JP4644590B2 - Peripheral vehicle position detection device and peripheral vehicle position detection method - Google Patents

Description

The present invention relates to a surrounding vehicle position detection device and a surrounding vehicle position detection method , and is particularly suitable for use in an apparatus that detects the position of a surrounding vehicle using an in-vehicle radar.

  2. Description of the Related Art In recent years, a system has been provided that detects a surrounding vehicle with an in-vehicle radar and presents position information of the detected surrounding vehicle to a user or controls steering according to a situation. In-vehicle radars receive radio waves reflected from surrounding vehicles by emitting radio waves such as millimeter waves, for example, and based on propagation time from millimeter wave emission to reception and frequency differences caused by the Doppler effect. The position (distance, azimuth) from the vehicle to the surrounding vehicle and the relative speed of the surrounding vehicle with the host vehicle are measured.

  In the case of an application for detecting an obstacle in a wide range around the host vehicle, a wide-angle radar module having a wide radio wave emission area is often used. However, the wide-angle radar module is composed of a small number of transmission / reception antenna elements, can detect the direction only to the extent that there is an obstacle somewhere in the emission area of radio waves, and has a problem that the detection accuracy of the direction is poor. is there.

  Therefore, conventionally, based on the trajectory of the position of the surrounding vehicle repeatedly detected by periodic scanning, the position where the surrounding vehicle will be present is predicted at the next timing, and at the predicted position and the next timing, The specific gravity was calculated with the position actually measured by the radar, and the final position of the surrounding vehicle was calculated. Here, the predicted position is calculated on the assumption that the surrounding vehicle will make the same movement as the movement captured in the previous scans.

  In addition, the final position of the surrounding vehicle is obtained by calculating the specific gravity between the predicted position and the measured position by the radar. In the specific gravity calculation, when the accuracy of the predicted position captured in the previous scan is good (the predicted position and When the difference from the actual position measured by the radar is not large), the specific gravity of the predicted position is made higher than the actual position. Thereby, even if the accuracy of the azimuth actually measured by the radar is poor, the accuracy of the position of the surrounding vehicle to be finally obtained can be increased.

  However, while the surrounding vehicle is moving as predicted, the accuracy of the position calculated by the specific gravity calculation is high, but when the surrounding vehicle moves differently from the prediction, the specific gravity calculation with a high specific gravity of the predicted position is set. As a result, the finally obtained position is attracted toward the predicted position, and the actual position of the surrounding vehicle cannot be obtained correctly. FIG. 5 is a diagram for explaining such a problem. In FIG. 5, D (t0) indicates the position of the surrounding vehicle detected by the radar at the time t = t0, and D (t1) is determined by the radar at the time t = t1, which is advanced by a predetermined time from the time t = t0. The position of the detected surrounding vehicle is shown.

As shown in FIG. 5, if there is a surrounding vehicle that moves straight behind the host vehicle until the previous scan at t = t0, t1, the next timing (timing advanced by a predetermined time from t = t1). ) predicted position _{P P} near the vehicle at t = t2 is created in the straight direction. In addition, the specific gravity of the predicted position in the specific gravity calculation is set higher as the time during which the surrounding vehicle is traveling straight becomes longer. When in this state, the succeeding vehicle when the lane change, even if the measured position P _L as measured by the radar is not largely moved from the straight direction, the position P _T of the finally required the predicted position P _P I will attract you. This increases the position error of the succeeding vehicle whose lane has been changed.

In addition, the white line of the road is recognized from the image captured by the camera, the road condition is recognized from the current position data and the map data measured by the GPS receiver, and the position where the preceding vehicle should be present is determined from these recognition results. There is also a technique in which accurate detection of the inter-vehicle distance can be achieved by estimating and directing the pointing direction of the millimeter wave radar to the estimated position of the preceding vehicle (see, for example, Patent Document 1).
JP-A-6-206507

  However, with the technology described in Patent Document 1, since the position of the preceding vehicle is predicted based on the surrounding situation such as the white line of the road captured by the camera and the current position captured by the GPS receiver, it cannot always be predicted correctly. . For example, since it cannot be predicted at all that the lane change such that the preceding vehicle crosses the white line, if the preceding vehicle changes the lane, the error between the actual existence position and the predicted position becomes large.

  The present invention has been made to solve such problems, and can improve the accuracy of the position of the surrounding vehicle to be finally obtained even when the surrounding vehicle moves differently from the previous movement. The purpose is to be able to.

In order to solve the above-described problems, in the present invention, information acquired from a surrounding vehicle by a captured image of the surrounding vehicle by a camera or inter-vehicle communication (for example, an operation state of a direction indicator, an operation state of a steering wheel, or a direction sensor) Information indicating the vehicle direction or the like) is used to detect the direction in which the surrounding vehicle is predicted to move, and the predicted position of the surrounding vehicle is reset according to the detection result. Then, calculated by the set specific gravity respectively and measured position by resetting the predicted position and the radar, interpolation calculation performed with the measured position and the estimated position after setting the specific gravity, the position of the nearby vehicle To do.

According to the present invention configured as described above, since the predicted position of the surrounding vehicle is calculated from the driving situation itself of the surrounding vehicle, the predicted position according to the actual movement is obtained, and the prediction accuracy is increased. . Therefore, even if the surrounding vehicle moves differently from the previous movement, the predicted position is set after predicting the movement, so the specific gravity is set for the predicted position and the measured position by the radar. The error between the position of the surrounding vehicle finally obtained by the interpolation calculation performed between the predicted position after setting the specific gravity and the actually measured position and the actual existing position can be reduced. Thereby, the detection accuracy of the surrounding vehicle position by the radar can be improved.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram illustrating a configuration example of a surrounding vehicle position detection device according to the present embodiment. FIG. 2 is a diagram illustrating the operation principle of the surrounding vehicle position detection apparatus according to the present embodiment.

  In FIG. 1, reference numeral 1 denotes a radar, which is installed, for example, at the rear of the vehicle. The radar 1 emits a radio wave such as a millimeter wave, and receives a radio wave that is reflected and returned from the surroundings, so that the position of the surrounding vehicle in the vicinity of the host vehicle (distance and direction from the host vehicle). Measure. In addition to the millimeter wave radar, an infrared radar or other radar may be used as the radar 1.

  Reference numeral 2 denotes a camera, which is also installed at the rear part of the vehicle and photographs the rear of the vehicle. If there is a surrounding vehicle behind the vehicle, the surrounding vehicle is photographed by the camera 2. An image processing unit 3 recognizes a direction in which the surrounding vehicle is predicted to move from the blinking state of the direction indicator (winker) of the surrounding vehicle by performing image recognition processing on the image captured by the camera 2. To do. The camera 2 and the image processing unit 3 constitute a moving direction detection unit of the present invention.

  Reference numeral 4 denotes a calculation unit, which predicts a position where a surrounding vehicle will exist at the next timing based on the locus of the position of the surrounding vehicle repeatedly detected by the periodic scan of the radar 1. Then, the specific gravity is calculated between the predicted position and the position actually measured by the radar 1 at the next timing, and the final position of the surrounding vehicle is calculated.

At this time, the calculation unit 4 determines whether or not the difference between the predicted position and the actually measured position by the radar 1 is smaller than a predetermined value. If the difference is smaller, the specific gravity of the predicted position is set higher than before. Thereby, the specific gravity of the predicted position in the specific gravity calculation gradually increases as the state where the difference between the predicted position and the position actually measured by the radar 1 is smaller than the predetermined value continues for a long time. For example, as shown in FIG. 2, if there is a surrounding vehicle that moves straight behind the host vehicle until the previous scan at t = t0, t1, the predicted position of the surrounding vehicle at the next timing t = t2 P _P is created in the straight direction, the specific gravity of the predicted position P _P in the specific gravity calculation is set high.

  In the present embodiment, the calculation unit 4 sets the predicted position of the surrounding vehicle according to the result of the image recognition process by the image processing unit 3. Here, when it is detected as a result of the image recognition of the image processing unit 3 that the blinker of the surrounding vehicle is not blinking, the calculation unit 4 sets the predicted position as usual. For example, in the example of FIG. 2, since the blinker of the surrounding vehicle is not blinking at the time of scanning at t = t0, the predicted position of the surrounding vehicle at t = t1 is set in the straight traveling direction (position of D (t1)).

On the other hand, when it is detected as a result of the image recognition of the image processing unit 3 that the blinker of the surrounding vehicle is blinking, the calculation unit 4 moves the predicted position set as usual by a predetermined amount in the direction of the blinker. Let In the example of FIG. 2, the surrounding vehicle advances to the position D (t1) as predicted at t = t1, and blinking of the blinker of the surrounding vehicle is detected by the scan at that time, so the next timing t = moved by a predetermined amount the predicted position P _P of normally set in the straight direction as the predicted position in the t2 in the direction of the turn signal, the predicted position and P _W. The calculation unit 4 performs specific gravity calculation using the predicted position _PW .

  Next, the operation of the surrounding vehicle position detection apparatus according to the present embodiment configured as described above will be described. FIG. 3 is a flowchart showing an operation example of the surrounding vehicle position detection apparatus according to the present embodiment.

In FIG. 3, the calculation unit 4 predicts a position where the surrounding vehicle will be present at the next timing based on the movement of the surrounding vehicle captured by the previous scan of the radar 1 (step S1). That is, setting the predicted position P _P shown in FIG. Also, the surrounding vehicle is photographed by the camera 2 (step S2), and the blinking state of the blinker of the surrounding vehicle is recognized by the image processing unit 3 performing image recognition processing on the photographed image (step S3).

And the calculating part 4 determines whether the blinking state of the blinker was detected (step S4). Here, feel it is detected that turn signal is blinking, the arithmetic unit 4, sets the predicted position P _W at a position moved by a predetermined amount the predicted position P _P set in step S1 in the direction of the blinker Re-execute (step S5). On the other hand, when the blinking of the turn signal is not detected, the processing in step S5 is not performed, it is maintained without changing the predicted position P _P set in step S1.

Thus, the predicted position setting process is completed. Next, the calculating part 4 inputs the position information of the surrounding vehicle measured by the radar 1 (step S6). Then, the calculation unit 4 performs a predetermined specific gravity calculation using the predicted position P _P obtained in step S1 or the predicted position P _W obtained in step S5 and the actually measured position actually measured by the radar 1 in step S6. The final position of the surrounding vehicle is calculated (step S7).

As described above in detail, in the present embodiment, the moving direction of the surrounding vehicle is detected from the blinking state of the blinker of the surrounding vehicle using the captured image of the surrounding vehicle by the camera 2, and the surrounding vehicle is determined according to the detection result. since so as to set the predicted position P _W of, it is possible to set the predicted position P _W tailored to actual motion around the vehicle, it is possible to increase the prediction accuracy. Thereby, even when the surrounding vehicle moves differently from the previous movement, the error between the position of the surrounding vehicle finally obtained by the specific gravity calculation using the predicted position _PW and the actual existing position can be reduced. Thus, the detection accuracy of the surrounding vehicle position by the radar 1 can be improved.

  In the above embodiment, the example in which the moving direction detection unit is configured by the camera 2 and the image processing unit 3 has been described, but the present invention is not limited to this example. For example, as shown in FIG. 4, the vehicle-to-vehicle communication unit 11 (corresponding to the information acquisition unit of the present invention) that performs wireless communication with surrounding vehicles and the information acquired by the vehicle-to-vehicle communication unit 11 An information processing unit 12 that recognizes the moving direction may be provided, and the moving direction of the surrounding vehicle may be predicted based on the winker operation information acquired from the surrounding vehicle by the inter-vehicle communication unit 11. Further, steering operation information, output information of a direction sensor for detecting the vehicle direction, and the like may be acquired from the surrounding vehicle by the inter-vehicle communication unit 11.

  Moreover, although the said embodiment demonstrated the example which installs the radar 1 and the camera 2 behind the own vehicle, it is not limited to this. For example, the present invention can be applied to a case where the radar 1 and the camera 2 are installed in front of the host vehicle and the positions of surrounding vehicles in front of the host vehicle are detected.

Further, in the above embodiment, so that is moved by a predetermined amount the predicted position P _P in the direction of the turn signal when detecting that the turn signal around the vehicle is flashing, but is not limited thereto. For example, when it is detected that the turn signal around the vehicle is flashing, lowering the specific gravity of the predicted position P _P at the time of performing the specific gravity calculations with the measured position by the predicted position P _P radar 1 by a predetermined amount (measured positions May be increased by a predetermined amount).

  In addition, each of the above-described embodiments is merely an example of implementation in carrying out the present invention, and the technical scope of the present invention should not be construed in a limited manner. In other words, the present invention can be implemented in various forms without departing from the spirit or main features thereof.

  The present invention is useful for an apparatus that detects the position of a surrounding vehicle using an in-vehicle radar.

It is a block diagram which shows the structural example of the surrounding vehicle position detection apparatus by this embodiment. It is a figure which shows the principle of operation of the surrounding vehicle position detection apparatus by this embodiment. It is a flowchart which shows the operation example of the surrounding vehicle position detection apparatus by this embodiment. It is a block diagram which shows the other structural example of the surrounding vehicle position detection apparatus by this embodiment. It is a figure for demonstrating the conventional problem.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Radar 2 Camera 3 Image processing part 4 Calculation part 11 Inter-vehicle communication part 12 Information processing part

Claims (6)

A radar that measures the position of surrounding vehicles existing around the vehicle by emitting radio waves and receiving reflected and returned radio waves,
A movement direction detection unit for detecting a movement prediction direction of the surrounding vehicle;
Based on the locus of the position of the surrounding vehicle repeatedly measured by the radar, the position of the surrounding vehicle after a predetermined time is set as a predicted position, and the position of the surrounding vehicle is determined according to the detection result by the moving direction detection unit. The predicted position is reset , the specific gravity is set for each of the measurement position measured by the radar and the reset predicted position after the predetermined time, and the measured position and the predicted position after the specific gravity is set. A peripheral vehicle position detection device comprising: a calculation unit that obtains the position of the peripheral vehicle by interpolation calculation performed between the two . The moving direction detector is
A camera for photographing the surrounding vehicle,
An image processing unit for recognizing a moving direction of the surrounding vehicle from a blinking state of the direction indicator of the surrounding vehicle by performing image recognition processing on an image captured by the camera; The surrounding vehicle position detection device according to claim 1. The moving direction detector is
Information acquisition that wirelessly communicates with the surrounding vehicles and obtains at least one of direction indicator operation information, steering operation information, and direction sensor output information that detects the vehicle direction of the surrounding vehicles And
The surrounding vehicle position detection device according to claim 1, further comprising an information processing unit that recognizes a moving direction of the surrounding vehicle based on information acquired by the information acquisition unit. A radar that measures the position of surrounding vehicles existing around the vehicle by emitting radio waves and receiving reflected and returned radio waves,
A movement prediction direction detection unit for detecting a movement prediction direction of the surrounding vehicle;
Based on the locus of the position of the surrounding vehicle repeatedly measured by the radar, a predicted position of the surrounding vehicle after a predetermined time is set, and the measured position measured by the radar after the predetermined time and the set prediction A specific gravity for each of the positions, and a calculation unit for obtaining the position of the surrounding vehicle by interpolation calculation between the measurement position and the predicted position after setting the specific gravity ,
The arithmetic unit, upon detecting a movement prediction direction of the peripheral vehicle by the movement direction detection unit, along with lowering the specific gravity of the predicted position in the interpolation calculation by a predetermined amount, the specific gravity of the measurement position by the predetermined amount A surrounding vehicle position detecting device characterized by being raised . A first step of measuring a position of a surrounding vehicle existing around the own vehicle by a radar that emits a radio wave and receives a reflected radio wave;
A second step of setting the position of the surrounding vehicle after a predetermined time as a predicted position based on the locus of the position of the surrounding vehicle repeatedly measured by the radar;
A third step of photographing the surrounding vehicle with a camera;
A fourth step of recognizing the moving direction of the surrounding vehicle from the blinking state of the direction indicator of the surrounding vehicle by performing image recognition processing on the image captured in the third step;
Depending on the direction of movement of the fourth of said peripheral vehicle recognized in step, a fifth step of re-setting the predicted position of the peripheral vehicle set in the second step,
A sixth step of measuring the position of the surrounding vehicle by the radar after the predetermined time;
A specific gravity is set for each of the predicted position reset by the fifth step and the measurement position of the surrounding vehicle measured by the sixth step, and the measurement position and the predicted position after the specific gravity is set. And a seventh step of obtaining the position of the surrounding vehicle by an interpolation calculation performed between and a surrounding vehicle position detection method. A first step of measuring a position of a surrounding vehicle existing around the own vehicle by a radar that emits a radio wave and receives a reflected radio wave;
A second step of setting the position of the surrounding vehicle after a predetermined time as a predicted position based on the locus of the position of the surrounding vehicle repeatedly measured by the radar;
It communicates by radio between said peripheral vehicle, direction indicator operation information of the peripheral vehicle, steering operation information, third to acquire at least one of the output information of the azimuth sensor for detecting the vehicle direction And the steps
A fourth step of recognizing the direction of movement of the surrounding vehicle based on the information acquired in the third step;
Depending on the direction of movement of the fourth of said peripheral vehicle recognized in step, a fifth step of re-setting the predicted position of the peripheral vehicle set in the second step,
A sixth step of measuring the position of the surrounding vehicle by the radar after the predetermined time;
A specific gravity is set for each of the predicted position reset by the fifth step and the measurement position of the surrounding vehicle measured by the sixth step, and the measurement position and the predicted position after the specific gravity is set. And a seventh step of obtaining the position of the surrounding vehicle by an interpolation calculation performed between and a surrounding vehicle position detection method .

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