JP2015118669A - Travel information management system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a travel information management system capable of effectively determining deterioration of a road sign.SOLUTION: A digital tachograph 1 includes: a main camera 11 picking up an image of an area including a track on which a vehicle travels; an image recognition CPU 10 recognizing a road mark based on the picked-up image output from the main camera 1 and reference data corresponding to a road sign; and a control system processing CPU 20 recording a type of the recognized road sign, a similarity, a position of the track, and a travel direction of the vehicle on the track as road sign information. Furthermore, a management device 5 includes an information management CPU 54 acquiring the road sign information recorded in the on-vehicle information recording device (digital tachograph 1), accumulates the acquired road sign information, and monitoring similarities of the road signs matching in the position of the track and the travel direction of the track, thereby determining deterioration of the road sign.

Description

  The present invention relates to an operation information management system.

  Conventionally, an operation information management system including an in-vehicle information recording device and a management device is known. For example, in a business operator who uses a vehicle, it is an important issue to prompt a driver of the vehicle to drive safely and prevent an accident. Therefore, for example, an in-vehicle information recording device called “digital tachograph” is used so that the operator's manager can check whether each occupant is performing safe driving on a daily basis.

  The digital tachograph is mounted for each vehicle, and automatically records information such as speed and engine speed acquired every predetermined time (for example, 0.5 seconds). Data recorded in the digital tachograph can be read by a management device (for example, a personal computer) installed in a sales office through a recording medium or a cloud system. Therefore, the manager can grasp the operation information for each crew member by examining the data collected by the digital tachograph using the analysis program installed in the management device. Thereby, it becomes possible to promote safe driving and economical driving for each crew member. This operation information includes vehicle travel time, distance traveled, maximum speed, average speed, overspeed time, overspeed, engine speed overtime and overspeed, sudden start, rapid acceleration, rapid deceleration, idling Time etc.

  In the digital tachograph, a road marking (for example, speed limit) is recognized through a captured image captured by a camera, and the recognized road marking is compared with the vehicle state to record operation information (for example, overspeed). Has also been proposed.

  Here, for example, Patent Document 1 discloses a technique for recognizing road markings based on an image obtained by photographing a predetermined area including a traveling path of the host vehicle with an in-vehicle camera. Further, for example, Patent Document 2 discloses a device that can recognize the speed limit of a travel path in real time. In this device, the speed limit for road marking is recognized based on an image in front of the vehicle captured by the camera, and the obtained speed limit is output to the alarm control unit. The alarm control unit compares the vehicle speed with the speed limit, determines whether the speed is exceeded, and notifies the driver of the excess speed if the speed is exceeded.

JP 2011-43995 A JP 2005-128790 A

  However, the road markings drawn on the road may be unclear compared to the original drawn because it will deteriorate over time, may not be recognized by the captured image, There is a problem that even if it can be recognized, it is erroneously recognized.

  This invention is made | formed in view of this situation, The objective provides the operation information management system which can determine effectively degradation of a road marking.

  In order to solve this problem, the present invention includes an in-vehicle information recording device that is mounted on a vehicle and records operation information of the vehicle, and a management device that manages the operation information of the vehicle recorded in the in-vehicle information recording device. Provide an operation information management system. Here, the in-vehicle information recording device captures an area including a traveling path on which the vehicle travels, thereby outputting a captured image, a captured image output from the camera, and reference data corresponding to the road marking. Based on the similarity, the image recognition unit for recognizing the road surface marking, and the road surface marking recognized by the image recognition unit, the type, the similarity, the position of the road, and the traveling direction of the road And a control system processing unit for recording as information. In addition, the management device accumulates the road marking information acquired by the acquisition unit that acquires the road marking information recorded by the in-vehicle information recording device of each vehicle, the type, the position of the road, and the road And an information management unit that determines the deterioration of the road marking by monitoring the degree of similarity of the road marking with the same traveling direction.

  In the present invention, it is desirable that the road marking information includes a time when the road marking is recognized. In this case, the information management unit of the management device monitors the transition of the degree of similarity over time for road markings that have the same type, the position of the traveling path, and the traveling direction of the traveling path, and the degree of similarity is predetermined. It is preferable to determine the deterioration of the road marking when it falls below the threshold over a certain period.

  ADVANTAGE OF THE INVENTION According to this invention, the similarity regarding the recognized road marking can be collected, recognizing the road marking of a running road with a vehicle-mounted information recording device. Thereby, in the management apparatus, degradation of the road marking drawn on the traveling road can be determined by analyzing the road marking information including the collected similarity. Furthermore, since a plurality of road marking information collected from the in-vehicle information recording device mounted on each vehicle can be widely used, it is possible to accurately determine the deterioration of the road marking.

The block diagram which shows the structure of the operation information management system which concerns on this embodiment. The flowchart explaining operation | movement by the operation information management system which concerns on this embodiment. The flowchart explaining operation | movement by the operation information management system which concerns on this embodiment. The flowchart explaining operation | movement by the operation information management system which concerns on this embodiment.

  FIG. 1 is an explanatory diagram showing the configuration of the operation management system according to the present embodiment. This operation information management system includes a digital tachograph 1 and a management device 5.

  First, the digital tachograph 1 will be described. The digital tachograph 1 is an in-vehicle information recording device that is mounted on a vehicle and records vehicle operation information, and mainly includes an image recognition CPU 10 and a control system processing CPU 20.

  The digital tachograph 1 includes a main camera 11. The main camera 11 is disposed in the vicinity of a vehicle such as an automobile, for example, a driver's seat in the passenger compartment, and images a predetermined area ahead in the traveling direction that can be seen through the windshield glass in front. The main camera 11 images a travel path ahead in the traveling direction in which the vehicle travels, a part of the body of the host vehicle, a preceding vehicle, an oncoming vehicle, and the like as subjects. The main camera 11 can always take an image during the operation of the digital tachograph 1, repeatedly takes an image at a fixed frame period (for example, 30 frames / second), and sequentially outputs the taken images.

  An optional camera 12 may be provided in addition to the main camera 11 or instead of the main camera 11. For example, the option camera 12 is disposed in the vicinity of the rear seat in the vehicle interior, and images a predetermined region behind the traveling direction that can be seen through the rear windshield glass. With this option camera 12, a travel path behind the traveling direction, a part of the body of the host vehicle, a succeeding vehicle, an oncoming vehicle, and the like are imaged as subjects. The image captured by the option camera 12 can be used for recognition of road markings and the like, similar to the image captured by the main camera 11.

  An NTSC (National Television System Committee) video signal output from the main camera 11 is input to the decoder 13. The decoder 13 processes an NTSC video signal, extracts a plurality of signal components (Y, Cb, Cr) included therein, and performs A / D conversion to generate a digital image signal that can be used for image processing. To do. Image data which is a digital image signal generated in the decoder 13 is read by the image recognition CPU 10. The image data is read by the control system processing CPU 20 as necessary.

  The image recognition CPU 10 has a function for performing predetermined image processing such as pattern recognition. The image recognition CPU 10 recognizes the road marking based on the similarity between the image data corresponding to the captured image output from the main camera 11 and the reference data corresponding to the road marking (image recognition unit).

  The image recognition CPU 10 is connected to a memory 14 composed of ROM and a memory 15 composed of SDRAM. The memory 14 is a database in which information (reference data corresponding to road markings) representing various features of various patterns is registered so that the image recognition CPU 10 can use the pattern matching to recognize road markings. Constant data is held in advance. The memory 15 is used to temporarily hold data such as images processed by the image recognition CPU 10.

  The image recognition CPU 10 has a communication function, and communicates with the control system processing CPU 20. Specifically, when recognizing the road marking, the image recognition CPU 10 notifies the control system processing CPU 20 of the recognized road marking type and its time.

  The image recognition CPU 10 can output image data to the encoder 16 as necessary. The encoder 16 processes the image data and generates an NTSC video signal. The encoder 16 is connected to the monitor output unit 17, and a video signal from the encoder 16 can be output to the monitor by connecting a monitor (not shown) to the monitor output unit 17.

  The control system processing CPU 20 implements various functions required for the digital tachograph 1 by executing a predetermined program stored therein in advance. Specifically, when the control system processing CPU 20 reads information input through various interfaces, the control system processing CPU 20 records this information as predetermined operation information, or the road markings recognized by the image recognition CPU 10 and the vehicle state. And the comparison result is recorded as operation information. For example, the control system processing CPU 20 reads the speed, engine speed, etc. acquired every certain time (for example, 0.5 seconds), and the vehicle travel time, travel distance, maximum speed, average speed, overspeed time, overspeed The operation information such as the number of times, the engine speed excess time and the engine speed excess number, the sudden start, the rapid acceleration, the rapid deceleration, and the idling time are recorded in a file.

  The control system processing CPU 20 is connected to a memory 21 composed of ROM, a memory 22 composed of SDRAM, and a memory 23 composed of EEPROM. The memory 21 holds in advance a program executed by the control system processing CPU 20, various constant data used by the control system processing CPU 20, and the like. The memory 22 is used to hold temporary data such as data being processed. The memory 23 holds data such as various constants referred to by the control system processing CPU 20. Since the memory 23 is a nonvolatile memory, the data is held as it is even when the supply of power is stopped. The contents of data held in the memory 23 can be rewritten as necessary.

  The control system processing CPU 20 is connected to various interfaces.

  The vehicle signal interface 25 inputs various signals output from the vehicle side and performs processing for converting the signals into signals that can be processed by the control system processing CPU 20. Signals handled by the vehicle signal interface 25 include trigger output, ignition (IGN), manual switch (SW), brake, turn signal L side, turn signal R side, vehicle speed pulse, and the like.

  The GPS interface 26 performs processing for converting the GPS position information from the GPS receiver into a signal that can be processed by the control system processing CPU 20. This GPS receiver receives radio waves coming from a plurality of GPS (Global Positioning System) satellites, and calculates the current position of the receiving point, that is, the current position (latitude / longitude) of the vehicle based on the time difference between these radio waves. It is what you want. Therefore, the control system processing CPU 20 can recognize the current position of the vehicle from the GPS information.

  The CAN interface 27 performs processing for inputting information from another device mounted on the vehicle and converting it into a signal that can be processed by the control system processing CPU 20.

  The audio interface 28 is connected to an audio output unit such as a speaker (not shown). The audio interface 28 receives an audio signal from the control system processing CPU 20 and outputs a sound corresponding to the audio signal from the audio output unit. I do.

  The recording medium interface 29 has a slot into which a predetermined recording medium 7 such as a memory card can be mounted, and has a signal processing function necessary for the control system processing CPU 20 to access the recording medium 7. . The control system processing CPU 20 can store the operation information file in the recording medium 7 through the recording medium interface 29.

  The PC setting interface 30 is an interface for connecting a host device such as a personal computer and the digital tachograph 1. By connecting the host device to the PC setting interface 30, it is possible to change, for example, various threshold values referred to by the control system processing CPU 20 or change conditions for determining violations according to an instruction from the host device. Become.

  The vibrator output unit 31 is configured by a small motor or the like, and generates mechanical vibrations for alerting the occupant in accordance with a signal from the control system processing CPU 20.

  Next, the management device 5 will be described. The management device 5 is a device that manages vehicle operation information recorded in the digital tachograph 1. The management device 5 includes a display 50, an operation unit 51, a map database 52, a recording medium interface 53, and an information management CPU 54.

  The display 50 displays various types of information, and for example, a liquid crystal display can be used. The display 50 displays predetermined information according to a control signal output from the information management CPU 45.

  The operation unit 51 is configured by a pointing device such as a keyboard and a mouse. The operation unit 51 outputs an operation signal, which is an instruction operated by the administrator, to the information management CPU 54.

  Similar to the map data used by a general car navigation device, the map database 52 holds map data including information on the travel route (road) in advance. The map database 52 also includes road marking data. The road marking data is data configured by accumulating road marking information recorded by the digital tachograph 1 for each individual vehicle. The type of road marking, time (time when the road marking is recognized), position of the road, The traveling direction and the similarity of the road marking are associated with each other.

  The recording medium interface 53 has a slot into which a predetermined recording medium 7 such as a memory card can be mounted, and has a signal processing function necessary for the information management CPU 54 to access the recording medium 7. . When the recording medium 7 in which the operation information file is recorded by the digital tachograph 1 is attached to the slot of the recording medium interface 53, the information management CPU 54 can read the operation information file from the recording medium 7. .

  The information management CPU 54 controls the entire management device 5 according to a control program stored in a built-in ROM and executes a predetermined operation. Specifically, the information management CPU 31 acquires road marking information recorded by the digital tachograph 1 of each vehicle via the recording medium interface 53 (acquisition unit). In addition, the information management CPU 54 accumulates road marking information acquired from each vehicle, and monitors the similarity of road markings in which the type, the position of the traveling road, and the traveling direction of the traveling road coincide with each other. To determine the deterioration of the road marking (information management unit).

  Hereinafter, the operation of the operation information management system according to the present embodiment will be described. Here, FIGS. 2-4 is a flowchart which shows the operation | movement by the operation information management system which concerns on this embodiment.

  First, in step 10 (S10), the image recognition CPU 10 performs a road marking recognition process. Specifically, when the image recognition CPU 10 reads image data corresponding to one frame from the main camera 11, the image data and pattern matching information stored in the memory 14 (reference data corresponding to road markings) and Pattern matching is performed based on In this pattern matching, the similarity between the two is calculated. When the road marking is displayed in a recognizable manner in the captured image corresponding to the image data, a high degree of similarity is shown between the road marking and the corresponding reference data. The road marking can be recognized.

  In step 11 (S11), the image recognition CPU 10 determines whether or not the road marking has been recognized. If a negative determination is made in step 11, that is, if the road marking has not been recognized, the process returns to step 10. On the other hand, if an affirmative determination is made in step 11, that is, if a road marking is recognized, the process proceeds to step 12.

  In step 12 (S12), the image recognition CPU 10 notifies the control system processing CPU 20 of the recognized type of road marking and the similarity. Corresponding to this notification, the control system processing CPU 20 comprises the type, similarity, time (time when the road marking is recognized), the position of the travel path, and the traveling direction of the travel path. The road marking information is recorded in a file as part of the operation information.

  When the operation information is recorded through such operations, the recording medium 7 on which the operation information file is recorded is collected from the digital tachograph 1 by the manager on the office side at the timing of the end of the operation of the vehicle.

  In the management device 5 on the office side, the recording medium 7 in which the operation information file is recorded is mounted in the slot of the recording medium interface 53. Thereby, the information management CPU 54 reads the operation information file from the recording medium 7 through the recording medium interface 53 (step 20 (S20)).

  In step 21 (S21), the information management CPU 54 determines whether or not road marking information is recorded based on the read operation information. If an affirmative determination is made in step 21, that is, if road marking information is recorded, the process proceeds to step 22 (S22). On the other hand, if a negative determination is made in step 21, that is, if road marking information is not recorded, this processing is terminated.

  In step 22 (S22), the information management CPU 54 refers to the road marking information, identifies the position and traveling direction of the traveling road where the road marking is recognized, and then corresponds to the position and traveling direction of the traveling road. It is determined whether or not road marking data to be present exists in the map database 52. If an affirmative determination is made in step 22, that is, if road marking data exists in the map database 52, the process proceeds to step 23 (S23). On the other hand, if a negative determination is made in step 22, that is, if the road marking data does not exist in the map database 52, the process proceeds to step 24 (S24) described later.

  In step 23, the information management CPU 54 matches the speed limit data in the map database 52 with the road marking type (for example, numbers such as “30”, “40”, “50”) in the road marking information read in step 20. Judge whether to do. If an affirmative determination is made in step 23, that is, if the road marking data matches the type of road marking, the process proceeds to step 24 (S24). On the other hand, if a negative determination is made in step 23, that is, if the speed limit data and the type of speed limit indication do not match, the process proceeds to step 24.

  In step 24, the information management CPU 54 associates the road marking information read in step 20 with the type of road marking, the position of the road, the traveling direction, the similarity, and the time, and uses this as road marking data. Accumulate in the map database 52.

  When the road marking data is accumulated through such an operation, the information management CPU 54 analyzes the road marking data at regular intervals or triggered by an administrator's instruction (step 30 (S30)).

  In step 31 (S31), the information management CPU 54 extracts the data with the same type, the position of the traveling road, and the traveling direction for the road marking, and the state where the similarity is below a predetermined threshold is constant. Determine whether the period has continued. Since the road marking is deteriorated by being used over time, the similarity calculated for the road marking tends to decrease as the deterioration of the road marking proceeds. Therefore, in this step, the transition of the degree of similarity over time is monitored, and the deterioration of the road marking is determined on the condition that the degree of similarity is lowered. From this viewpoint, the predetermined threshold is set in advance. .

  If an affirmative determination is made in step 31, that is, if the predetermined state continues for a certain period, the process proceeds to step 32 (S 32). On the other hand, if a negative determination is made in step 31, that is, if the predetermined state has not continued for a certain period of time, the process returns to step 30, and another road marking with a different type, traveling path position and traveling direction is returned. Perform analysis.

  In step 32, the information management CPU 54 determines that it is necessary to repaint the road marking. In addition, the information management CPU 54 controls the display 50 and the like to notify the administrator that the road marking needs to be repainted, the type of the road marking, the position of the traveling road, and the traveling direction.

  As described above, in the present embodiment, the digital tachograph 1 includes a camera (for example, the main camera 11) that outputs a captured image by capturing an area including a traveling path on which the vehicle travels, and a captured image output from the camera. The image recognition CPU 10 (image recognition unit) for recognizing the road marking based on the similarity with the reference data corresponding to the road marking, the type and similarity of the recognized road marking, the position of the road, and the road And a control system processing CPU 20 (control system processing unit) that records the traveling direction as road marking information. Further, the management device 5 acquires the road marking information recorded by the in-vehicle information recording device of each vehicle, accumulates the acquired road marking information, and each of the type, the position of the traveling path, and the traveling direction of the traveling path. The information management CPU 54 (acquisition unit, information management unit) that determines deterioration of the road markings by monitoring the similarity of the road markings with the same.

  According to this configuration, the digital tachograph 1 can collect the degree of similarity regarding the recognized road marking while recognizing the road marking of the traveling road. Thereby, the management apparatus 5 can determine the deterioration of the road marking drawn on the traveling road by analyzing the road marking information including the collected similarity. Furthermore, since a plurality of speed limit information collected from the digital tachograph 1 mounted on each vehicle can be widely used, it is possible to accurately determine the deterioration of the road marking.

  In the present embodiment, the road marking information includes the time when the road marking is recognized. Then, the information management CPU 54 of the management device 5 monitors the transition of the degree of similarity over time for road markings that have the same type, position of the traveling path, and traveling direction of the traveling path, and the degree of similarity is predetermined. The deterioration of the road marking is determined when the state below the threshold value of the road continues for a certain period.

  Even if the vehicle passes the road marking, the road marking may not be recognized depending on the road surface condition or traffic conditions, and even if it can be recognized, information on misrecognition may be included. However, the deterioration of road markings can be accurately monitored by monitoring multiple accumulated road marking data over time, such as driving the same vehicle multiple times at the same position and driving multiple vehicles at the same position. Can be judged well.

  As mentioned above, although the operation information management system concerning this embodiment was demonstrated, this invention is not limited to this embodiment, A various change is possible in the range of the invention. For example, the in-vehicle information recording device is not limited to a digital tachograph, and can be applied to, for example, a drive recorder or other devices having a similar data recording function. In this embodiment, data is exchanged between the in-vehicle information recording apparatus and the management apparatus via the recording medium, but may be performed by a communication technique such as wired or wireless.

1 Digital tachograph 10 Image recognition CPU
11 Main Camera 12 Optional Camera 13 Decoder 14 Memory (ROM)
15 Memory (SDRAM)
16 Encoder 17 Monitor output unit 20 Control system processing CPU
21 Memory (ROM)
22 Memory (SDRAM)
23 Memory (EEPROM)
25 Vehicle Signal Interface 26 GPS Interface 27 CAN Interface 28 Audio Interface 29 Recording Medium Interface 30 PC Setting Interface 31 Vibrator Output Unit 5 Management Device 50 Display 51 Operation Unit 52 Map Database 53 Recording Medium Interface 54 Information Management CPU
7 Recording media

Claims (2)

In an operation information management system comprising: an in-vehicle information recording device that is mounted on a vehicle and records operation information of the vehicle; and a management device that manages the operation information of the vehicle recorded in the in-vehicle information recording device.
The in-vehicle information recording device is
A camera that outputs a captured image by imaging a region including a travel path on which the vehicle travels;
An image recognition unit for recognizing the road marking based on the similarity between the captured image output from the camera and reference data corresponding to the road marking;
About the road marking recognized by the image recognition unit, it has a control system processing unit that records the type, the similarity, the position of the traveling road, and the traveling direction of the traveling road as road marking information. ,
The management device
An acquisition unit for acquiring road marking information recorded by the in-vehicle information recording device of each vehicle;
The road marking information acquired by the acquisition unit is accumulated, and deterioration of the road marking is monitored by monitoring the degree of similarity of the road markings in which the type, the position of the traveling road, and the traveling direction of the traveling road coincide with each other. An operation information management system comprising: an information management unit for determining. The road marking information includes a time when the road marking is recognized,
The information management unit of the management device monitors the transition of the degree of similarity over time for road markings that have the same type, position of the traveling path, and traveling direction of the traveling path, and the degree of similarity is a predetermined threshold value. 3. The operation information management system according to claim 1, wherein the deterioration of the road marking is determined when a state below the threshold value continues for a certain period.

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