converted to the master mode and outputs the light. Node location addresses of 0x401, 0x402, 0x403, and 0x404 are sequentially assigned to the failure diagnosis apparatus 10 and the amplifier 3, respectively. At this time, the allocated node location address is recorded in the registers of the MOST transceivers 10, 20, 30, 40, and 102 provided in the units 1, 2, 3, 4, and 10 (S30).

Then, the control unit 104 of the failure diagnosis apparatus 10 reads the node position address of the failure diagnosis apparatus 10 newly allocated and recorded above from the register of the MOST transceiver 102 (S40), and reads the node position. The address is output to the display unit 106 (S50).

According to the above-described embodiment, the node position address recorded in the MOST transceiver 102 of the fault diagnosis apparatus 10 becomes 0x403, and is counterclockwise from the fault diagnosis apparatus 10 from the result of outputting it to the display unit 106. It is possible to confirm that there is no light incident on the DVD player 4 located in the third direction. This means that a ring brake is generated between the DVD player 4 and the amplifier 3 so that light incident on the DVD player 4 is blocked or a failure occurs in the DVD player 4.

Therefore, according to the present invention, through the failure diagnosis apparatus 10 provided in the MOST network, it is possible to accurately grasp the location of the ring brake occurring in the MOST network or the location of the failed unit.

According to the present invention, when a failure such as a ring break occurs in the MOST network, a fault diagnosis apparatus implemented to record a newly allocated node location address according to the MOST network protocol and display the recorded node location address. By providing in the MOST network, there is an effect that can accurately identify the location of the failure in the MOST network.

In addition, accurate identification of faults within the MOST network facilitates the repair and replacement of damaged optical cables or components.

Claims (2)

An optical connector connecting portion to which light emitted from a unit operating in a master mode by a failure of a MOST network is received; A MOST transceiver for recording a node location address newly allocated by the light entering the optical connector connection portion; And And a control unit for reading and displaying the node location address recorded in the MOST transceiver. When a unit in which no light is incident from the head unit is switched to the master mode due to a failure of the MOST network, light is emitted from the unit switched to the master mode so that a node position address is newly assigned to the failure diagnosis apparatus on the MOST network. Stage 1; And And a second step of reading and displaying a node position address newly assigned to the failure diagnosis apparatus, so as to identify a unit through which the light is not incident through the node position address.

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