KR101076984B1 - Lane Departure Warning apparatus using multiple laser beams - Google Patents

Abstract

The present invention relates to a device for recognizing a lane of a road surface using a laser, and more particularly, to irradiate a plurality of laser beams to a road surface at different separation distances, and to compare the relative number of laser beams that are reflected after the road surface is irradiated. A lane departure prevention apparatus for determining a distance between a lane and a vehicle by determining whether a specific laser beam of a plurality of laser beams is positioned above a lane based on a change in intensity.

The lane departure prevention apparatus according to the present invention calculates the distance between the lane and the vehicle by identifying the plurality of laser beams reflected from the road surface by the distance after irradiating a plurality of laser beams to the road surface at different distances from the vehicle The distance between the lane and the vehicle can be calculated. In addition, the lane departure prevention apparatus according to the present invention uses a low-cost laser and recognizes the lane based on the relative intensity change of the laser beam reflected from the road surface, so that the lane can be easily searched at low cost.

Lane departure, drowsy driving, safe driving, lane recognition

Description

Lane Departure Warning apparatus using multiple laser beams

The present invention relates to a device for recognizing a lane of a road surface using a laser, and more particularly, to irradiate a plurality of laser beams to a road surface at different separation distances, and to compare the relative number of laser beams that are reflected after the road surface is irradiated. The lane departure prevention apparatus for determining the distance between the lane and the vehicle based on the intensity change.

In recent years, studies are being actively conducted to prevent accidents by warning the driver by predicting potential accidents while driving away from post-safety measures such as seat belts or airbags that minimize the driver's damage from various accidents occurring while driving the vehicle. Is going on.

In general, ASV (Advanced Safety Vehicle) is an advanced vehicle that applies advanced electronic and control technology to improve the safety of the vehicle. It reduces traffic accidents, increases traffic volume, saves energy, and facilitates driver's convenience. Lane Departure Warning System (LDWS) is an ASV that detects lanes in which a vehicle is currently running, and alerts you if a driver attempts to leave the lane due to carelessness or drowsy driving. to be.

Lane departure warning systems currently in use or being developed are mainly using optical instruments such as CCD cameras. This system is focused on the fact that the shape and color of the center line and the driving line is different from the shape and color of the road surface.The system analyzes the image data captured by the CCD camera to determine the centrality or lane, and then invades the center line or stops the lane. In case of departure, the driver will be alerted. Furthermore, intelligently developed vehicles have also been proposed to identify lanes and to drive themselves while maintaining lanes.

The structure of the conventional LDWS (hereinafter referred to as 'prior art 1') includes an image sensor unit which receives forward and backward driving images, an image processor which performs image processing for lane recognition, and whether the vehicle is separated based on the recognized lane. It is composed of a departure determination unit for determining, an interface input unit for receiving a vehicle interface (Interface) signal, and an interface output unit for indicating the lane departure warning and the situation. At this time, the vehicle interface is composed of various variables such as lane width, lane curvature radius, lane crossing time. Here, the image sensor unit recognizes the lane on the road by using a plurality of cameras installed in the front and rear center, and detects the difference between the detected lane center and the camera optical axis to generate a lane departure warning.

On the other hand, the lane departure warning system disclosed in Korean Patent Laid-Open No. 10-2008-0088675 (hereinafter referred to as 'Prior Art 2') uses a lane from a left and right image input by a plurality of cameras installed in both side mirrors. 3D mapping of the extracted left and right lanes to obtain the actual coordinates of the lanes, calculating the left and right direction angles at the intersections of the straight lines made up of the actual coordinates of the lanes with the direction lines of the vehicle bodies, and calculating the direction lines and the lanes. Calculate the left and right side distances from a straight line consisting of the actual coordinates, calculate the lane departure distance by geometrical analysis of the direction angle and the side distance, and calculate the departure time from the vehicle speed detected by the vehicle speed sensor and the lane departure distance. If the time is less than the reference value, an alarm is generated to prevent a vehicle accident due to lane departure.

Meanwhile, the lane departure warning system disclosed in JP 20-2000-0015809 (hereinafter referred to as `` Prior Art 3 '') alerts the driver after judging the intrusion of the center line by a relatively simple and inexpensive configuration without using a CCD camera. A device for generating a laser beam, comprising: a laser beam transmitter mounted on a vehicle (preferably to the left of the vehicle front) to emit a laser beam at a predetermined angle toward the lower side of the vehicle; The laser beam receiver mounted on the right side of the transmitter and receiving the laser beam returned after the emitted laser beam is reflected on the road, a laser driver for driving the laser beam transmitter and the laser beam receiver, and the state of the center line, lanes and road surface Look-up table that stores the intensity data of the received laser beam according to The central control unit receives the intensity data of the received laser beam from the driver and inquires the intensity data of the received laser beam received from the look-up table to determine whether the current vehicle has invaded the center line and to generate an alarm when the center line is invaded. It is configured to include.

The above-described prior art 1 and the prior art 2 use the CCD camera disposed in the vehicle to photograph the road around the vehicle and process the image of the photographed road to recognize the lane, and use various variables calculated from the recognized lane. To determine whether the vehicle has left the lane. Therefore, expensive equipment for processing complex processes such as CCD camera, image processing unit, lane recognition unit, and lane departure determination unit using various variables is required.It is difficult to quickly calculate lane departure in real time in a fast moving vehicle. Has the problem.

Meanwhile, the related art 3 detects a lane by comparing the intensity of the laser beam reflected from the road surface and the intensity of the laser beam along the lane, which is pre-stored in the lookup table. It is possible to determine whether the departure. However, due to the presence of sunlight, the headlights of surrounding vehicles, or ambient lighting around the moving vehicle, the intensity of the background light received by the surrounding environment of the vehicle is different from each other, and thus the laser according to the lane stored in the lookup table is simply different. It is difficult to accurately determine the lane using only the strength of the signal. In addition, one of the most important factors in the lane departure warning system is the distance between the lane and the vehicle. According to the configuration of the related art 3, the distance between the lane and the vehicle cannot be measured only by determining whether the vehicle has passed through the lane. I have a problem.

Accordingly, an object of the present invention is to provide a lane departure prevention apparatus that can be manufactured with a relatively simple configuration and low cost.

Another object of the present invention is to provide a lane departure prevention apparatus capable of not only detecting a lane but also measuring a distance between the lane and the vehicle.

Another object of the present invention is to provide a lane departure prevention apparatus having a function of determining the water film state of the road by using a laser having a different rate of attenuation for water.

The lane departure prevention apparatus according to the present invention includes a laser irradiation unit for irradiating a plurality of laser beams at different separation distances from a vehicle by a virtual irradiation line on a road surface, and a plurality of reflections on the road surface after being irradiated on the road surface at different separation distances. A lane based on a laser receiver for receiving a laser beam of a laser beam, a laser identification unit for distinguishing the plurality of received laser beams according to the irradiated separation distance, and a separation distance of a laser beam causing a relative change in intensity among the received plurality of laser beams And a lane determination unit for calculating a distance between the vehicle and the vehicle.

Preferably, the laser irradiator irradiates a plurality of laser beams with a virtual irradiation line formed in a direction perpendicular to the driving direction of the vehicle, and the laser irradiator irradiates a plurality of laser beams modulated at different frequencies from different distances from the vehicle. It is characterized by.

The lane determination unit may include: an intensity change search unit for searching for a laser beam causing relative intensity change among the plurality of laser beams received based on the received laser beam intensity; a lane identification unit for identifying a lane based on relative intensity change of the laser beam; And a lane distance calculation unit that calculates a distance between the identified lane and the vehicle based on the searched distance of the laser beam.

Preferably, the lane distance calculation unit calculates a distance between the lane and the vehicle as a lane exists between the laser beam searched and the laser beam closest to the laser beam searched in the vehicle direction, or the distance of the searched laser beam. It is characterized by calculating the distance between the lane and the vehicle.

Preferably, the vehicle departure prevention apparatus according to the present invention is reflected after irradiating the water film detection laser light emitting unit and the road surface irradiated with the road surface a moisture detection laser having a different moisture attenuation rate relative to the laser beam irradiated from the laser light emitting unit The water film determination unit may further include a water film determination unit configured to determine a water film formation state on the road surface based on the difference in intensity between the water film detection laser and the plurality of laser beams.

The lane departure prevention apparatus according to the present invention has various effects as follows as compared with the conventional lane departure prevention apparatus.

First, the lane departure prevention apparatus according to the present invention, after irradiating a plurality of laser beams to the road surface at different distances from the vehicle to identify a plurality of laser beams reflected from the road surface by the separation distance to determine the distance between the lane and the vehicle By calculating, the distance between the lane and the vehicle can be calculated.

Second, the lane departure prevention apparatus according to the present invention uses a low-cost laser and recognizes the lane based on the relative intensity change of the laser beam reflected from the road surface, so that the lane can be easily searched at low cost.

Third, the lane departure prevention apparatus according to the present invention can monitor the water film formed on the road by measuring the relative reception intensity of the laser having a different rate of attenuation for moisture.

Hereinafter, a lane departure prevention apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

1 illustrates an example in which a lane departure prevention apparatus according to the present invention is mounted on a vehicle.

Referring to Figure 1 in more detail, the lane departure prevention apparatus 20 according to the present invention is predetermined of the vehicle 10 that can irradiate the laser beam to the road 40 of the lane in which the vehicle 10 currently runs Installed at the location. Preferably, the lane departure prevention apparatus 20 according to the present invention is installed on the left or right side of the vehicle so that the laser beam can be irradiated to the lane 30 displayed on the road surface when driving the road, more preferably It is installed in the left or right front.

The lane departure prevention apparatus 20 irradiates a plurality of laser beams 23 at different separation distances d from the vehicle 10 by a virtual irradiation line of a road surface to measure the distance between the vehicle 10 and the lane, or Then, the film is irradiated with a water film detection laser beam for detecting the water film formation state of the road surface on which the vehicle 10 runs. Preferably, the lane departure prevention device 20 is characterized by irradiating a plurality of laser beams 23 with a virtual irradiation line formed in a direction perpendicular to the driving direction of the vehicle 10. Preferably, the lane departure prevention apparatus 20 is characterized in that for irradiating the water film detection laser to the road surface on which the vehicle 10 runs.

The plurality of laser beams 23 irradiated at different separation distances with the virtual irradiation line formed on the road surface are irradiated onto the road surface at different irradiation angles θ _i . The plurality of laser beams 23 irradiated onto the road surface at different irradiation angles θ _i are reflected by the road surface and received by the lane departure preventing apparatus 20 again.

When the vehicle departure prevention apparatus according to the present invention is largely divided into functional units, the unit 100 irradiates a plurality of laser beams to the road surface and a plurality of laser beams reflected from the road surface to receive the distance between the lane and the vehicle. It is comprised by the unit 200 to calculate. 2 is a functional block diagram for explaining the laser irradiation unit 100 in more detail, and FIG. 3 is a functional block diagram for explaining the unit 200 for calculating the distance between the lane and the vehicle in more detail.

First, the laser irradiation unit 100 will be described in more detail with reference to FIG. 2. The laser irradiation unit 100 emits a plurality of laser beams for measuring the distance between the modulation control unit 110 and a vehicle and a lane. The laser light emitting unit 120 and the water film detecting laser light emitting unit 130 for irradiating a laser beam for detecting the water film state of the road surface on which the vehicle travels are provided. The laser emitter 120 includes a plurality of laser emitters 1, 2,.. N that respectively irradiate a laser beam from a vehicle to road surfaces of different distances. The laser beam irradiated from the plurality of laser emitters 1, 2,..., N has a different attenuation rate for moisture compared to the laser beam irradiated from the water film sensing laser emitter 130. Preferably, the laser beam irradiated from the plurality of laser emitters 1, 2,..., N has a low attenuation rate for moisture compared to the laser beam irradiated from the water film sensing laser emitter 130.

Meanwhile, the modulation controller 110 modulates and controls the plurality of laser beams irradiated from the laser light emitters 120 and the water film detection laser beam irradiated from the water film detection laser light emitter 130. On the road surface on which the vehicle travels, there are various noise lights generated from sunlight, headlights of other vehicles traveling around, lane changing lights, etc., and these noise lights mainly consist of a DC component or a low frequency component. The modulation controller 110 may generate a plurality of laser beams irradiated from the laser light emitter 120, and may be generated by the laser emitters 120 so that the ambient noise light and the plurality of irradiated laser beams may be distinguished from each other. Modulation control of a plurality of laser beams. In addition, the modulation controller 110 modulates the water film detection laser beam generated by the water film detection laser light emitter 130 so that the water film detection laser beam irradiated from the water film detection laser light emitter 130 can be distinguished from the ambient noise light. To control. Preferably, the modulation control unit 110 modulates a plurality of laser beams generated by the laser light emitter 120 and the water film detection laser beams generated by the water film detection laser light emitter 130 in a high frequency band. Preferably, the modulation controller 110 pulse-modulates the plurality of laser beams generated by the laser light emitter 120 and the water film detection laser beam generated by the hydrofilm detection laser generator 130 at different frequencies.

The plurality of laser light emitting units 1, 2,.. N constituting the laser light emitting unit 120 are virtual irradiation lines formed on the road surface to prevent vehicle departure from each other so that the laser beams can be irradiated at different distances from the vehicle. It is fixedly placed in a housing (not shown) of the device.

Referring to FIG. 3, the unit 200 for calculating the distance between the lane and the vehicle will be described in more detail. The unit 200 for calculating the distance between the lane and the vehicle receives a laser beam reflected from the road surface and returned. Each of the modulation frequency of the laser receiver 210 and the plurality of laser beams irradiated by the high frequency modulation from the laser light emitting unit 120 (hereinafter referred to as a 'distance measurement laser beam') and the high frequency modulated laser beams are irradiated. A storage unit 220 which stores information on the separation distance from the vehicle and information on the modulation frequency of the water film detection laser beam irradiated with high frequency modulation by the water film detection laser light emitting unit 130, and modulation of the received laser beam. The laser identification unit 230 that identifies the laser beam based on the frequency, and searches for the lane based on the change in intensity of the received laser beam for distance measurement. Lane determination unit 240 for calculating the distance between the water, and the water film determination unit 250 for determining the water film formation state of the road based on the difference in the received intensity of the received water film detection laser beam and the received distance measuring laser beam. And a warning controller 260 that warns the user of lane departure or drowsiness driving or warns the user of the formation of a road mandrel based on the calculated distance between the lane and the vehicle.

Looking at the laser receiver 210 in more detail with reference to Figures 4 and 5, the laser receiver 210 is mixed with the laser receiver 211, the received laser signal to receive the laser signal reflected back from the road surface AC coupling unit 213 for removing a DC component signal, filtering unit 215 for filtering the frequency band of the multiple laser beam for distance measurement or the frequency band of the water film detection laser beam from the AC-coupled laser signal and the filtered An analog-digital converter 217 for converting an analog laser signal into a digital value is provided.

The first graph shown in FIG. 5 (a) shows the intensity of the received laser beam without the DC component mixed. The second graph shown in FIG. 5 (a) shows the headlights of the surrounding vehicles mixed. The intensity of the receiving laser beam is shown and the third graph shown in FIG. 5 (a) shows the intensity of the receiving laser beam mixed with sunlight. The headlights of sunlight or surrounding vehicles act as DC components of constant size. Meanwhile, the first to third graphs shown in FIG. 5 (b) show a laser beam AC-coupled by removing DC components from the first to third graphs shown in FIG. 5 (a). .

Referring to FIG. 3 again, the unit 200 for calculating the distance between the lane and the vehicle will be described in more detail. The laser identification unit 230 may store the laser light emitting unit 120 stored in the storage unit 220. Received laser beams are respectively identified based on information on modulation frequency bands of the plurality of laser beams to be irradiated or information on modulation frequencies of the water film detection laser beams irradiated by the water film detection laser light emitting unit 130. In the laser light emitting unit 120, the plurality of distance measuring laser beams are irradiated at different distances from the vehicle, and the plurality of distance measuring laser beams irradiated at different distances is modulated at different frequencies.

The lane determination unit 240 includes an intensity change search unit 241 for searching for a laser beam causing a change in relative intensity among the plurality of distance measuring laser beams based on the received intensity of the laser beam for distance measurement, and the searched laser beam. A lane identification unit 243 for identifying a lane on a road surface based on a relative change in intensity of the beam, and a distance between the identified lane and a vehicle based on a separation distance of a laser beam for distance measurement causing a change in relative intensity. The lane distance calculation part 245 is provided. The road surface is paved with asphalt, cement, etc., and various kinds of white or yellow lanes are marked on the paved road surface. When the laser is irradiated to the road surface, the laser beam is reflected at a stronger intensity on the road surface where the lane is displayed than on the road surface where the lane is not displayed. The intensity change searching unit 241 searches for a laser beam causing a relative intensity change among the plurality of distance-measuring laser beams received, and the lane identifying unit 243 is a position where the laser beam causing the relative intensity change is irradiated, that is, a laser beam. It is determined that the lane exists at a distance from the vehicle to which the beam is irradiated.

The water film determination unit 250 determines the water film formation state of the road based on the difference in the received intensity between the received water film detection laser beam and the received distance measuring laser beam, and the water film detection laser beam irradiated from the water film detection laser light emitting unit. The attenuation rate with respect to moisture is higher than that of the laser beam for distance measurement irradiated from the laser light emitting unit. Therefore, as shown in FIG. 6A, when the water film is not formed on the road 300, the intensity R1 reflected by the distance measuring laser beam S1 from the road 300 and the water film detection laser The intensity R2 of the beam S2 reflected by the road 300 is the same. However, as shown in FIG. 6 (b), when the water film 310 is formed on the road 300, the attenuation rate for the water of the distance measuring laser beam is relatively small compared to the water film detection laser beam, thereby measuring the distance. The intensity R3 of the laser beam R1 reflected by the water film 310 is greater than the intensity R4 of the water film detection laser beam S2 reflected by the water film 310.

The warning controller 250 may provide a warning signal for notifying the driver of lane departure or drowsiness driving based on the distance between the lane identified by the lane identification unit 243 and the lane calculated by the lane distance calculation unit 245 and the vehicle. Or warning signal to indicate the formation of water film on the road.

FIG. 7 illustrates an example of a laser beam for multiple distance measurement, which is irradiated by being modulated at different frequencies by the laser light emitter 120, and FIGS. 7 to 10 are reflected by a road surface and received by the laser receiver 210. Several examples of multiple distance measuring laser beams are shown.

First, an example of the laser beam for multiple distance measurement irradiated from the laser light emitter 120 will be described in detail with reference to FIG. 7. As shown in FIG. Pulse width modulated with S1 and period T1. As shown in FIG. 7B, the second laser beam of the plurality of laser beams is pulse-width modulated with an intensity S2 and a period T2. As shown in FIG. 7C, the third laser beam of the plurality of laser beams is pulse-width modulated with an intensity S3 and a period T3.

Referring to FIG. 8, an example of a laser beam for measuring multiple distances received by the laser receiver 210 will be described. The laser beam illustrated in FIG. 8A may be a first laser beam illustrated in FIG. 7A. The laser beam is reflected and received after being irradiated to this road surface. The laser beam shown in FIG. 8 (b) shows the laser beam received by being reflected after the second laser beam shown in FIG. 7 (b) is irradiated onto the road surface. The laser beam shown in FIG. 8 (c) shows the laser beam received by being reflected after the third laser beam shown in FIG. 7 (c) is irradiated onto the road surface. As shown in FIGS. 8A to 8C, only the intensity of the first laser beam of the first to third laser beams received by the laser receiver 210 is changed. Accordingly, the lane identification unit 243 determines that the lane exists at the irradiation distance of the first laser beam, and the lane distance calculation unit 245 calculates the distance between the lane and the vehicle based on the irradiation distance of the first laser beam. do.

Referring to another example of the laser beam for multiple distance measurement received by the laser receiver 210 with reference to FIG. 9, the laser beam shown in FIG. 9 (a) is the first laser beam shown in FIG. 7 (a). The laser beam is reflected and received after being irradiated to this road surface. The laser beam shown in FIG. 9 (b) shows the laser beam received and reflected after the second laser beam shown in FIG. 7 (b) is irradiated onto the road surface. The laser beam shown in FIG. 9 (c) shows the laser beam received by being reflected after the third laser beam shown in FIG. 7 (c) is irradiated onto the road surface. As shown in FIGS. 9 (a) to 9 (c), only the intensity of the second laser beam among the first to third laser beams received by the laser receiver 210 is changed. Accordingly, the lane identification unit 243 determines that the lane exists at the irradiation distance of the second laser beam, and the lane distance calculation unit 245 calculates the distance between the lane and the vehicle based on the irradiation distance of the second laser beam. do.

Looking at another example of the laser beam for multiple distance measurement received by the laser receiver 210 with reference to FIG. 10, the laser beam shown in FIG. 10 (a) is the first laser shown in FIG. 7 (a). The laser beam is reflected and received after the beam is irradiated to the road surface. The laser beam shown in FIG. 10 (b) shows the laser beam received after being reflected after the second laser beam shown in FIG. 7 (b) is irradiated onto the road surface. The laser beam shown in FIG. 10 (c) shows the laser beam received by being reflected after the third laser beam shown in FIG. 7 (c) is irradiated onto the road surface. As shown in FIGS. 10A to 10C, only the intensity of the third laser beam among the first to third laser beams received by the laser receiver 210 is changed. Accordingly, the lane identification unit 243 determines that the lane exists at the irradiation distance of the third laser beam, and the lane distance calculation unit 245 calculates the distance between the lane and the vehicle based on the irradiation distance of the third laser beam. do.

FIG. 11 illustrates an example of a separation distance to which a plurality of distance measuring laser beams are irradiated.

As shown in Fig. 11A, the laser light emitting unit irradiates the first to fifth laser beams to the road surface. The first laser beam is irradiated at a distance farthest from the vehicle, and the second to fifth laser beams are sequentially irradiated at a close distance from the vehicle. The separation distance between the first to fifth laser beams is equal to d1.

As shown in Fig. 11 (b), the laser light emitting unit irradiates the first to fifth laser beams to the road surface. The first laser beam is irradiated at a distance farthest from the vehicle, and the second to fifth laser beams are sequentially irradiated at a close distance from the vehicle. The separation distance between the first laser beam and the second laser beam is d2, the separation distance between the second laser beam and the third laser beam is d3, and the separation distance between the third laser beam and the fourth laser beam is d4, and the fourth The separation distance between the laser beam and the fifth laser beam is d5. The separation distance between the multiple laser beams irradiated with the imaginary radiation increases sequentially from the vehicle.

Referring to FIG. 11B, referring to an example of calculating a distance between a lane and a vehicle by the lane distance calculator 245, the lane distance calculator 245 finally receives a second signal from the lane identifier 243. If the lane is identified by the laser beam and the lane is not currently identified by the first to fifth laser beams, the lane is calculated to exist between the second laser beam and the third laser beam closest in the vehicle direction d3. .

Referring to another example of calculating the distance between the lane and the vehicle in the lane distance calculation unit 245 with reference to FIG. 11B, the lane distance calculation unit 245 finally receives a second signal in the lane identification unit 243. If the lane is identified by the laser beam and the lane is not currently identified by the first to fifth laser beams, the separation distance d3 + d4 + d5 of the second laser beam which finally identified the lane is determined between the lane and the vehicle. Calculate by distance.

12 is a flowchart illustrating an example in which a warning controller outputs a warning signal to a driver based on a distance between a vehicle and a lane. Referring to FIG. 11, the distance between the lane and the vehicle may be calculated. S1), the speed of change of the distance between the vehicle and the lane is calculated based on the calculated distance between the lane and the vehicle (S3). It is determined whether the calculated distance change speed between the lane and the vehicle is equal to or greater than the first threshold value TH1 (S5). When it is determined that the calculated distance change speed between the lane and the vehicle is equal to or greater than the first threshold value TH1, it is determined whether the distance between the lane and the vehicle is equal to or less than the second threshold value TH2 (S7). When the distance change speed between the lane and the vehicle is greater than or equal to the first threshold value TH1 and the distance between the lane and the vehicle is less than or equal to the second threshold value TH2, the controller 100 outputs a warning signal to the user (S17). The warning signal is output as a warning sound to the driver through the speaker installed in the vehicle or as a warning message to the driver through the display installed in the vehicle.

What has been described above is only an exemplary embodiment of the lane departure prevention apparatus according to the present invention, and the present invention is not limited to the above-described embodiment, and as claimed in the following claims, it departs from the gist of the present invention. Without this, anyone skilled in the art to which the present invention pertains will have the technical spirit of the present invention to the extent that various modifications can be made.

1 illustrates an example in which a lane departure prevention apparatus according to the present invention is mounted on a vehicle.

2 is a functional block diagram for explaining the laser irradiation unit 100 in more detail.

3 is a functional block diagram for describing in more detail the unit 200 for calculating a distance between a lane and a vehicle.

4 is a functional block diagram illustrating the laser receiver in more detail.

5 illustrates a laser signal received through a laser receiver.

FIG. 6 illustrates a reflection state of a distance measuring laser beam and a water film detection laser beam depending on whether a water film is formed on a road.

FIG. 7 illustrates an example of a plurality of laser beams that are irradiated by being modulated at different frequencies by the laser irradiator 100.

8 to 10 illustrate various examples of the multiple laser beams reflected by the road surface and received by the laser receiver 210.

11 illustrates an example of a separation distance at which multiple laser beams are irradiated.

12 is a flowchart illustrating an example in which a warning controller outputs a warning signal to a driver based on a distance between a vehicle and a lane.

Description of the main parts of the drawing

10: vehicle 20: lane departure prevention device

30: road surface 40: lane

100: laser irradiation unit 110: modulation control unit

120: laser light emitting unit 200: lane distance calculation unit

210: laser receiver 220: storage unit

230: laser identification unit 240: lane determination unit

241: strength change determination unit 243: lane identification unit

245: lane distance calculation unit 250: water film determination unit

260: warning control unit

Claims (10)

A laser light emitting unit for irradiating a plurality of laser beams at different distances from the vehicle by a virtual irradiation line on a road surface; A modulation controller for modulating the plurality of laser beams at different frequencies in order to distinguish them from each other; A laser receiver configured to receive a plurality of laser beams reflected from the road surface after being irradiated onto the road surface at different distances; A laser identification unit for discriminating and identifying the irradiated plurality of laser beams according to a separation distance based on the received modulation frequencies of the plurality of laser beams; An intensity change searcher searching for a laser beam causing a relative change in intensity among the plurality of received laser beams based on the received intensity of the laser beam; A lane identification unit for identifying a lane based on a change in relative intensity of the laser beam; And And a lane distance calculator configured to calculate a distance between the identified lane and the vehicle based on the retrieved distance of the laser beam. The method of claim 1, wherein the laser irradiation unit And a plurality of laser beams are irradiated to the virtual irradiation line formed in a direction perpendicular to the driving direction of the vehicle. delete delete The method of claim 1, wherein the lane distance calculation unit And a lane exists between the searched laser beam and the laser beam closest to the searched laser beam in a vehicle direction, thereby calculating a distance between the lane and the vehicle. The method of claim 1, wherein the lane distance calculation unit The lane departure prevention apparatus, characterized in that for calculating the distance of the searched laser beam as the distance between the lane and the vehicle. The method of claim 1, And the distance between the separation distances of the plurality of laser beams irradiated with the virtual irradiation line increases sequentially from the vehicle. According to claim 1, wherein the lane departure prevention apparatus And a warning controller configured to output a warning signal to a driver based on the determined distance between the vehicle and the lane. The method of claim 8, wherein the warning control unit Based on the type of the determined lane and the distance between the determined vehicle and the lane, the speed change distance between the vehicle and the lane is equal to or less than a first threshold, and the distance between the vehicle and the lane is equal to or less than a second threshold. Lane search apparatus for generating a beep. According to claim 1, wherein the lane departure prevention apparatus A water film detection laser light emitting unit for irradiating a moisture detection laser having a different water attenuation rate relative to the laser beam irradiated from the laser light emitting unit to a road surface; And And a water film determination unit configured to determine a water film formation state of the road surface based on a difference in intensity between the water film detection laser and the plurality of laser beams which are reflected after the road surface is irradiated.

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