KR100970406B1 - test apparatus for possibility of interchange of automatic vehicle-detecting system - Google Patents

Abstract

The present invention extracts transmission and reception data of a module for generating a traffic light lighting signal and a loop signal indicating a vehicle speed, and modules of an unmanned traffic control device operated according to a signal of the simulator, and extracts the data and reference data during normal operation. Disclosed is a compatibility test apparatus for checking the compatibility of the unmanned traffic control equipment to be made of an analysis PC for comparing.

Unmanned Transportation Control System, Compatibility, Simulator

Description

Test apparatus for possibility of interchange of automatic vehicle-detecting system

The present invention relates to a compatibility test apparatus for testing whether the unmanned traffic control equipment combined with various modules can be interchanged with the modules of other unmanned traffic control equipment.

Unmanned traffic control equipment is used to detect traffic signal violations, speed violations, or to measure traffic volume, and is fixedly fixed or mobile at one point.

These unmanned traffic control devices must ensure the reliability of operation before they are installed on site, and when the unmanned traffic control device consisting of multiple modules is manufactured differently by various manufacturers, the modules manufactured by each manufacturer can be interchanged with each other. This should be secured.

In order to verify the reliability of the unmanned traffic control equipment, install the standard unmanned traffic control equipment and the unmanned traffic control equipment (hereinafter referred to as unmanned traffic control equipment or inspected equipment) on the road and operate the traffic lights. When passing, the results of the crackdown between the standard unmanned traffic control equipment and the unmanned traffic control equipment under test (vehicle speed, vehicle number, and signal status at the time) must be compared.

In addition, in order to confirm the compatibility of the unmanned traffic enforcement equipment under test, after replacing and installing specific modules of the standard unmanned traffic enforcement equipment and the unmanned traffic enforcement equipment, it is generated from each module by operating traffic lights while passing the vehicle on the actual road. In this case, compatibility is determined by comparing the data exchanged with the prescribed data.

However, in order to perform reliability test or compatibility test in real road environment, it is very dangerous to install standard unmanned traffic control device and unmanned traffic control device under test, operate traffic lights, and pass the vehicle. This is the job required.

The present invention is to solve such a problem, the problem of the present invention is to install a simulator for generating a traffic light signal and a vehicle entry / exit signal, and to extract the operation result of the test equipment to be operated by the signal of the simulator An object of the present invention is to provide a compatibility inspection apparatus for unmanned traffic control equipment that can confirm the reliability and compatibility of the inspection equipment.

In the compatibility inspection apparatus of the unmanned traffic enforcement equipment that checks the compatibility of the unmanned traffic enforcement equipment installed with a specific module replaced with the standard unmanned traffic enforcement equipment: Dummy module for detecting data transmitted and received between the modules of the unmanned traffic enforcement equipment ; A simulator for generating and transmitting a loop signal having a time difference generated when a virtual vehicle passes through the unmanned traffic control device under test and a signal lamp lighting signal indicating that a specific signal lamp is turned on; When the speed signal and the signal lamp lighting signal of the simulator are input to the unmanned traffic control device, reference data to be transmitted and received between the modules of the unmanned traffic control device are prepared, and actual data transmitted from the dummy module is input. And an analysis computer for analyzing whether the reference data matches the actual data, and the simulator changes the time difference so that the unmanned traffic control device recognizes that the speed of the vehicle has changed.

In the present invention, it is preferable that the transmission and reception of data between the modules of the inspection apparatus is performed by a serial communication method.

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According to the present invention having the above-mentioned problems and means, by providing a traffic light signal and a loop signal from the simulator to the unmanned traffic enforcement equipment to check the compatibility without installing the unmanned traffic enforcement equipment and the standard unmanned traffic enforcement equipment on the actual road. By doing so, you can get economic time benefits.

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

1 is a block diagram illustrating a connection state of the unmanned traffic control equipment under test, the simulator and the analysis PC in the present invention.

The reference unmanned traffic control equipment (1) receives the CCU module (11) for controlling the modules installed in the reference unmanned traffic control equipment (1), and receives the simulator loop signal generated when the virtual vehicle passes through, and calculates the speed of the vehicle. It detects whether the vehicle is overspeed by speed and supplies the vehicle detection module 13 which detects the current traffic light signal and stable AC power (AC) to the device while receiving the simulator traffic light signal and at the same time, the status of the equipment through serial communication with the CCU. Power supply unit (AVR) module 15 for monitoring the watchdog function is installed in the case.

In addition, the CCU module 31, the vehicle detection module 33, and the power supply module 35 performing the same function are installed in the unmanned traffic control device 3 to be inspected.

In order to check the compatibility, the standard unmanned traffic control equipment (1) is replaced with the specific module of the unmanned traffic control equipment (3), so that it is primarily manufactured in the same size and whether the connection ports are compatible with each other. Carry out a primary specification check.

In addition, the dummy module 17 is additionally installed in the standard unmanned traffic control device 1 and the unmanned traffic control device 3 to be inspected for compatibility. The dummy module 17 is connected to the serial communication line of the CCU module 31, the vehicle detection module 33, and the power supply module 35 to detect and transmit data transmitted and received between these modules to the outside.

As such, after a specific module of the unmanned traffic control device 3 to be installed is replaced with a corresponding module of the reference unmanned traffic control device 1, it is checked whether they perform an appropriate operation.

 The analysis PC 9 is provided with an analysis program for analyzing a scenario to be performed by the inspector for the compatibility check and a result of performing the compatibility check according to the scenario.

The simulator 5 generates a traffic light signal and a loop signal according to a scenario and supplies the traffic light signal to the unmanned traffic control device 3 under test.

In addition, the simulator (5) and the analysis PC (9), the maintenance SW PC (7) and the unmanned traffic control equipment (3), the maintenance SW PC (7) and the analysis PC (9) can transmit data by TCP / IP. The CCU module 31, the vehicle detection module 33, and the power supply module 35 of the unmanned traffic control device 3 under test transmit and receive data by serial communication.

The inspector replaces and installs a specific module of the reference unmanned traffic control device 1 with the corresponding module of the unmanned traffic control device 3 according to the scenario of the analysis PC 9 for the compatibility test. As an example, a case in which the vehicle detection module 33 is replaced with the vehicle detection module 13 of the reference unmanned traffic control device 1 will be described.

In this state, the CCU module 31 and the maintenance SW PC 7 are connected to the TCP / IP port because the data is transmitted by TCP / IP, and the CCU module 31 and the vehicle detection module 33 are serially connected. It is made by a communication method, the dummy module 37 is connected to the serial communication line, the data output from the dummy module is transmitted to the analysis PC (9).

The maintenance SW installed in the maintenance SW PC 7 selects an intermittent mode to be performed by the unmanned traffic control device 3, namely, an overspeed detection mode, a bus-only lane violation mode, a signal violation mode, a section interruption mode, and the like. Software to allow the user to select the enforcement speed, set the equipment status of the unmanned traffic control equipment (3) such as the shape of the traffic light, the brightness of the camera image, and set the display status of the enforcement information. The setting by the maintenance SW PC 7 must be set as specified in the scenario.

As such, when the traffic light signal and the loop signal are input from the simulator 5 to the unmanned traffic control device 3 installed in the vehicle detection module replaced with that of the reference unmanned traffic control device 1, the maintenance SW PC 7 is inputted to the maintenance SW PC 7. After the operation is performed, the data transmitted / received between the CCU module, the vehicle detection module, and the power supply module in the unmanned traffic control equipment 3 under test is finally input to the analysis PC 9, and the analysis is performed. In the PC 9, the contents of the data transmission / reception are compared with the reference data, and they are analyzed to match them, and the analysis results are displayed.

2 is a circuit diagram of a simulator of the present invention, Figure 3 is an exemplary diagram of a loop signal generated in the simulator of the present invention.

The mode setting unit 61 is connected to the loop signal generator 63 of the simulator 5, and the inspector sets the loop signal generation lane through the mode setting unit 61 according to the inspection scenario (during the first and second roads). One lane selection, one lane selection of three lanes and four lanes, and a virtual vehicle pass loop signal can be generated in a total of two lanes).

The speed input unit 59 is connected to the loop signal generator 63, and the inspector inputs a desired speed to the speed input unit 59 according to a scenario.

The loop signal generator 63 generates a loop signal according to a speed input through the speed input unit 63 and a mode input from the mode setting unit 61.

3 illustrates loop signals A, B, C, and D generated when two virtual vehicles pass through one set lane. Two loop signals are required to measure the speed of a vehicle, so two loop signals must be generated when passing through a vehicle. Therefore, loop signals A and B are signals generated when one vehicle passes, and are input to the unmanned traffic enforcement equipment under test, while loop signals C and D are signals generated when another vehicle passes. Is entered.

At this time, the time difference T1 of the loop signals A and B and the time difference T2 of the loop signals C and D are proportional to the passing time of the vehicle, and the time difference is determined according to the speed value set by the speed input unit 59. . Therefore, the loop signals C and D mean a case where a speed relatively higher than the loop signals A and B is set.

The signal light generator 53 of the simulator 5 is connected to a signal selector 53 for selecting red, green, orange, and left turn signals, and is turned on when a specific signal light is selected in the signal selector 53. Traffic light lamps 57 are connected.

The traffic light signal generator 55 generates specific traffic light lighting information and transmits the traffic light lamp 57 to the unmanned traffic control device 3 when the specific traffic light is selected by the signal selector 53, and sends the traffic light lamp 57 to the signal selector 53. Lights up according to the input of).

4 is a circuit diagram illustrating an operation process of the present invention.

In the analysis PC 9, a plurality of test scenarios are prepared for the compatibility test, and the inspector prepares the CCU module 31, the vehicle detection module 33, and the power supply device installed in the unmanned traffic control equipment 3 according to the test scenario. Replace one or two of the modules 35 with a module of the reference unmanned traffic control equipment 1 and set the mode and the speed of the simulator 5 according to the test scenario to detect the loop signal and the traffic light signal. Supply to the intermittent equipment (3).

In addition, the dummy module 37 of the unmanned traffic control device 3 under test analyzes data transmitted and received on the serial communication line between the CCU module 31, the vehicle detection module 33, and the power supply module 35. To be sent).

The analysis module 91 of the analysis PC 9 receives the simulated traffic light signal, the loop signal, the setting mode information, and the state information of the simulator 5, and then the module of the unmanned traffic control device 3 according to the test scenario. Generate the reference data to be transmitted and received between them and the reference log data to be generated in the maintenance SW PC (7), the transmission and reception data input from the actual dummy module 37 and the log data of the maintenance SW PC (7) And then analyze whether the reference data and the reference log data match.

At this time, the log data are OP code information and corresponding setting information transmitted and received between the maintenance SW PC 7 and the unmanned traffic control device 3 to be inspected.

The analysis PC 9 displays the results of the analysis on the monitor for each item in a prepared form.

In particular, the above compatibility test is carried out not only in the unmanned enforcement equipment under test but also in the standard unmanned enforcement equipment.

The unmanned traffic control equipment of FIG. 1 to FIG. 4 may be operated in a fixed state and may be used as a wireless mobile device. The protection scope of the present invention is defined by the following claims.

1 is a block diagram showing a connection state of the unmanned traffic control equipment under test, the simulator and the analysis PC in the present invention.

2 is a circuit diagram of a simulator of the present invention.

3 is an exemplary diagram of a loop signal generated in the simulator of the present invention.

4 is a circuit diagram illustrating an operation process of the present invention.

Claims (3)

In the compatibility inspection apparatus of the unmanned traffic enforcement equipment which checks the compatibility of the installed unmanned traffic enforcement equipment with a specific module replaced with the standard unmanned traffic enforcement equipment: A dummy module detecting data transmitted and received between the modules of the unmanned traffic control device under test; A simulator for generating and transmitting a loop signal having a time difference generated when a virtual vehicle passes through the unmanned traffic control device under test and a signal lamp lighting signal indicating that a specific signal lamp is turned on; When the speed signal and the signal lamp lighting signal of the simulator are input to the unmanned traffic control device, reference data to be transmitted and received between the modules of the unmanned traffic control device are prepared, and actual data transmitted from the dummy module is input. An analysis computer for receiving and analyzing whether the reference data matches the actual data; The simulator is a device for checking the compatibility of unmanned traffic control equipment, characterized in that the unmanned traffic control equipment to recognize that the speed of the vehicle is changed by changing the time difference. The apparatus of claim 1, wherein the transmission and reception of data between the modules of the inspection apparatus is performed by a serial communication method. delete

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