JP6426512B2 - Driving lane recognition system - Google Patents

Description

  The present invention relates to a traveling parting line recognition apparatus that recognizes a traveling parting line of a road based on an image captured by an onboard camera.

  2. Description of the Related Art Conventionally, there has been proposed an apparatus that recognizes a traveling division line that divides a lane of a road based on an image captured by an on-vehicle camera. In such an apparatus, it becomes a problem to misrecognize other than a traveling division line as a traveling division line. Therefore, in the lane identification device described in Patent Document 1, the image captured by the on-vehicle camera is divided into a plurality of unit blocks, and the dispersion value of luminance and color difference in the unit block is calculated for each unit block. Then, unit blocks having a variance value equal to or higher than the threshold value are excluded because they have high complexity of the image and include disturbance factors, and a traveling lane is detected from the unit blocks whose variance value is less than the threshold value.

JP, 2014-142866, A

  In the above-mentioned lane identification device, even if there is no disturbance factor other than the traveling division line in the unit block, if the traveling division line is blurred or the road surface is rough, the variance value of the unit block is the threshold value. There is a risk of being excluded and being over. Therefore, there is a possibility that it can not recognize a run division line appropriately.

  In view of the above situation, the present invention has as its main object to provide a traveling parting line recognition device capable of improving the recognition accuracy of traveling parting lines.

  The invention according to claim 1 is a traveling lane line recognition apparatus for solving the above-mentioned problems, which is a candidate for a traveling lane line which divides a lane of a road from an image photographed by a camera mounted on a vehicle. A candidate extraction unit that extracts a certain partition line candidate, and a first certainty calculation that calculates, for each feature of the partition line, a partition line certainty factor that is the partition line of the partition line candidate extracted by the candidate extraction unit A second calculation unit configured to calculate the division line certainty factor, which is the division line of the division line candidate, lower as the division line candidate has the feature of the predetermined target that is a disturbance factor when recognizing the division line; An integrated certainty factor is calculated by unifying the certainty factor calculating means, the division line certainty factor calculated by the first certainty factor calculating means, and the section line certainty factor calculated by the second certainty factor calculating means Means of integration and said integration And a division line recognizing means for recognizing as the partition lines the integrated confidence that the calculated higher the lane line candidate than the first threshold value by the step.

  According to the first aspect of the present invention, a parting line candidate which is a candidate for a traveling parting line is extracted from a photographed image of a camera, and the certainty factor of the parting line candidate is calculated for each feature of the traveling parting line. Further, the certainty factor of the parting line candidate is calculated to be lower as the parting line candidate has the feature of the predetermined object that causes the disturbance. That is, it is identified that the dividing line candidate is likely to be the predetermined target, and the certainty factor of the dividing line candidate is calculated to be low. Then, the dividing line certainty factor calculated for the feature of the predetermined object and the dividing line certainty factor calculated for each feature of the traveling parting line are integrated to calculate the integrated certainty factor. Furthermore, a dividing line candidate whose calculated integrated certainty factor is higher than the first threshold value is recognized as a dividing line. Therefore, when the division line candidate is highly likely to correspond to the predetermined object, the integrated division line certainty factor is calculated to be low, so that recognition of the predetermined object as the traveling division line can be suppressed. . Therefore, the recognition accuracy of the traveling lanes can be improved.

  The invention described in claim 2 is a traveling lane line recognition apparatus, which is a lane line candidate that is a candidate for a traveling lane line that divides a road lane from an image captured by a camera mounted on a vehicle. A candidate extraction unit for extracting, a division line recognition unit that recognizes, as the division line, the division line candidate selected from the division line candidates extracted by the candidate extraction unit based on the characteristics of the division line; Object recognition means for recognizing the division line candidate selected from the division line candidates extracted by the candidate extraction means as the predetermined object based on the characteristics of the predetermined object which is a disturbance factor when recognizing a line And when the marking line recognition means does not recognize the marking line, the marking line candidate recognized as the predetermined target by the object recognition means is the new marking line. Characterized in that it does not recognize Te.

  According to the second aspect of the present invention, division line candidates which are candidates for traveling division lines are extracted from the photographed image of the camera. Then, on the basis of the characteristics of the traveling division lines, the division line candidates selected from the extracted division line candidates are recognized as the traveling division lines. Further, based on the feature of the predetermined object which is a disturbance factor, the dividing line candidate selected from the extracted dividing line candidates is recognized as the predetermined object. Then, when the traveling parting line is not recognized based on the characteristics of the traveling parting line, the parting line candidate recognized as the predetermined object is not recognized as a new traveling parting line. Therefore, the recognition accuracy of the traveling lanes can be improved.

The figure which shows the mounting position of a vehicle-mounted camera. FIG. 2 is a block diagram showing a schematic configuration of a traveling lane marking recognition apparatus. The figure which shows the roadside thing extracted as a division line candidate. The figure which shows the roadside thing extracted as a division line candidate. The figure which shows the calculation range of variation. The flowchart which shows the process sequence which recognizes the travel division line which concerns on 1st Embodiment. The flow chart which shows the processing procedure which recognizes the run division line and the roadside thing concerning a 2nd embodiment.

  Hereinafter, each embodiment that embodies the traveling lane marking recognition apparatus will be described with reference to the drawings. In addition, in the following each embodiment, the same code | symbol is attached | subjected to the mutually same or equal part in the figure, and the description is used about the part of the same code | symbol.

First Embodiment
First, with reference to FIGS. 1 and 2, a travel lane line recognition apparatus according to the present embodiment will be described. The travel lane line recognition device according to the present embodiment is an on-vehicle device that is constituted by the ECU 20 and recognizes travel lane lines dividing the left and right of the traveling lane from the front image captured by the on-vehicle camera 10.

  The on-vehicle camera 10 is configured of at least one of a CCD image sensor, a CMOS image sensor, and the like. As shown in FIG. 1, the on-vehicle camera 10 is mounted, for example, in the vicinity of the upper end of the windshield of the vehicle 50, and captures an area extending in a predetermined angle range toward the front of the vehicle. That is, the on-vehicle camera 10 captures the surrounding environment including the road ahead of the vehicle 50.

  The driving support device 40 is a deviation warning device that warns of a lane deviation based on the driving division lines recognized by the ECU 20, and a driving support device that performs driving support. When the travel support device 40 is a departure warning device, the travel support device 40 is configured as a display, a speaker, a human machine interface such as a vibrator, and outputs a warning to the driver when the vehicle 50 deviates from the lane. In addition, when the driving support device 40 is a driving support device, the driving support device 40 is configured as a steering actuator or a braking actuator, and performs steering control and brake control of the vehicle 50.

  The ECU 20 is a computer provided with a CPU, a RAM, a ROM, an I / O, and the like. When the CPU executes various programs stored in the ROM, the candidate extraction unit 21, the determination unit 22, the dividing line certainty calculating unit 23, the roadside object certainty calculating unit 24, the integrating unit 28, and the dividing line recognition unit 29 and each function of the learning unit 30 are realized.

  The candidate extraction unit 21 (candidate extraction unit) extracts division line candidates that are candidates for traveling division lines from the image captured by the on-vehicle camera 10. Specifically, the candidate extraction unit 21 scans the image in the horizontal direction, and extracts an up edge point where the luminance value greatly increases and a down edge point where the luminance value largely decreases. The candidate extraction unit 21 applies the Hough transform to the extracted up edge point and down edge point to extract an edge line composed of the up edge point and an edge line composed of the down edge point. Then, the candidate extraction unit 21 extracts an edge line formed by the up edge point and a line whose outline is an edge line formed by the down edge point as division line candidates.

  The determination unit 22 (determination unit) determines whether the division line candidate extracted by the candidate extraction unit 21 is a compound line by any known method. For example, when the interval between the plurality of dividing line candidates extracted on the same side with respect to the vehicle 50 matches the pattern of the compound line defined in advance, the determining unit 22 determines the plurality of dividing line candidates Is determined to be included in the compound line.

  The dividing line certainty calculating unit 23 (first certainty calculating unit) calculates dividing line certainty of the dividing line candidate extracted by the candidate extracting unit 21 for each feature of the traveling dividing line. The lane line certainty factor indicates the likelihood that the lane line candidate is a traveling lane line. In more detail, the dividing line certainty calculating unit 23 calculates the dividing line certainty higher as the degree of the dividing line candidate including the characteristic of the running parting line is higher, for each of the features of the running parting line. The characteristics of the traveling division line are the contrast of the traveling division line with respect to the road surface, the thickness of the traveling division line, the continuous distance of the traveling division line, and the like.

  The roadside object certainty factor calculation unit 24 (second certainty factor calculation means) determines the division line candidate extracted by the candidate extraction unit 21 based on the feature of the predetermined object which is a disturbance factor when recognizing the traveling division line. Calculate the lane line certainty factor. In the present embodiment, the predetermined object is a roadside object. Roadside items include guard rails, road sidewalls, road shoulders, poles, and the like.

  As shown in FIG. 3, since the white guardrail extended along the lane has a higher luminance than the surrounding area, it is extracted as a candidate for a dividing line in the same manner as an original running dividing line. Further, as shown in FIG. 4, the surface of the curb on the road shoulder looks bright on the screen, and therefore, it is extracted as a division line candidate in the same manner as the original travel division line. As shown in FIGS. 3 and 4, when the roadside object is extracted as a dividing line candidate, the original traveling dividing line is faded and not extracted as a dividing line candidate, the roadside extracted as a dividing line candidate An object may be recognized as a running section line. When a roadside object is recognized as a travel division line, there is a possibility that trouble may occur when performing travel support.

  Therefore, the roadside object certainty factor calculation unit 24 determines the parting line certainty factor of the parting line candidate as the parting line candidate has the feature of the roadside object so that the parting line candidate corresponding to the roadside object is not recognized as the traveling parting line. Calculate low. The characteristics of the roadside object include the variation of color information of the image or the variation of luminance information, the ratio of the width of the dividing line candidate to the distance from the center of the screen in the width direction to the dividing line candidate The lane line candidates extracted on the right and left sides of the vehicle 50, which are far from the width of the vehicle, are asymmetric with respect to the center of the traveling lane, and the like. Hereinafter, calculation of division line certainty factor to the feature of each roadside thing is explained.

  Since there are plantings, grass, and the like around the roadside object, variations in color information and variations in luminance information become large in the vicinity of the parting line candidate corresponding to the roadside object on the image. Therefore, the roadside object certainty factor calculation unit 24 calculates the parting line certainty factor lower as the variation in the color information or the variation in the brightness information around the parting line candidate increases in the image. The variation in color information or the variation in luminance information is calculated by the variation calculating unit 25.

  The variation calculation unit 25 (variation calculation means) calculates variation in color information or variation in luminance information of predetermined regions Rr and Rl close to the dividing line candidate in the image. The variation may be, for example, a variance value. The predetermined regions Rr and Rl are, as shown in FIGS. 4 and 5, a region on the right side adjacent to the division line candidate and a region on the left side.

  However, some composite lines are composed of white lines and yellow lines. Therefore, when the dividing line candidate corresponds to a line included in the compound line, the variation calculated by the variation calculating unit 25 may be relatively large. Therefore, when the roadside object certainty factor calculation unit 24 determines that the dividing line candidate is included in the compound line by the determination unit 22, the variation of the color information or the variation of the brightness information is determined by the feature of the roadside object. And not. That is, when the determining unit 22 determines that the dividing line candidate is included in the compound line, the variation calculating unit 25 does not calculate the variation in color information or the variation in luminance information. As a result, when the parting line candidate corresponds to the compound line, the parting line certainty factor of the parting line candidate is not reduced.

  In addition, roadside objects such as guardrails are at a higher position than the road surface, so they are extracted as division line candidates corresponding to traveling division lines located farther from the vehicle than the actual roadside objects in the width direction of the road. Be done. For example, as shown in FIG. 3, when there is a guardrail on the left side of the vehicle 50, the guardrail exists at a position on the left side of the actual guardrail in the width direction of the road, ie, a position where the guardrail is projected onto the road surface. It is extracted as a candidate for dividing line. Therefore, when the extracted lane line candidate corresponds to a roadside object, the actual roadside object is closer to the on-vehicle camera 10 than the lane line candidate extracted on the road surface. Therefore, when the parting line candidate corresponds to a roadside object, the width Wa of the parting line candidate looks wider than in the case where the parting line candidate corresponds to the traveling parting line.

  Therefore, the roadside object certainty factor calculation unit 24 determines the division line as the ratio of the width of the division line candidate calculated by the candidate width calculation unit 26 to the distance from the center in the width direction of the image to the division line candidate increases. Calculate the degree of certainty low. The candidate width calculation unit 26 (candidate width calculation means) calculates the width of the dividing line candidate, that is, the interval between the edge line consisting of the up edge point and the edge line consisting of the down edge point.

  In addition, when the dividing line candidate corresponds to a roadside object, the width Wa of the dividing line candidate is often far from the width of the dividing line. Therefore, the roadside object certainty factor calculation unit 24 determines the certainty factor as the deviation between the calculated width of the dividing line candidate and the learning value of the width of the traveling dividing line learned by the learning unit 30 described later increases. Calculate low. It should be noted that, instead of the learning value, a standard travel division line width defined in advance may be used.

  In addition, if at least one of the dividing line candidates extracted on the right side and left side of the vehicle 50 corresponds to a roadside object, the left and right dividing line candidates are asymmetric with respect to the center of the running lane. There are many. Therefore, when the lane line candidates extracted on the right and left sides of the vehicle 50 are asymmetrical with respect to the center of the traveling lane, the roadside object certainty factor calculation unit 24 determines the lane line certainty from the first threshold value. It is calculated lower than the third threshold which is also a low value. In this case, the lane line candidate on one side may correspond to the traveling lane line. Therefore, when the roadside item certainty factor calculating unit 24 integrates the dividing line certainty factor by the integration unit 28 described later, the integrated certainty factor exceeds the first threshold when the other parting line certainty factor is sufficiently high. So as not to underestimate the line-line certainty about the asymmetry. For example, the third threshold is set to 50%, and the dividing line certainty factor regarding the asymmetry is set to several tens percent lower than 50%.

  However, at a point where the width of the lane is largely changed from the standard width, such as a branch point of a lane or a junction point, the left and right travel division lines become asymmetric with respect to the center of the lane. Therefore, when the deviation between the lane width and the predetermined width, which is included in advance, is larger than the predetermined deviation, the feature of the roadside is that the division line candidates extracted on the right and left sides of the vehicle 50 are asymmetric. do not do. The vehicle width is estimated from the history of the recognition result of the traveling lanes. When the vehicle 50 includes map information including lane width information and a GPS receiver, the lane width at the current position may be acquired from the map information.

  Further, while the vehicle 50 travels for a predetermined time or a predetermined distance, the holding unit 27 (holding unit) holds the marking line certainty factor calculated by the roadside object certainty factor calculation unit 24. Specifically, the holding unit 27 is a lane line candidate extracted at the same position in the width direction of the lane in the plurality of frames of images taken after that, with the lane line certainty factor calculated by the roadside object certainty factor calculating unit 24. Hold as a certainty for The holding unit 27 may hold division line certainty factors calculated for each of the features of the roadside object, or may integrate and hold the division line certainty factors calculated for each of the features of the roadside object.

  The integration unit 28 (integration means) integrates all the division line certainty degrees calculated by the division line certainty calculation unit 23 and all the division line certainty degrees calculated by the roadside object certainty calculation unit 24, Calculate the integrated certainty factor. For example, Bayesian estimation is an example of a method of integrating parcel line certainty factors. Furthermore, when the dividing line certainty factor is held by the holding unit 27, the integrating unit 28 integrates the dividing line certainty factors held by the holding unit 27 to calculate the integrated certainty factor. Thereby, once the lane line candidates that are likely to be roadside objects are extracted, the lane line candidates extracted at the same position in the width direction of the lane continue to be calculated with relatively low integrated certainty for a while.

  The dividing line recognition unit 29 (division line recognition unit) is a division line candidate whose integrated certainty factor calculated by the integrating unit 28 is higher than the first threshold in each of the right side and the left side of the vehicle 50 The division line candidate having the highest value is recognized as a traveling division line.

  The learning unit 30 (learning unit) learns the width of the traveling lane line recognized by the lane line recognition unit 29. For example, the learning unit 30 calculates a new learning value by performing weighted averaging on the stored learning value and the width of the newly recognized traveling division line, and stores the calculated learning value in the storage device.

  Next, the processing procedure for recognizing the traveling lane lines according to the present embodiment will be described with reference to the flowchart of FIG. The processing procedure is repeatedly executed by the ECU 20 each time an image of one frame is taken by the on-vehicle camera 10.

  First, a forward image captured by the on-vehicle camera 10 is acquired (S10). Subsequently, dividing line candidates are extracted from the image acquired in S10 (S11).

  Subsequently, the certainty factor of the dividing line candidate extracted in S11 is calculated (S12). Specifically, for each of the features of the travel division line, the higher the degree of having the feature of the travel division line is, the higher the division line certainty factor is calculated. Further, the lane line certainty factor is calculated to be lower as the degree of having the feature of the roadside object is higher for each of the features of the roadside object.

  Subsequently, the plurality of dividing line certainty factors calculated in S12 are integrated to calculate an integrated certainty factor (S13). Subsequently, on each of the right side and left side of the vehicle 50, the division line candidate having the integrated certainty factor calculated in S13 higher than the first threshold and having the highest integrated certainty factor is recognized as a traveling parting line, Calculate the parameters. The travel division line parameters are a lane curvature, a curvature change amount, a lane position, a lane inclination, a lane width and the like. Then, the calculated travel lane parameter is output to the travel support device 40. Also, the width of the recognized travel lane is calculated, and the learning value is updated. This is the end of the process.

  According to the first embodiment described above, the following effects can be obtained.

  -As the lane line candidate has the feature of the roadside object, the certainty factor of the lane line candidate is calculated to be lower. That is, when the division line candidate is highly likely to be the predetermined target, the certainty factor of the division line candidate is calculated to be relatively low. Then, the dividing line certainty factor calculated for each feature of the roadside object and the dividing line certainty factor calculated for each feature of the traveling parting line are integrated to calculate an integrated certainty factor. Furthermore, a division line candidate whose calculated integrated certainty factor is higher than the first threshold value is recognized as a traveling division line. Therefore, when it is highly possible that the traveling lane line candidate corresponds to the roadside object, the integrated certainty factor is calculated to be relatively low, so that recognition of the roadside object as the traveling lane line can be suppressed. Therefore, the recognition accuracy of the traveling lanes can be improved.

  The dividing line certainty factor calculated for the feature of the roadside object is held for a predetermined time or a predetermined distance. Then, when the dividing line certainty factor calculated for the feature of the roadside object is held, the integrated certainty factor is calculated using the held dividing line certainty factor. Therefore, even when the actual travel division line is blurred and the division line candidate corresponding to the actual travel division line is not extracted, the integrated certainty factor of the division line candidate corresponding to the roadside object is continuously calculated relatively low. As a result, recognition of the roadside object as a new travel division line can be suitably suppressed.

  In a predetermined area close to a roadside object, variation in color information or luminance information of an image becomes large. Therefore, it is preferable to recognize the roadside object as a travel division line by calculating the division line certainty factor of the division line candidate to be lower as the variation in color information or luminance information of the predetermined area closer to the division line candidate is larger. Can be suppressed.

  In the case where the traveling division line is a compound line, variation in color information or luminance information of an image may be large in a predetermined area close to the traveling division line. Therefore, when it is determined that the dividing line candidate is included in the compound line, the variation in the color information or the luminance information of the image is not considered as the feature of the roadside object. Thereby, it is possible to prevent the division line candidate included in the compound line from being excluded from the recognition target, and the compound line can be appropriately recognized.

  Since the roadside object has a height, it is extracted as a dividing line candidate at a position farther from the vehicle 50 than the actual position of the roadside object in the width direction of the image. Therefore, when the lane line candidate corresponds to a roadside object, it looks thicker than the lane line candidate corresponding to the traveling lane line. Therefore, the division line certainty factor of the division line candidate is calculated to be lower as the ratio of the width of the division line candidate is larger than the distance from the center of the image in the width direction to the division line candidate. Thereby, it can suppress suitably recognizing a roadside thing as a run division line.

  If the lane line candidate corresponds to a roadside object, the width of the lane line candidate is often far from the width of the traveling lane line. Therefore, the division line certainty factor of the division line candidate is calculated to be lower as the deviation between the calculated division line candidate width and the learning value of the recognized travel division line width is larger. Thereby, it can suppress suitably recognizing a roadside thing as a run division line.

  If at least one of the left and right lane line candidates corresponds to a roadside object, the left and right lane line candidates are often asymmetrical with respect to the center of the lane. Therefore, when the left and right dividing line candidates are asymmetric with respect to the center of the lane, the dividing line certainty factor is calculated to be lower than the third threshold. Thereby, it can suppress suitably recognizing a roadside thing as a run division line. At this time, the central position of the lane is calculated from the history information or the like of the recognized traveling lanes.

  • At points where the lane width changes significantly, such as junctions and junctions, the left and right travel division lines are asymmetric with respect to the center of the lanes. Therefore, when the deviation between the lane width and the predetermined width held in advance is larger than the predetermined threshold value, it is not considered that the left and right dividing line candidates are asymmetric. Thus, it is possible to appropriately recognize the parting line candidate at the point where the width of the traveling parting line changes significantly.

Second Embodiment
Next, with respect to the travel lane line recognition apparatus according to the second embodiment, differences from the travel lane line recognition device according to the first embodiment will be described.

  In the travel lane line recognition apparatus according to the second embodiment, the roadside object certainty factor calculation unit 24 calculates the lane line certainty factor of the lane line candidate lower as the extracted lane line candidate has the feature of the roadside object. The roadside object certainty factor of the dividing line candidate is calculated to be high. The roadside object certainty factor (object certainty factor) represents the certainty that the lane line candidate is a roadside thing. Furthermore, the roadside object certainty factor calculation unit 24 integrates the roadside object certainty factors calculated for each feature of the roadside thing, and calculates an integrated roadside item certainty factor.

  Further, as shown in FIG. 2, the traveling lane marking recognition apparatus according to the second embodiment includes the function of the roadside object recognition unit 31. The roadside object recognition unit 31 (target object recognition means) recognizes a division line candidate having a roadside object certainty factor calculated by the roadside object certainty factor calculation unit 24 higher than a second threshold value as a roadside thing.

  In addition, when the lane marking recognition unit 29 no longer recognizes the traveling lane marking, that is, when there is no marking line candidate whose integrated certainty factor exceeds the first threshold, the roadside article recognition unit 31 recognizes the roadside article. The lane line candidate is not recognized as a new traveling lane line. The higher the roadside object certainty factor of the lane line candidate, the lower the lane line certainty factor. Therefore, even when the original travel division line is not recognized, the division line candidate recognized as the roadside object is not recognized as the travel division line.

  Next, the processing procedure for recognizing the traveling lane lines according to the present embodiment will be described with reference to the flowchart of FIG. The processing procedure is repeatedly executed by the ECU 20 each time an image of one frame is taken by the on-vehicle camera 10.

  First, in S20 and S21, the same processing as S10 and S11 is performed. Subsequently, the roadside object certainty factor is calculated based on the characteristics of the roadside object for the lane line candidates extracted in S21 (S22). Subsequently, in S23 and S24, the same processing as S12 and S13 is performed.

  Subsequently, a lane line candidate whose roadside object certainty factor calculated in S22 is higher than the second threshold value is recognized as a roadside object (S25). That is, from the parting line candidates extracted in S21, the parting line candidate selected based on the feature of the roadside object is recognized as the roadside object.

  Subsequently, a division line candidate whose division line certainty factor calculated in S24 is higher than the first threshold value is recognized as a traveling division line (S26). That is, from the parting line candidates extracted in S21, the parting line candidate selected based on the features of the traveling parting line and the features of the roadside object is recognized as the traveling parting line. Then, based on the recognized travel division lines, the travel division line parameters are calculated, and the calculated travel division line parameters are output to the travel support device 40. Also, the width of the recognized travel lane is calculated, and the learning value is updated. This is the end of the process.

  According to the second embodiment described above, the following effects can be obtained.

  The lane line candidate recognized as a roadside object has a relatively low integrated certainty factor. Therefore, when the traveling parting line is not recognized based on the characteristics of the traveling parting line and the characteristics of the roadside thing, the parting line candidate recognized as the roadside thing is not recognized as a new traveling parting line. Therefore, even when the actual travel division line is blurred and the division line candidate corresponding to the actual travel division line is not extracted, the division line candidate corresponding to the roadside object is not recognized as a new travel division line. . Therefore, the recognition accuracy of the traveling lanes can be improved.

(Other embodiments)
The roadside object certainty factor calculation unit 24 may calculate the lane line certainty factor or the roadside object certainty factor based on the feature of at least one roadside thing. The features of the roadside may be used in combination as appropriate.

  In the second embodiment, the roadside object certainty factor calculation unit 24 may calculate only the roadside thing certainty factor based on the characteristics of the roadside thing, and may not calculate the dividing line certainty factor. In this case, the lane line candidate recognized as a roadside object is excluded from the recognition targets recognized as the traveling lane lines. In this way, even if the actual travel division line is blurred and no division line candidate corresponding to the actual travel division line is extracted, the division line candidate corresponding to the roadside object is recognized as a new travel division line. There is no Therefore, the recognition accuracy of the traveling lane lines can be improved.

  -The predetermined target object which becomes a disturbance factor when recognizing a traveling division line is not limited to a roadside object. The predetermined symmetrical object may be, for example, coal tar buried in a cracked portion of the road surface or a disturbance on the road surface such as a shadow on the road surface. Coal tar is extracted as a dividing line candidate because it appears to glow in the image. Further, when the shadow of the pipe-shaped guardrail as shown in FIG. 3 is on the road surface, the shadowed portion of the pipe becomes darker than the road surface. Therefore, the road surface sandwiched by the shadows of two parallel pipes is extracted as the dividing line candidate.

  When the disturbance factor on the road surface is also a predetermined object, in addition to the features of the roadside, the straight line shape of the traveling division line, the color information of the traveling division line, the luminance information of the traveling division line, etc. It is good. However, when the predetermined object is a disturbance factor on the road surface, the predetermined object is not at a high position from the road surface, so the ratio of the width of the division line candidate to the distance from the center in the width direction of the screen to the division line candidate Is not a feature of the predetermined object.

  10: In-vehicle camera, 20: ECU, 50: Vehicle.

Claims (11)

From an image taken by the vehicle (50) camera (10) mounted on, and candidate extracting means for extracting the lane line candidate that is a candidate of lane marking defining a lane of a road,
A first certainty factor calculating unit that calculates a certainty factor of the dividing line that is the dividing line of the dividing line candidate extracted by the candidate extraction unit for each feature of the dividing line;
Second confidence calculation that calculates the certainty of the parting line candidate of the parting line candidate lower as the parting line candidate has the feature of the predetermined target that is a disturbance factor when recognizing the parting line Means,
Integrating means for integrating the certainty factor by integrating the dividing line certainty factor calculated by the first certainty factor calculating means and the dividing line certainty factor calculated by the second certainty factor calculating means;
Partition line recognition unit that recognizes the partition line candidate having the integrated certainty factor calculated by the integration unit higher than a first threshold value as the partition line;
Road marking recognition device provided with From an image taken by the vehicle (50) camera (10) mounted on, and candidate extracting means for extracting the lane line candidate that is a candidate of lane marking defining a lane of a road,
Division line recognition unit that recognizes the division line candidate selected from the division line candidates extracted by the candidate extraction unit as the division line based on the characteristic of the division line;
An object that recognizes the division line candidate selected from the division line candidates extracted by the candidate extraction unit as the predetermined object, based on the characteristics of the predetermined object that is a disturbance factor when recognizing the division line And a recognition means,
The marking line recognition means does not recognize the marking line candidate recognized as the predetermined target by the object recognition means as a new marking line when the marking line is no longer recognized. Road marking line recognition device. A first certainty factor calculating unit that calculates a certainty factor of the dividing line that is the dividing line of the dividing line candidate extracted by the candidate extraction unit for each feature of the dividing line;
As the division line candidate has the feature of the predetermined object, the division line certainty factor which is the division line of the division line candidate is calculated to be lower, and the object certainty factor which is the predetermined object of the division line candidate Second confidence calculation means for calculating
Integrating means for integrating the certainty factor by integrating the dividing line certainty factor calculated by the first certainty factor calculating means and the dividing line certainty factor calculated by the second certainty factor calculating means;
The parting line recognition means recognizes the parting line candidate having the integrated certainty factor calculated by the integration means higher than a first threshold as the parting line.
The travel according to claim 2, wherein the object recognition means recognizes the division line candidate having the object certainty factor calculated by the second certainty factor calculation unit higher than a second threshold as the predetermined object. Lane marking recognition device.   3. The traveling parting line recognition apparatus according to claim 2, wherein the parting line recognition means excludes the parting line candidate recognized as the predetermined target by the object recognition means from recognition targets. A holding unit configured to hold the dividing line certainty factor calculated by the second certainty factor calculation unit for a predetermined time or a predetermined distance;
The integrated means calculates the integrated certainty factor using the parting line certainty factor held by the holding means when the parting line certainty factor is held by the holding means. The travel lane line recognition device according to 3. The image includes variation calculation means for calculating variation in color information or variation in luminance information of a predetermined area adjacent to the division line candidate extracted by the candidate extraction means in the image;
The travel division line according to any one of claims 1, 3 and 5, wherein the second certainty factor calculation means calculates the division line certainty factor lower as the variation calculated by the variation calculation means is larger. Recognition device. It has a determination means for determining whether the parting line candidate extracted by the candidate extraction means is a compound line,
The second certainty factor calculation means does not use the variation in color information or the variation in luminance information as the feature of the predetermined object when the determination means determines that the dividing line candidate is a compound line. The traffic lane line recognition device as described. The predetermined object is a roadside object of the lane,
A candidate width calculating unit configured to calculate the width of the dividing line candidate extracted by the candidate extracting unit;
The second certainty factor calculating means is configured such that the ratio of the width of the parting line candidate calculated by the candidate width calculating means to the distance from the center in the width direction of the image to the parting line candidate is larger. The travel lane line recognition apparatus according to any one of claims 1 to 5, wherein the lane line certainty factor is calculated to be low. Candidate width calculating means for calculating the width of the dividing line candidate extracted by the candidate extracting means;
And learning means for learning the width of the dividing line recognized by the dividing line recognition means,
The second certainty factor calculating means is configured to calculate the division as the deviation between the width of the dividing line candidate calculated by the candidate width calculating means and the learning value of the width of the dividing line learned by the learning means increases. The travel lane line recognition apparatus according to any one of claims 1, 3, 5 and 8, wherein the line certainty factor is calculated to be low.   The second confidence factor calculation unit is configured to determine the division if the division line candidate extracted by the candidate extraction unit on the right and left sides of the vehicle is asymmetrical with respect to the center of the lane on which the vehicle travels. The travel lane line recognition apparatus according to any one of claims 1, 3, 5 and 9, wherein the line certainty factor is calculated to be lower than a third threshold which is a value lower than the first threshold.   The second certainty factor calculation means extracts the section extracted by the candidate extraction means on the right and left sides of the vehicle when the deviation between the width of the lane and the predetermined width held in advance is larger than a predetermined deviation. The travel lane line recognition apparatus according to claim 10, wherein the line candidate is not characterized as being asymmetric as a feature of the predetermined object.