JP2013001298A - Monitoring device for vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To capture an image capable of being used for parking assist or surrounding observation during traveling and an image capable of being used for monitoring safety of vehicle surrounding by using cameras 12, 22 arranged at door mirrors 1, 2.SOLUTION: A monitoring device 100 for a vehicle includes the door mirrors 1, 2 mounted on a vehicle M and having housings H in which the cameras 12, 22, and mirror bodies 13, 23, are mounted and housing driving mechanisms 11, 21 for changing the directions of the housings H of the door mirrors 1, 2. The monitoring device 100 for the vehicle includes a control device 10. When the control device 10 allows the housing driving mechanisms 11, 21 to change the directions of the housings H corresponding to a vehicle state pattern determined by action information obtained from the vehicle, the control device 10 obtains action information including information of whether the engine of the vehicle is in on-state or in off-state, and corresponding to the vehicle state pattern determined by the obtained action information, the control device 10 allows the housing driving mechanisms 11, 21 to change the directions of the housings H of the door mirrors 1, 2.

Description

  The present invention relates to a vehicle monitoring device that monitors the surroundings of a vehicle using a camera provided on a door mirror of the vehicle.

  2. Description of the Related Art A navigation device that converts viewpoints of images from a plurality of cameras and displays a synthesized image on a monitor in a vehicle interior is known (Patent Document 1).

JP 2010-208483 A

  However, the conventional technology has a problem that each camera acquires an image with a field of view according to the purpose and cannot be used for other purposes. For example, a camera provided on a door mirror captures a road surface (downward) image for parking assistance and observation of the surroundings when traveling. Such a road surface (downward) image is suspicious when approaching a vehicle. Since it is impossible to capture an entire image of a tall object such as a person, it cannot be used for the purpose of monitoring the surroundings of the vehicle for the safety of the vehicle, and there is a problem that the purpose of use is limited.

  The problem to be solved by the present invention is that a camera provided on a door mirror can be used for parking assistance, observation of surroundings during traveling, monitoring of the surroundings of the vehicle, etc., depending on the state of the vehicle. Is to image.

  The present invention solves the above problem by changing the orientation of the housing of the door mirror of the vehicle in accordance with the vehicle state pattern determined from operation information such as whether or not the vehicle engine is on.

  According to the present invention, it is possible to change the imaging direction of the camera provided in the housing by changing the orientation of the housing of the door mirror of the vehicle according to the vehicle state pattern determined from the operation information of the vehicle. It is possible to acquire an image in the imaging direction suitable for the purpose of use according to the vehicle state pattern. As a result, using the camera provided in the housing of the door mirror, not only images suitable for parking assistance and observation of surroundings during traveling, but also images suitable for safety monitoring around the vehicle are acquired according to the state of the vehicle. be able to.

1 is a configuration diagram of a monitoring system including a vehicle monitoring apparatus according to an embodiment of the present invention. It is a figure which shows the example of installation of a door mirror. It is a 1st figure for demonstrating the drive operation of the housing of a door mirror. It is a 2nd figure for demonstrating the drive operation | movement of the housing of a door mirror. It is a 3rd figure for demonstrating the drive operation | movement of the housing of a door mirror. It is a flowchart figure which shows the control procedure of the vehicle monitoring system which concerns on embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the present embodiment, a case where the vehicle monitoring apparatus 100 according to the present invention is applied to a monitoring system 1000 capable of remote monitoring using an external terminal device 800 will be described as an example.

  FIG. 1 is a block configuration diagram of a monitoring system 1000 having a vehicle monitoring apparatus 100 according to the present embodiment. As shown in FIG. 1, the monitoring system 1000 of this embodiment includes a vehicle monitoring device 100, a vehicle controller 200, a communication device 700, and an external terminal device 800. The monitoring system 1000 can include an ignition switch 300 that can exchange information with the vehicle controller 200, a vehicle speed sensor 400, a positioning switch 500, and a steering angle sensor 600. Each of these devices is connected by a CAN (Controller Area Network) or other in-vehicle LAN, and can exchange information with each other.

  In the monitoring system 1000 of this embodiment shown in the figure, the vehicle monitoring device 100 can communicate with a mobile phone, a smartphone, or other external terminal device 800 (computer) via the communication device 700. The external terminal device 800 includes a communication device 810, an image processing device 820, and a display 830. The communication device 810 acquires a captured image from the vehicle monitoring device 100 side, and the image processing device 820 is necessary for display. The image 82 is displayed, and the display 821 displays the captured image. The user who owns the external terminal device 800 can check the captured image of the vehicle transmitted from the vehicle monitoring device 100 even at a remote location.

  As shown in the figure, the vehicle monitoring device 100 includes a right door mirror 1, a left door mirror 2 (sometimes collectively referred to as door mirrors 1 and 2, and the same hereinafter) and a control device 10.

  FIG. 2 is a diagram showing a right door mirror 1 and a left door mirror 2 installed in the vehicle. As shown in FIG. 2, the right door mirror 1 is provided on the right door of the vehicle M, and the left door mirror 2 is provided on the left door of the vehicle M. Although not shown, in addition to the right door mirror 1 and the left door mirror 2, cameras 32 and 42 can be provided at the rear of the vehicle or the front of the vehicle.

  FIG. 3 is a view of the right door mirror 1 as viewed from the front side of the vehicle. Since the left door mirror 2 appears symmetrically with the right door mirror 1, the illustration is omitted. As shown in FIG. 3, the camera 12 (22) is provided in the housing H of the right door mirror 1 (left door mirror 2) (the right camera 12 and the left camera 22 are also collectively referred to as cameras 12 and 22). The same applies below). The camera 12 (22) is attached so that the imaging direction thereof is directed to the lower side of the vehicle, that is, the traveling road surface side in normal times. The camera 12 (22) is configured using an imaging element such as a CCD (Charge Coupled Devices) and captures an image in a predetermined imaging direction. Although not particularly limited, a wide-angle camera 12 (22) can be used as the camera 12 (22) of the present embodiment.

  A right housing drive mechanism 11 including a motor that rotationally drives the housing H of each door mirror 1 (2) is provided inside the housing H of each door mirror 1 (2) of the present embodiment (the right housing drive mechanism 11 and The left housing drive mechanism 21 is generically referred to as housing drive mechanisms 11, 21, etc. The same applies hereinafter). Each housing drive mechanism 11 (21) of the present embodiment, when supplied with power in accordance with a drive command from the control device 10 or an input command from the mirror control switch, displays each housing H in the x-axis, y shown in the figure. The direction of each door mirror 1, 2 can be changed up, down, left, and right by being driven to rotate about the axis and the z axis. Incidentally, the x-axis is along the vehicle axle direction, the y-axis is along the vehicle length direction, and the z-axis is along the vehicle height direction (gravity direction) (the same applies to other drawings).

  Specifically, the direction of the right door mirror 1 shown in FIG. 3 can be changed by using each housing drive mechanism 11 (21) with the y axis as a rotation axis. Specifically, when the housing H is driven with the y-axis as the rotation axis, the portion indicated by the point Q in the housing H in FIG. 3 can be moved upward (z-axis side) along the trajectory q. That is, the imaging direction of the right camera 12 that has captured the downward direction (the road surface side: the z-axis downward direction in FIG. 3) is changed to the lateral direction of the vehicle M (the vehicle side side: the x-axis direction in FIG. 3). . That is, when the housing H is driven with the y-axis as the rotation axis, the optical axis of the right camera 12 is directed in the direction along the x-axis or in the direction having the x-axis direction component, and the lateral image of the vehicle M is captured. Can do.

  Further, as shown in FIG. 4, the housings H of the right door mirror 1 and the left door mirror 2 can be changed in direction with the z axis as a rotation axis by the housing drive mechanisms 11 and 21 provided in each housing H. When the housing H is driven with the z-axis as the rotation axis, the portion indicated by the point R in the housing H in FIG. 4 can be moved along the vehicle body width (x-axis side) along the track r. By this driving, the door mirrors 1 and 2 can be stored (folded to the vehicle body side).

  FIG. 5 is a view of the left door mirror 2 as seen from the rear side of the vehicle. Since the right door mirror 1 appears symmetrically with the left door mirror 2, the illustration is omitted. As shown in FIG. 5, the housing H of the left door mirror 2 (1) can be changed in direction about the x axis as a rotation axis by each housing drive mechanism 21 (11) provided in each housing H. When the housing H is driven with the x-axis as the rotation axis, a portion indicated by a point P at the lower end of the housing H in FIG. 6 is moved along the track p in the vehicle body length direction (the vehicle rear side along the y-axis). be able to. Of course, the point P can be moved to the lower end of the housing H in the opposite direction (the vehicle front side along the y-axis). That is, the imaging direction of the right camera 12 that has imaged the downward direction (the road surface side: the z-axis downward direction in FIG. 5) is changed to the front direction or the rear direction (y-axis direction in FIG. 5) of the vehicle M. That is, when the housing H is driven with the x axis as the rotation axis, the right camera 12 can capture a forward or backward image of the vehicle M.

  Each housing drive mechanism 21 (21) is not only in one direction but also in each housing H according to a drive command including one or more of an x-axis component, a y-axis component, and a z-axis component from the control device 10. Can be directed in any direction.

  As shown in the figure, the housing H of the left door mirror 2 (1) of the present embodiment is provided with a left mirror main body 23 (13) (the left mirror main body 23 and the right mirror main body are respectively connected to the mirror main bodies 13). The housings H of the present embodiment may be provided with a left mirror drive mechanism 24 (14) that changes the direction of the mirror surface of each mirror body 23 (13) (hereinafter, the same). The left mirror driving mechanism 24 and the right mirror driving mechanism 14 may be collectively referred to as mirror driving mechanisms 14, 24, etc. (the same applies hereinafter). By this left mirror drive mechanism 24 (14), the mirror surface of the left mirror main body 23 (13) can be moved up and down or left and right. As shown in FIG. 5, the left mirror drive mechanism 24 (14) can drive the left mirror main body 23 (13) to the left and right with the z axis passing through the center of the mirror surface as the rotation axis. Can be driven up and down with the z-axis passing through the axis as the rotation axis. That is, the mirror surface of the left mirror body 23 (13) is moved so that the left end or the right end of the mirror surface is pushed into the housing H with the z axis as a support shaft, and the upper end or the lower end of the mirror surface with the x axis as a support shaft. It can be moved to be pushed into H.

  The specific configuration and operation of each of the housing drive mechanisms 11 and 21 and / or the mirror drive mechanisms 14 and 24 described above are not particularly limited, and are used for a door mirror control system and a mirror control system known at the time of filing. The mechanism can be used as appropriate.

  Here, returning to FIG. 1, the control device 10 of the vehicle monitoring device 100 according to the present embodiment that controls the housing drive mechanisms 11 and 21 and the mirror drive mechanisms 14 and 24 described above will be described. The control device 10 executes a ROM (Read Only Memory) 12 in which a program for controlling the operations of the housing drive mechanisms 11 and 21 and the mirror drive mechanisms 14 and 24 is stored, and the program stored in the ROM 12. Thus, a CPU (Central Processing Unit) 11 as an operation circuit that functions as the vehicle monitoring device 100 and a RAM (Random Access Memory) 13 that functions as an accessible storage device are provided.

  Further, the CPU 11 of the control device 10 according to the present embodiment includes an image processing control unit (IPCU). The control device 10 uses the image processing control unit to analyze the captured images acquired from the cameras 12, 22, 32, and 42, extracts an image corresponding to the object from the captured data, and further extracts an object based on the extracted image. It is possible to calculate the change of the position of the object over time (the presence position with respect to the vehicle or the direction of presence with respect to the vehicle). For these image processes, a method known at the time of filing can be used.

  The control device 10 of the vehicle monitoring device 100 according to the present embodiment can execute each function by cooperation of software for realizing the control function and the hardware described above. In the present embodiment, the control device 10 will be described by taking an example in which the drive commands are sent to the housing drive mechanisms 11 and 21 and the mirror drive mechanisms 14 and 24. However, the control device 10 of the present embodiment is a vehicle controller. It is also possible to control the housing drive mechanisms 11 and 21 and the mirror drive mechanisms 14 and 24 through the control unit 200.

  Hereinafter, a housing drive control function, a mirror drive control function, a moving object detection function, and a transmission function realized by the control device 10 of the vehicle monitoring apparatus 100 will be described.

  First, the housing drive control function will be described. The control device 10 of the present embodiment provides the right door mirror 1 and / or the left door mirror 2 to the right housing drive mechanism 11 and / or the left housing drive mechanism 21 according to the vehicle state pattern determined from the operation information acquired from the vehicle. A drive command for changing the direction of the housing H is sent out.

  The vehicle operation information in the present embodiment includes one or more information among engine on / off information, vehicle shift position, vehicle speed, camera on / off, and vehicle steering angle. The control device 10 can acquire an on / off signal of the vehicle engine from the ignition switch 300 or an engine control device (not shown), can acquire the vehicle speed from the vehicle speed sensor 400, and positions the vehicle shift position. It can be acquired from the switch 500, a camera on / off signal can be acquired from the right camera 12 and the left camera 22, and the steering angle of the vehicle can be acquired from the steering angle sensor 600. The control device 10 according to the present embodiment can acquire the operation information via the vehicle controller 200.

  The control device 10 of the present embodiment acquires operation information including information on whether the vehicle engine is in an on state or an off state, and according to the vehicle state pattern determined from the acquired operation information, The housing drive mechanisms 11 and 21 can change the orientation of the door mirror housing. Although not particularly limited, the vehicle state pattern in the present embodiment includes a driving support mode in which the vehicle is driving, a parking support mode in which the vehicle is performing a parking operation, a passenger getting off and leaving the vehicle, and remotely A remote monitoring mode for viewing safety.

  Although not particularly limited, the control device 10 of the present embodiment acquires information (operation information) on whether the vehicle engine is in an on state or an off state via the vehicle controller 200, and this acquired operation. The vehicle state pattern is determined from the information. In the present embodiment, the control device 10 can determine that the vehicle state pattern is in the remote monitoring mode when the engine is in the off state. Further, when the engine is on, the control device 10 can determine that the vehicle state pattern is either the parking support mode or the travel support mode.

  The control device 10 of the present embodiment can cause the housing drive mechanisms 11 and 21 to change the orientation of the housing H of the door mirrors 1 and 21 according to the determined vehicle state pattern.

  As shown in Table 1 below, the control device 10 of the present embodiment can previously define a combination of operation information acquired from the vehicle side and a vehicle state pattern in the correspondence information T. The control device 10 can determine the vehicle state pattern from the acquired operation information with reference to the predefined correspondence information T.

  Specifically, when the control device 10 according to the present embodiment acquires the operation information corresponding to the information that the engine of the vehicle is in the off state and the content that the ignition switch is in the off state, Each housing drive mechanism 11 sends a drive command to change the orientation of the housing H of the door mirrors 1 and 2 so that the image pickup direction of 22 is higher than the image pickup direction of the cameras 12 and 22 when the engine is on. , 21. The upward direction in the present embodiment refers to a direction having a component in the direction (top) opposite to the mounting surface (road surface) of the vehicle when the horizontal plane when the vehicle is horizontally mounted is a reference. is there. In the example of FIG. 3, when the housing H of the door mirrors 1 and 2 is oriented upward, the movable part of the housing H moves to the + z direction side from the xy plane including the mounting position of the housing H. Specifically, the control device 10 rotates clockwise about the right door mirror 1 and moves about the left door mirror 2 so that the end including the point Q of the door mirrors 1 and 2 moves upward with at least the y axis as the rotation axis. Sends a drive command for executing an operation including a counterclockwise rotation operation to each housing drive mechanism 11, 21. Each housing drive mechanism 11, 21 drives the housing H of each door mirror 1, 2 in accordance with the drive command acquired from the control device 10. Note that the control device 10 can include either or both of the rotation component around the x axis and the rotation component around the z axis in the drive command including the rotation component around the y axis.

  When the housing drive mechanisms 11 and 21 rotate and drive the housing H based on a movement command including a rotation component around the y-axis, the direction of the imaging direction (optical axis) of the cameras 12 and 22 depends on the engine on state. Compared to the downward direction (road surface side: z-axis downward direction in FIG. 3), the horizontal direction (vehicle side side: x-axis direction in FIG. 3) changes. When the imaging direction of the cameras 12 and 22 attached to the door mirrors 1 and 2 is set to the lateral direction of the vehicle body, the surroundings of the vehicle body can be imaged from the height of the door mirrors 1 and 2, so that an object with a height around the vehicle Can be imaged (the whole body of the suspicious person). In addition, if an image of the surroundings of the vehicle body is taken from the height of the door mirrors 1 and 2, a suspicious person or the like can be captured at the center of the imaging region, so even if the cameras 12 and 22 are wide-angled, A clear image can be obtained. By the way, if the cameras 12 and 22 are facing downward, suspicious people around the vehicle are often caught near the boundary of the imaging region, so that the image quality of the image capturing the suspicious person is reduced, Although the size of the suspicious person existing near or far from the boundary is captured smaller than the actual size and the content of the video is difficult to understand, the cameras 12 and 22 are centered on the y axis as in this embodiment. Such inconvenience can be solved by rotating and imaging the surroundings of the vehicle body from the height of the door mirrors 1 and 2.

  Further, as shown in Table 1, the control device 10 according to the present embodiment acquires the operation information indicating that the engine is on and the shift position is reverse, and the vehicle state pattern is in the parking assistance mode. The direction of the housing H of the door mirrors 1 and 2 can be changed so that the imaging direction of each camera 12 and 22 faces downward (so as to be in the state of FIGS. 3 and 5). Specifically, the control device 10 sends a rotation drive command to each of the housing drive mechanisms 11 and 21 so that at least the x axis or the y axis is a rotation axis and the imaging direction of each camera 12 and 22 is downward. Each housing drive mechanism 11, 21 drives the housing H of each door mirror 1, 2 in accordance with the drive command acquired from the control device 10. Note that the control device 10 can include a rotation component around the z axis in a drive command including a rotation component around the x axis and a rotation component around the y axis.

  Furthermore, as shown in Table 1, the control device 10 of the present embodiment indicates that the engine is on, the shift position is other than reverse, and the vehicle speed is equal to or higher than a predetermined speed (for example, 10 km / h or higher). When the movement information is acquired, it is determined that the vehicle state pattern is the driving support mode, and the orientation of the housing H of the door mirrors 1 and 2 is changed so that the imaging direction of the cameras 12 and 22 is rearward. Can be made. Specifically, the control device 10 sends a rotation drive command to each of the housing drive mechanisms 11 and 21 so that at least the x axis is a rotation axis and the imaging direction of each camera 12 and 22 is rearward. Each housing drive mechanism 11, 21 drives the housing H of each door mirror 1, 2 in accordance with a drive command acquired from the control device 10. Note that the control device 10 can include a rotation component around the y axis and a rotation component around the z axis in the drive command including the rotation component around the x axis. In Table 1, the predetermined speed is 10 km / h or more and less than 10 km / h, but the predetermined speed as a threshold for determining whether the vehicle is running or parking is arbitrarily set. can do.

  In addition, as shown in Table 1, in the control device 10 of the present embodiment, the engine is on, the shift position is other than reverse, and the vehicle speed is less than a predetermined speed (for example, less than 10 km / h). When the operation information indicating that the cameras 12 and 22 are in the off state is acquired, the vehicle state pattern is determined to be the driving support mode, and the door mirror is set so that the imaging direction of the cameras 12 and 22 is the rear side. The direction of the housings 1 and 2 is changed. Further, in the control device 10 of the present embodiment, the engine is on, the shift position is other than reverse, the vehicle speed of the vehicle is less than a predetermined speed (for example, less than 10 km / h), and the cameras 12 and 22 are on. Is obtained, the vehicle state pattern is determined to be in the parking assist mode, and the orientation of the housing H of the door mirrors 1 and 2 is adjusted so that the imaging direction of the cameras 12 and 22 is downward. Change it. In either case, the vehicle is running at a low speed or stopped, but when the cameras 12 and 22 are operating, the parking support system is likely to be operating, and the parking support system is operating This is because it is preferable to provide an image captured in a downward imaging direction to assist the parking operation.

  Specifically, the control device 10 sends a rotation drive command to each of the housing drive mechanisms 11 and 21 so that at least the x axis is a rotation axis and the imaging direction of each camera 12 and 22 is rearward. Each housing drive mechanism 11, 21 drives the housing H of each door mirror 1, 2 in accordance with the drive command acquired from the control device 10. Note that the control device 10 can include a rotation component around the y axis and a rotation component around the z axis in the drive command including the rotation component around the x axis.

  Further, as shown in Table 1, in the control device 10 of the present embodiment, the engine is on, the shift position is other than reverse, and the vehicle speed is less than a predetermined speed (for example, less than 10 km / h), When the operation information indicating that the cameras 12 and 22 are in the off state is acquired, it can be determined that the driving support mode is in effect, but this state may be a state during a part of the operation in a series of parking operations. In this case, if the direction of the housing H is changed, the imaging direction of the cameras 12 and 22 is also changed, which is troublesome for a driver who performs a parking operation while viewing the images of the cameras 12 and 22. For this reason, in this embodiment, even when the driving support mode of the vehicle state pattern 3 in Table 1 is derived from the operation information, if the immediately preceding operation information indicates the parking support mode, the vehicle is in the parking operation. Therefore, the direction of the housing H is not changed.

  That is, the control device 10 of the present embodiment has acquired operation information that the engine is on, the shift position is other than reverse, the vehicle speed is less than a predetermined speed, and the cameras 12 and 22 are off. If the operation information acquired immediately before acquiring the operation information is the operation information indicating that the engine is on and the shift position is reverse (in the case of the vehicle state pattern 1), or the engine is on. In the state, the shift position is other than reverse, the vehicle speed is less than the predetermined speed, and the operation information indicates that the cameras 12 and 22 are in the ON state, the direction of the housing H of the door mirrors 1 and 2 Do not make any changes. Thereby, it can prevent that the imaging direction of the cameras 12 and 22 is changed in the middle of parking operation.

  The control device 10 of the present embodiment can consider the steering angle as the operation information when the shift position is reverse. As shown in Table 2 below, the control device 10 of the present embodiment can define a combination of operation information including the steering angle acquired from the vehicle side and the vehicle state pattern as correspondence information T in advance. The control device 10 can determine the vehicle state pattern from the acquired operation information with reference to the predefined correspondence information T.

  In the control device 10 of the present embodiment, when the operation information indicating that the engine is on, the shift position is reverse, and the steering angle of the vehicle is greater than or equal to a predetermined value is acquired, the vehicle state pattern is the driving support. The mode is determined, the direction of the housing H of the door mirrors 1 and 2 is changed so that the imaging direction of the cameras 12 and 22 is rearward, the engine is on, the shift position is reverse, When the operation information indicating that the steering angle of the vehicle is less than the predetermined value is acquired, it is determined that the vehicle state pattern is the parking assistance mode, and the door mirror 1 is set so that the imaging direction of the cameras 12 and 22 is downward. , 2 is changed in direction. Specifically, the control device 10 sends a rotational drive command to each housing drive mechanism 11, 21 so that at least the x axis is a rotational axis and the imaging direction of each camera 12, 22 is rearward or downward. To do. Each housing drive mechanism 11, 21 drives the housing H of each door mirror 1, 2 in accordance with the drive command acquired from the control device 10. Note that the control device 10 can include a rotation component around the y axis and a rotation component around the z axis in the drive command including the rotation component around the x axis.

  In the control considering the steering angle, the control device 10 can drive the housing H of only one of the right door mirror 1 and the left door mirror 2 in accordance with the direction of the steering angle. When acquiring the operation information indicating that the steering angle of the vehicle is rightward steering, the control device 10 changes the direction of the housing H of the right door mirror 1 on the right side of the vehicle so that the steering angle of the vehicle is left. When the operation information indicating that the steering is in the direction is acquired, the direction of the housing H of the left door mirror 2 on the left side of the vehicle can be changed. Thereby, only the door mirrors 1 and 2 that need to change the imaging direction of the cameras 12 and 22 can be driven.

  As described above, the control device 10 of the present embodiment causes the housing drive mechanisms 11 and 21 to change the orientation of the housing H of the door mirrors 1 and 21 in accordance with the vehicle state pattern determined from the vehicle operation information. When the orientation of the housing H changes, the orientation of the mirror bodies 13 and 23 also changes. However, there are cases where it is desired to change the imaging direction of the cameras 12 and 22 according to the vehicle state pattern, but not to change the orientation of the mirror bodies 13 and 23.

  In order to respond to this request, the control device 10 of the vehicle monitoring device 100 of the present embodiment has a mirror drive control function. The control device 10 collectively refers to the mirror drive mechanisms 14 and 24 (the right mirror drive mechanism 14 and the left mirror drive mechanism 24 based on the amount of change in the orientation of the housing H by the housing drive mechanisms 11 and 21. The same applies hereinafter. ) Can change the direction of the mirror surface of the mirror main body 13.23. Specifically, the control device 10 determines the housing based on a control command including a rotation drive shaft, a rotation drive direction, a rotation amount, and a rotation speed for changing the direction of the housing H sent to the housing drive mechanisms 11 and 21. A drive command including a rotation drive shaft, a rotation drive direction, a rotation amount, and a rotation speed that cancels the movement of the housing H is generated so that the movement of H does not affect the direction of the mirror bodies 13 and 23. It is preferable that the drive command for the mirror bodies 13 and 23 has such a content that the movement of the mirror bodies 13 and 23 can cancel the movement of the housing H. That is, when the drive command for the housing H and the drive command for the mirror main bodies 13 and 23 are executed, the control device 10 synchronizes the temporal movement of the housing H and the temporal movement of the mirror main bodies 13 and 23. Then, a drive command is generated so that the mirror surface positions of the mirror bodies 13 and 23 are maintained over time.

  For example, when the vehicle state pattern changes from the driving support mode to the parking support mode and from the parking support mode to the driving support mode, the control device 10 of the present embodiment changes the optical axes of the cameras 12 and 22 to the vehicle state. A drive command for directing in the corresponding imaging direction is sent to the housing drive mechanisms 11 and 21, and a drive command for maintaining the orientation of the mirror bodies 13 and 23 (a drive command for canceling the movement of the housing H). It is sent to each mirror drive mechanism 14, 24.

  Each mirror drive mechanism 14, 24 can keep the direction of the mirror bodies 13, 23 constant even when the direction of the housing H is changed by executing the drive command received from the control device 10. Thus, even if the orientation of the housing H is changed according to the vehicle state pattern, the orientation of the mirror bodies 13 and 23 is not changed, so that the driver can feel the situation around the vehicle reflected on the mirror bodies 13 and 23 without feeling uncomfortable. You can drive while checking.

  Next, the moving body detection function of the control apparatus 10 of this embodiment is demonstrated. When the vehicle state pattern is in the remote monitoring mode, the control device 10 according to the present embodiment can capture an image that tracks the detected moving object.

  The control device 10 according to the present embodiment can detect the moving body around the vehicle and the moving direction thereof based on the captured images of the cameras 12 and 22. As described above, the control device 10 of the present embodiment includes an image processing control unit (IPCU), and the control device 10 uses the image processing control unit and the camera 12 mounted on the vehicle. , 22, 32, etc., the image corresponding to the object is extracted from the imaging data, the movement of the object is tracked based on the extracted image, and the position of the object over time (vehicle Can be calculated).

  Moreover, the control apparatus 10 can calculate the presence direction of the moving body based on the position of the image corresponding to the moving body included in the captured image (the position on the image coordinates). The control device 10 calculates the imaging direction along the direction in which the moving object exists. And the control apparatus 10 calculates the imaging direction of the cameras 12 and 22 for imaging the presence direction of a moving body.

  The control device 10 acquires the operation information indicating that the engine is in the off state, and determines that the vehicle state pattern is in the remote monitoring mode, and if the moving body is detected, the detected movement A drive command for changing the direction of the housing H of the door mirrors 1 and 2 is generated according to the direction in which the body is present or the movement direction of the moving body, and is sent to the housing drive mechanisms 11 and 21. Each housing drive mechanism 11, 21 can track and image the moving body by driving the housing H of the door mirrors 1, 2 in accordance with a drive command. As a result, it is possible to take an image that automatically tracks the moving body during remote monitoring, so even if a danger occurs in the vehicle, the state of the vehicle can be accurately grasped remotely. Can be dealt with appropriately.

  Finally, the communication function of the control device 10 of the present embodiment will be described. The control device 10 of the present embodiment has a communication function with a terminal device having an external communication function, acquires operation information indicating that the vehicle engine is off, and the vehicle state pattern is in the remote monitoring mode. If it is determined, video data captured by the cameras 12 and 22 can be sent to the terminal device 800 outside the vehicle. The terminal device 800 causes the image processing device 820 to process video data received by the communication device 810 and display the data on the display 830. As a result, the owner of the vehicle can check the situation of his / her vehicle by video even at a position away from the vehicle.

  Next, a control procedure of the monitoring system 1000 according to the present embodiment will be described based on the flowchart in FIG.

  First, in step 11, the control device 10 of the vehicle monitoring apparatus 100 acquires vehicle operation information from the vehicle controller 200 at a predetermined cycle, and in step 12, determines a vehicle state pattern based on the operation information. In the present embodiment, the vehicle state pattern is determined from the operation information based on correspondence information T (see Tables 1 and 2) in which the relationship between the operation information and the vehicle state pattern is defined in advance.

  In step 13, the control device 10 generates a drive command for the housing H according to the vehicle state pattern. This drive command includes information on the rotation direction (rotation direction), rotation amount, and rotation speed of the rotation axis (x, y, z) of the housing H.

  In subsequent step 14, control device 10 generates a drive command for mirror bodies 13 and 23 based on the drive command for housing H generated in step 13. This drive command includes information on the rotation direction (x, y, z), rotation amount, and rotation speed of the mirror bodies 13 and 23H.

  In step 15, the control device 10 sends the drive command for the housing H generated in step 13 to the housing drive mechanisms 11 and 21. In step 16, the control device 10 controls the mirror main bodies 13 and 23 generated in step 14. A drive command is sent to the mirror drive mechanisms 14 and 24.

  In step 17, the housing drive mechanisms 11 and 21 drive the housing H based on the drive command sent in step 15.

  Similarly, in step 18, the mirror drive mechanisms 14, 24 drive the mirror bodies 13, 23 based on the drive command sent in step 16. Since the driving of the mirror bodies 13 and 23 is synchronized with the driving of the housing H over time, the mirror surface positions (orientations) of the mirror bodies 13 and 23 can be maintained while changing the orientation of the housing H.

  When the control device 10 determines that the vehicle state pattern is in the remote monitoring mode (step 19), the process proceeds to step 20, and the video is transmitted to the external terminal device 800 of the remote user. In step 20, the control device 10 detects the position and direction of the moving body based on the images taken by the cameras 12 and 22. As described above, a known method can be appropriately used as a method for detecting information about a moving object from an image.

  In step 21, the control device 10 changes the direction of the housing H so that the imaging direction of the cameras 12 and 22 provided with the housing H matches the direction of existence of the moving body according to the detected direction of the moving body. A drive command to be changed is generated and sent to the housing drive mechanisms 11 and 21. The housing drive mechanisms 11 and 21 drive the direction of the housing H in accordance with this drive command. When the housing H is driven, the optical axes of the cameras 12 and 22 can be aligned with the direction in which the moving body exists, so that the cameras 12 and 22 can image the moving body.

  In step 22, the control device 10 transmits the video captured by the cameras 12 and 22 to the external terminal device 800. The external terminal device 800 displays the received video on the display 830 and presents the situation around the vehicle to the user.

  The processing after step 20 is continued until the remote monitoring mode is canceled (for example, until the ignition key is turned on and the engine starts driving).

  Since this invention is comprised as mentioned above and acts as mentioned above, there exist the following effects.

  According to the vehicle monitoring device 100 and the monitoring system 1000 of the present embodiment, the housing H is changed by changing the orientation of the housing H of the door mirrors 1 and 2 of the vehicle according to the vehicle state pattern determined from the operation information of the vehicle. Since the imaging directions of the cameras 12 and 22 provided in the camera can be changed, an image in the imaging direction according to the vehicle state pattern can be acquired. As a result, by using the cameras 12 and 22 provided in the housing H, not only images suitable for parking assistance and observation of the surroundings during traveling, but also images suitable for safety monitoring around the vehicle according to the state of the vehicle. Can be acquired.

  For example, the vehicle monitoring apparatus 100 of the present embodiment changes the orientation of the housing H of the door mirrors 1 and 2 according to the vehicle state pattern corresponding to the operation information indicating whether the engine is on or off. When the engine is on, an image suitable for parking assistance and surrounding observation during traveling can be obtained, and when the engine is off, an image suitable for safety monitoring around the vehicle can be obtained.

  The vehicle monitoring apparatus 100 of the present embodiment causes the mirror drive mechanisms 14 and 24 to change the mirror surface orientations of the mirror bodies 13 and 23 based on the amount of change in the orientation of the housing H by the housing drive mechanisms 11 and 21. Even when the housing H is driven, the orientation of the mirror bodies 13 and 23 can be kept constant. Thus, even if the orientation of the housing H is changed according to the vehicle state pattern, the orientation of the mirror bodies 13 and 23 is not changed, so that the driver can feel the situation around the vehicle reflected on the mirror bodies 13 and 23 without feeling uncomfortable. You can drive while checking.

  Since the vehicle monitoring apparatus 100 of the present embodiment uses one or more information among the vehicle speed, the shift position, the on / off of the cameras 12 and 22 and the steering angle of the vehicle as the operation information, the vehicle state Can be accurately determined. In other words, from these motion information, it is accurately determined whether an image suitable for parking assistance and observation of surroundings during driving is required in the current vehicle situation or an image suitable for safety monitoring around the vehicle. can do.

When the vehicle monitoring apparatus 100 according to the present embodiment acquires operation information indicating that the engine is off, the imaging direction of the cameras 12 and 22 is that of the cameras 12 and 22 when the engine is on. By changing the direction of the housing H of the door mirrors 1 and 2 so as to be upward from the imaging direction, the direction of the imaging direction (optical axis) of the cameras 12 and 22 is downward when the engine is on. In comparison, it can be changed horizontally. By setting the imaging direction of the cameras 12 and 22 attached to the door mirrors 1 and 2 to the lateral direction of the vehicle body, the surroundings of the vehicle body can be imaged from the height of the door mirrors 1 and 2, so that the height around the vehicle is It is possible to take an image of the entire object (the suspicious person's whole body).
In addition, if an image of the surroundings of the vehicle body is taken from the height of the door mirrors 1 and 2, a suspicious person or the like can be captured at the center of the imaging region, so even if the cameras 12 and 22 are wide-angled, A clear image can be obtained.

  The vehicle monitoring apparatus 100 according to the present embodiment can determine that the vehicle is in the parking state when the operation information indicating that the engine is on and the shift position is reverse is obtained. By changing the direction of the housing H of the door mirrors 1 and 2 so that the image capturing direction of the camera is directed downward, an image suitable for parking assistance can be captured.

  In the vehicle monitoring apparatus 100 according to the present embodiment, when the engine is on, the shift position is other than reverse, and operation information indicating that the vehicle speed is equal to or higher than a predetermined speed is acquired, the vehicle travels normally. Since it can be determined that the camera is in a state, it is possible to capture an image suitable for driving support by changing the orientation of the housing H of the door mirrors 1 and 2 so that the imaging direction of the cameras 12 and 22 is rearward. it can.

  The vehicle monitoring apparatus 100 according to the present embodiment operates to indicate that the cameras 12 and 22 are in an off state when the engine is on, the shift position is other than reverse, and the vehicle speed is less than a predetermined speed. When the information is acquired, the direction of the housing H of the door mirrors 1 and 2 is changed so that the imaging direction of the cameras 12 and 22 is rearward, while the operation that the cameras 12 and 22 are in an on state. When the information is acquired, the direction of the housing of the door mirror is changed so that the imaging direction of the cameras 12 and 22 is downward. When the cameras 12 and 22 are in the on state, it is determined that there is a high possibility that a parking assistance program is being executed, and an image suitable for parking assistance can be captured.

  The vehicle monitoring apparatus 100 according to the present embodiment acquires operation information indicating that the engine is on, the shift position is other than reverse, the vehicle speed is less than a predetermined speed, and the camera 12.22 is off. Even if it is determined that the vehicle state pattern is the driving support mode, the direction of the housing H of the door mirrors 1 and 2 is changed when the vehicle state pattern determined immediately before is the parking support mode. Since it does not perform, it can prevent that the imaging direction of the cameras 12 and 22 is changed in the middle of parking operation.

  The vehicle monitoring apparatus 100 according to the present embodiment obtains operation information indicating that the engine is on, the shift position is reverse, and the steering of the vehicle when it is determined that the vehicle state pattern is the parking assist mode. When motion information indicating that the angle is greater than or equal to a predetermined value is acquired, the direction of the housing H of the door mirrors 1 and 2 is changed so that the imaging direction of the cameras 12 and 22 is rearward, and the vehicle is steered. When the operation information indicating that the angle is less than the predetermined value is acquired, the direction of the housing H of the door mirrors 1 and 2 is changed so that the imaging direction of the cameras 12 and 22 is downward. When the vehicle is turned significantly, an image that can confirm the state of the rear direction is taken, and when the vehicle goes straight (Parallel parking), an image that can confirm the state of the down direction (road surface direction) is taken. Rukoto can.

  When the vehicle monitoring apparatus 100 according to the present embodiment acquires operation information indicating that the steering angle of the vehicle is steering in the right direction, the vehicle monitoring apparatus 100 changes the direction of the housing H of the door mirror 1 on the right side of the vehicle. When the operation information indicating that the steering angle is leftward steering is obtained, the direction of the housing H of the door mirror 2 on the left side of the vehicle is changed, so that the door mirror 1 in the direction (left or right) that needs to be confirmed. , 2 can be driven only.

  The vehicle monitoring apparatus 100 according to the present embodiment detects the moving body from the images of the cameras 12 and 22 and changes the direction of the door mirror housing H in accordance with the direction in which the moving body exists or the moving direction. The tracked video can be acquired.

  In the remote monitoring mode, the vehicle monitoring apparatus 100 according to the present embodiment sends the images captured by the cameras 12 and 22 to the external terminal device 800, so that the owner of the vehicle can perform his / herself even at a position away from the vehicle. The situation of the vehicle can be confirmed on the video.

  It should be noted that all the embodiments described above are described for facilitating the understanding of the present invention, and are not described for limiting the present invention. Therefore, each element disclosed in the above embodiment is intended to include all design changes and equivalents belonging to the technical scope of the present invention.

  In this specification, the vehicle monitoring apparatus 100 and the monitoring system 1000 will be described as an example of the vehicle monitoring apparatus according to the present invention, but the present invention is not limited to this.

  Moreover, in this specification, as one aspect | mode of the monitoring apparatus for vehicles which concerns on this invention, the mirror which changes the direction of the mirror drive direction of the housing drive mechanisms 11 and 21 and the mirror main bodies 13 and 23 which change the direction of the cameras 12 and 22 The vehicle monitoring device 100 including the control device 10 including the CPU 11, the ROM 12, and the RAM 13 that can control the drive mechanisms 14 and 24 will be described as an example, but is not limited thereto.

  In the present specification, as one aspect of the vehicle monitoring apparatus according to the present invention having a housing drive control means, a mirror drive control means, a moving body detection means, and a transmission means, a housing drive control function and a mirror drive control are provided. Although the vehicle monitoring device 100 having the control device 10 having the function, the moving body detection function, and the transmission function will be described, the present invention is not limited to this.

1000 ... Monitoring system 100 ... Vehicle monitoring device M ... Vehicle 10 ... Control device 11 ... CPU
12 ... ROM
13 ... RAM
DESCRIPTION OF SYMBOLS 200 ... Vehicle controller 300 ... Ignition switch 400 ... Vehicle speed sensor 500 ... Positioning switch 600 ... Steering angle sensor 700 ... Communication apparatus 800 ... External terminal device 900 ... Communication line

Claims (12)

A door mirror having a housing attached to a vehicle and having a camera and a mirror body attached thereto;
A housing drive mechanism for changing the orientation of the housing of the door mirror;
Housing drive control means for causing the housing drive mechanism to change the orientation of the housing according to a vehicle state pattern determined from operation information acquired from the vehicle,
The housing drive control means acquires operation information including information on whether an engine of the vehicle is in an on state or an off state, and according to a vehicle state pattern determined from the acquired operation information, A vehicle monitoring apparatus, wherein a housing driving mechanism is configured to change a direction of a housing of the door mirror. The vehicle monitoring device according to claim 1,
A mirror drive mechanism for changing the direction of the mirror surface of the mirror body;
A vehicle monitoring apparatus, further comprising: mirror drive control means for causing the mirror drive mechanism to change the direction of the mirror surface of the mirror body based on a change amount of the housing direction by the housing drive mechanism. The vehicle monitoring device according to claim 1 or 2,
The housing drive control means is configured to provide the housing drive mechanism with the door mirror based on one or more operation information of the vehicle speed, the shift position, the on / off of the camera, and the steering angle of the vehicle. A vehicle monitoring device characterized in that the orientation of a housing is changed. In the monitoring apparatus for vehicles as described in any one of Claims 1-3,
When the housing drive control means acquires the operation information indicating that the engine is in the off state, the imaging direction of the camera is upward from the imaging direction of the camera when the engine is in the on state. Thus, the direction of the housing of the door mirror is changed. The vehicle monitoring device according to claim 4,
The housing drive control means, when acquiring the operation information that the engine is on and the shift position is reverse, the orientation of the housing of the door mirror so that the imaging direction of the camera is downward The vehicle monitoring device characterized by changing the above. The vehicle monitoring device according to claim 4 or 5,
When the housing drive control means acquires operation information indicating that the engine is on, the shift position is other than reverse, and the vehicle speed of the vehicle is equal to or higher than a predetermined speed, the imaging direction of the camera is A vehicular monitoring device, wherein the orientation of the housing of the door mirror is changed so as to be rearward. In the monitoring device for vehicles according to any one of claims 4 to 6,
The housing drive control means obtains operation information indicating that the engine is on, the shift position is other than reverse, the vehicle speed of the vehicle is less than a predetermined speed, and the camera is off. Change the orientation of the housing of the door mirror so that the imaging direction of the camera is the rear side,
The housing drive control means obtains operation information indicating that the engine is on, the shift position is other than reverse, the vehicle speed of the vehicle is less than a predetermined speed, and the camera is on. Is a vehicle monitoring device that changes the direction of the housing of the door mirror so that the imaging direction of the camera is downward. The vehicle monitoring device according to claim 7,
The housing drive control means, when the engine is on, the shift position is other than reverse, the vehicle speed of the vehicle is less than a predetermined speed, and the operation information that the camera is off is acquired,
The operation information acquired immediately before acquiring the operation information is operation information indicating that the engine is on and the shift position is reverse, or the engine is on and the shift position is other than reverse. When the vehicle speed of the vehicle is less than a predetermined speed and the operation information indicates that the camera is in an on state, the orientation of the door mirror housing is not changed. apparatus. In the monitoring device for vehicles according to any one of claims 4 to 8,
The housing drive control means includes
When the operation information indicating that the engine is on, the shift position is reverse, and the steering angle of the vehicle is greater than or equal to a predetermined value is acquired, the imaging direction of the camera is set to the rear side , Change the direction of the door mirror housing,
When the operation information indicating that the engine is on, the shift position is reverse, and the steering angle of the vehicle is less than a predetermined value is acquired, the imaging direction of the camera is downward. A monitoring device for a vehicle, wherein the orientation of a door mirror housing is changed. The vehicle monitoring device according to claim 9, wherein
When the housing drive control means acquires the operation information indicating that the steering angle of the vehicle is steering in the right direction, the housing drive control means changes the orientation of the housing of the right door mirror of the vehicle,
The vehicle monitoring apparatus, wherein when the operation information indicating that the steering angle of the vehicle is leftward steering is acquired, the direction of the housing of the left door mirror of the vehicle is changed. In the vehicle monitoring device according to any one of claims 1 to 10,
A moving body detecting means for detecting a moving body around the vehicle and a moving direction thereof based on a captured image of the camera;
The housing drive control means obtains the operation information indicating that the engine is in an off state, and when the moving body detection means detects a moving body, the imaging direction of the camera is detected movement. A vehicle monitoring apparatus, wherein the direction of the housing of the door mirror is changed so as to face the direction of the body or the direction of movement of the moving body. In the vehicle monitoring device according to any one of claims 1 to 11,
A transmission means having a communication function with a terminal device having an external communication function;
The transmission unit transmits an image captured by the camera to a terminal device outside the vehicle when the operation information indicating that the engine of the vehicle is in an off state is acquired. Monitoring device.

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