KR20040045066A - Apparatus for determination of transmitter/receive signal pass on optical network - Google Patents

Abstract

PURPOSE: A method for measuring a signal path in network is provided to optimize a data transmission path by detecting luminous intensity of each node. CONSTITUTION: A luminous intensity detector(20) outputs a current value according to intensity of light inputted from an optical cable connected to a connector(10). A calculating and amplifying unit(30) calculates/amplifies a value of the infinitesimal current to a pre-set level and outputs it as a voltage signal. A voltage detector(40) detects a level of the voltage outputted from the calculating and amplifying unit(30) and indicates attenuated degree of luminous intensity and sensitivity with respect to a corresponding path. A current adjusting unit(50) adjusts an output voltage level of the calculating and amplifying unit(30).

Description

Signal path measuring device in the network {APPARATUS FOR DETERMINATION OF TRANSMITTER / RECEIVE SIGNAL PASS ON OPTICAL NETWORK}

The present invention relates to a network connected through an optical cable, and more particularly, in a network using an optical cable network to detect the brightness of each node and to optimize a data transmission path. A signal path measuring device.

In general, in accordance with the expansion of the application of various multimedia devices to automobiles and the application of various convenience devices such as collision warning device, navigation device, drowsiness driving prevention device, lane identification device, etc. The configuration is being applied to the optical cable, and the network application through the optical cable is accelerating as the data processing speed of the device to be applied is increased.

As described above, in the process of connecting each unit to be used in constructing a network using an optical cable, a connection in a straight path should be involved as much as possible, and an intermediate connection should be excluded for cables providing data transmission and reception. It should not be twisted or severely bent.

However, due to the nature of the automotive field, only the optical cable cannot be routed separately, and it can only be applied to the wiring in the form of a subassembly.

Therefore, it is inevitable that bending or twisting occurs during the routing of the optical cable according to each branch of the wiring, and it is a trend that modularized components are applied to reduce labor in mass production lines. As a result, in the high speed data transmission, the reduction of the speed and the loss of the signal occur, and the disadvantage of having to increase the power of the output signal.

That is, attenuation of the light intensity occurs due to the intermediate connection, the twisting and the bending of the optical cable, etc., thereby reducing the speed of the transmitted signal.

For example, as shown in the accompanying FIG. 3, a plurality of units (unit A, unit B, unit C, unit D) mounted at respective predetermined positions in the vehicle are connected via the optical cable F, Assuming the connection between the unit A and the unit B is connected using the joint connector E due to a shortage of cables, a measure against short circuit or disconnection, etc., the amount of light attenuation according to the connection in the optical cable itself connecting each unit About 2.23 발생 is generated, and the amount of luminosity attenuation generated by coupling to the vehicle wiring harness as a subassembly is about 8.96 ,, and the amount of luminosity attenuation when the vehicle is mounted is about 10.46 ㏈. Luminance attenuation is about 12.81㏈.

The present invention has been invented to solve the above problems, and its object is to detect the brightness of light for each node (Node) in a system using an optical network to find a transmission path that minimizes the attenuation of light between each unit The data transmission path is optimally connected.

1 is a block diagram of an apparatus for measuring a signal path in a network according to the present invention.

2 is an exemplary diagram for performing signal path measurement using a signal path measurement apparatus in a network according to the present invention.

3 is a state diagram showing a general network connection configuration relationship.

The present invention for realizing the above object is a connector for connecting the optical cable wired to the position where the measurement target unit is installed; A luminosity detector for outputting a current value (conduction electron) thereto according to the luminosity (light intensity) input from the optical cable connected to the connector; An operational amplifier which amplifies the minute current value output from the photometric detector to a set level and outputs the signal as a voltage signal; It includes a voltage detector for detecting the level of the voltage output from the operational amplifier to indicate the degree of sensitivity and the attenuation of the light intensity for the path.

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

As can be seen in FIG. 1, the signal path side device in the network according to the present invention comprises a connector 10, a light intensity detector 20, an operational amplifier 30, a voltage detector 40, and a current regulator 50. The connector 10 connects the optical cable wired to the position where the target module is installed.

The photometric detector 20 is composed of a photodiode and outputs a current value (conducting electron) thereto according to the light intensity (light intensity) input from the optical cable connected to the connector 10.

The operational amplifier 30 operates to amplify the minute current value outputted from the brightness detector 20 to a set level and outputs the signal as a voltage.

The voltage detector 40 detects the level of the voltage output from the operational amplifier 30 and indicates the degree of attenuation and the sensitivity of the brightness of the corresponding path.

The current regulator 50 is made of a variable resistor and adjusts the output voltage level of the operational amplifier 50.

In the above, the operational amplifier 30 has a ground connected to the non-inverting terminal (+), and an output feedback value and an output of the light intensity detector 20 are connected to the inverting terminal (−).

The operation of measuring a signal path in a network composed of optical cables using the present invention having the above configuration is as follows.

For example, when the light intensity is to be measured at the position of the unit B connected to the unit A in the configuration of FIG. 3, as can be seen in FIG. 2, the present invention is directed to an optical cable wired from the unit A to the position of the unit B. The connector 10 of the measuring device is connected.

After the unit A is connected to the measuring device of the present invention as described above, when the initial power is applied, the unit A transmits (Tx) initialization data for confirming whether the sub units are connected and then receives and analyzes the sub units for connection. Check.

At this time, since the sub-unit which is the measuring device is connected to the position of the unit B, when the unit A determines that the sub-unit is connected to the unit B and outputs the light quantity measuring signal, the light quantity measuring signal output from the unit A is It is applied to the photo detector 20 through the connector 10 to enable the photo detector 20, and outputs a current (conducting electron) in accordance with the light intensity (light intensity) to the inverting terminal (-) of the operational amplifier 30 ) Is entered.

In this case, the operational amplifier 30 may amplify and convert the current applied to the voltage according to the adjusted value of the current regulator 50 which sets the feedback to the output terminal, and then apply the voltage to the voltage detector 40.

Therefore, the tester who tests the signal path confirms the brightness sensitivity between the unit A and the unit B indicated by the voltage detector 40.

Subsequently, the measuring device of the present invention is disconnected at the position of the unit B and then connected to the optical cable wired to the unit C to measure the light sensitivity between the unit B and the unit C through the above-described process.

Therefore, if the signal transmission path between the unit A and the unit C is to be set, the above-described process is repeated to measure the luminance sensitivity between the unit A and the unit B, and the luminance sensitivity between the unit B and the unit C is measured to determine the degree of attenuation thereof. Comprehensive calculation extraction.

Thereafter, the luminance sensitivity between the unit A and the unit D is measured, and the luminance decrement between the unit D and the unit C is measured to comprehensively calculate and extract the degree of attenuation thereof.

As described above, when the luminance sensitivity of each path connected to the unit C is extracted, a path having a small luminance attenuation is selected from the two values, and the path is determined as a signal transmission path.

As described above, the present invention measures the attenuation of the light intensity between each unit in constructing a network by using an optical cable, and selects and sets a path having the least attenuation for data transmission. to provide.

Claims (5)

In a network using an optical cable, A connector for connecting the optical cable wired to the position where the measurement target unit is installed; A luminosity detector for outputting a current value (conduction electron) thereto according to the luminosity (light intensity) input from the optical cable connected to the connector; An operational amplifier which amplifies the minute current value output from the photometric detector to a set level and outputs the signal as a voltage signal; And a voltage detector configured to detect a level of a voltage output from the operational amplifier and indicate a degree and a sensitivity of brightness of a corresponding path. The method of claim 1, And a current regulator for setting an amplification level by adjusting an output voltage fed back from the operational amplifier. The method of claim 1, The operational amplifier is a signal path measuring device in a network, characterized in that the ground is connected to the non-inverting terminal (+), the output terminal of the inverting terminal (-) and the output terminal of the light intensity detector. The method of claim 1, And said photometric detector comprises a photodiode. The method of claim 1, The device for measuring the signal path in a network, characterized in that the current regulator is made of a variable resistor.