JP2007062429A - Step learning system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform suspension control for a step properly by performing the suspension control by corresponding to reliability of position information in a learned step area. <P>SOLUTION: This step learning system has a step detection means for detecting a step on a road, a storage means for storing step information in the step area detected by the step detection means together with reliability information of the step information, and a step control means for controlling a step based on the step information in the step area stored in the storage means and changing amount of control in accordance with the reliability information. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a step learning system.

2. Description of the Related Art Conventionally, there has been provided a vehicle suspension control device capable of performing suspension control in accordance with road condition data provided by the navigation device in a vehicle equipped with the navigation device (for example, Patent Document 1). reference.). In this case, it is determined whether there is a step on the road based on the database, and the hardness of the suspension is controlled. Learning is also performed in which vertical acceleration, which is input from the suspension, is acquired, whether there is a step on the road based on the acquired vertical acceleration, and recorded in a database. That is, the actual suspension control result is compared with the predicted control content, and the content of the database is corrected based on the comparison result.
JP 2000-318634 A

  However, in the conventional suspension control device, where the position of the step to be learned depends on the accuracy of the current position detected by the navigation device, the current position detected by the navigation device includes an unavoidable error. The position of the stepped portion may not match the actual stepped position. Therefore, when suspension control is performed based on the learned result, the suspension state changes at a position different from the actual step position, and the driver or passenger of the vehicle feels uncomfortable.

  The present invention solves the above-mentioned conventional problems, and performs suspension control according to the reliability of the learned position information of the step area so that the suspension can be appropriately controlled with respect to the step. The purpose is to provide a learning system.

  For this purpose, in the step learning system of the present invention, a step detecting means for detecting a road step, and a storage means for storing step information of the step area detected by the step detecting means together with reliability information of the step information, And a step control means for performing step control based on the step information of the step area stored in the storage means and changing the control amount in accordance with the reliability information.

  According to the present invention, suspension control is performed according to the reliability of the learned position information of the step area. Therefore, suspension control can be appropriately performed for the step.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 2 is a block diagram showing the configuration of the level difference learning system in the embodiment of the present invention.

  As shown in the figure, the step learning system in the present embodiment controls a navigation device 10 as a traveling environment information output unit that outputs vehicle traveling environment information as road information, and a vehicle suspension (suspension device). A suspension control device 20 as a control unit and a suspension unit 30 are provided. Here, the vehicle may be of any type as long as it can travel on a road such as a passenger car, a truck, a bus, or a two-wheeled vehicle. A case where the vehicle is provided with two wheels will be described. It is assumed that the suspension unit 30 is attached to each of the four wheels.

  Reference numeral 11 is a GPS (Global Positioning System) sensor, 12 is a gyro sensor that detects the rotational angular velocity of the vehicle, that is, a turning angle, 13 is a vehicle speed sensor that detects the vehicle speed, and 14 is a vehicle acceleration sensor. G sensor.

  Here, the navigation device 10 includes a calculation means such as a CPU and an MPU, a storage means such as a semiconductor memory and a magnetic disk, a CRT, a liquid crystal display, an LED (Light Emitting Diode) display, a display means such as a laser hologram, a touch panel, a remote A controller, input means such as a push button switch, a communication interface and the like are provided. In addition to the GPS sensor 11, the gyro sensor 12, the vehicle speed sensor 13, and the G sensor 14, the navigation device 10 includes a steering sensor that detects the steering angle of the vehicle operated by the driver, A winker sensor that detects the operation of the winker as a direction indicator, an accelerator sensor that detects an accelerator opening operated by the driver, a brake sensor that detects movement of a brake pedal of the vehicle operated by the driver, and weight information of the vehicle You may provide the vehicle weight sensor, geomagnetic sensor, distance sensor, beacon sensor, altimeter, etc. which are acquired. In this case, the GPS sensor 11 detects the current position on the earth by receiving radio waves transmitted from a GPS satellite (not shown), and the geomagnetic sensor detects the direction in which the vehicle is facing by measuring the geomagnetism. The distance sensor detects a distance between predetermined positions on the road. The beacon sensor receives position information from beacons arranged along the road and detects a current position. Then, the navigation device 10 is based on signals from the GPS sensor 11, the gyro sensor 12, the vehicle speed sensor 13, the G sensor 14, etc., the current position of the vehicle, the heading direction of the vehicle, the speed of the vehicle, The moving distance is detected.

  The storage means of the navigation device 10 includes a map data file, an intersection data file, a node data file, a road data file, and a facility information data file in which information on facilities such as hotels and gas stations in each region is stored. The map database unit 15 is provided. Further, the storage means includes information related to steps on the road detected by the suspension control device 20, that is, step information and data for searching for a route, along the searched route on the screen of the display means. A storage media unit 19 for storing various data for displaying a guide map, displaying a distance to the next intersection, a traveling direction at the next intersection, and other guidance information is provided. The storage media unit 19 also stores various data for outputting predetermined information as audio. The storage means includes all forms of storage media such as magnetic tape, magnetic disk, magnetic drum, flash memory, CD-ROM, MD, DVD-ROM, optical disk, MO, IC card, optical card, and memory card. It is also possible to use a removable external storage medium.

  The intersection data file stores intersection data, the node data file stores node data, and the road data file stores road data. The road data is displayed by the intersection data, node data, and road data. Displayed on the screen. The intersection data includes the type of intersection, that is, whether the intersection is a traffic signal lamp or an intersection where a traffic signal lamp is not installed. The node data constitutes at least the position and shape of the road in the map data recorded in the map data file, and includes actual road branch points (including intersections, T-junctions, etc.), node points And data indicating a link connecting the node points. Further, the node point indicates at least the position of a road bending point.

  The road data includes the width, gradient, cant, altitude, bank, road surface condition, number of road lanes, points where the number of lanes decreases, points where the width becomes narrower, etc. Contains data. In the case of a highway or a main road, each lane in the opposite direction is stored as separate road data and processed as a double road. For example, in the case of a main road having two or more lanes on one side, it is processed as a two-way road, and the lane in the upward direction and the lane in the downward direction are each stored in the road data as independent roads. The corner includes data such as a radius of curvature, an intersection, a T-junction, and a corner entrance. Further, the road attributes include data such as railroad crossings, expressway entrance rampways, expressway toll gates, downhill roads, uphill roads, road types (national roads, major local roads, general roads, highways, etc.).

  Further, the communication interface of the navigation device 10 communicates with the suspension control device 20 and transmits / receives various data to / from the FM transmitter, telephone line network, Internet, mobile phone network, and the like. For example, various data such as road information such as traffic jams, traffic accident information, and D-GPS information for detecting a detection error of the GPS sensor 11 received by an information sensor (not shown) is received.

  The navigation device 10 includes a current position detection unit 16 that detects a current position of the vehicle, a step area calculation processing unit 17 that executes a step area calculation process based on information about the step detected by the suspension control device 20, and A step information notification processing unit 18 that executes a step information notification process for notifying the suspension control device 20 of information about a step on the road ahead of the traveling direction of the vehicle is provided. Furthermore, the navigation device 10 has a learning request counter (not shown) as a counter that counts the number of learning requests transmitted at the same point. The navigation device 10 performs basic processing such as search for a route to a destination, travel guidance in the route, determination of a specific section, search for points, facilities, and the like, in the same manner as a normal vehicle navigation device. The map is displayed on the screen of the display means, and the current position of the vehicle, the route from the current position to the destination, guidance information along the route, etc. are displayed on the map. The guidance information may be output as a sound by a sound generation means. The navigation device 10 functions as current position specifying means for specifying the current position of the vehicle. In addition, the navigation device 10 determines the shape of a corner or the like (including an intersection, a T-junction, a highway entrance / exit rampway, etc.) positioned in front of the vehicle in the traveling route of the vehicle, a recommended approach speed to the corner, Recognize driving environment information. Then, the traveling environment information is transmitted to the suspension control device 20.

  The suspension control device 20 includes arithmetic means such as a CPU and MPU, storage means such as a semiconductor memory and a magnetic disk, a communication interface, and the like. The suspension control device 20 is communicably connected to the navigation device 10 via a communication network such as an in-vehicle LAN (Local Area Network) as a body communication network disposed in the vehicle. The suspension control device 20 includes a step detection processing unit 21 that executes a step detection process for detecting a step on the road, and a damping force control unit 25 as a suspension characteristic control unit that controls the characteristics of the suspension unit 30. Have

  The step detection processing unit 21 is connected to the step detection sensor 22 and detects that the vehicle has traveled on the step based on the detection signal of the step detection sensor 22. The step detection sensor 22 is, for example, a vertical acceleration sensor, and detects the vertical acceleration of the vehicle as an acceleration in which the sprung portion that is the vehicle body side portion of the suspension unit 30 moves in the vertical direction. Note that the G sensor 14 of the navigation device 10 and a vehicle height sensor (not shown) can also be used as the step detection sensor 22. Then, the step detection processing unit 21 extracts a high-frequency component of the vertical acceleration with a bandpass filter, and determines that the vehicle has traveled on the step if it is greater than or equal to a predetermined threshold (threshold) value. When the detected vertical acceleration has a low frequency, it can be considered that it is not caused by a step, but by road surface undulations, so that it is not determined that the vehicle has traveled on the step.

  The damping force control unit 25 is connected to a vehicle speed sensor 26 that detects the speed of the vehicle and a steering sensor 27 that detects the steering angle of the steering of the vehicle operated by the driver, and the vehicle speed sensor 26 and the steering sensor 27 The characteristics of each suspension unit 30 are controlled based on the detection signal and the step information acquired from the step information notification processing unit 18 of the navigation device 10. Note that the vehicle speed sensor 13 and the steering sensor of the navigation device 10 can also be used as the vehicle speed sensor 26 and the steering sensor 27. Further, the damping force control unit 25 may control any characteristic of the suspension unit 30. For example, the damping force control unit 25 may control the value of the spring rate (spring constant or spring rate) of the spring member. A case where the damping force as a characteristic of the suspension unit 30 is controlled will be described. The damping force may be controlled by any method, but here, by driving an actuator built in the hydraulic damper 34 of each suspension unit 30 and rotating the orifice switching type damping variable valve, It is assumed that the diameter of the orifice in the oil flow path is changed.

  Here, the suspension unit 30 has one end rotatably attached to the vehicle body, the other end attached to a hub member or the like that supports the axle, a wheel support device such as an upper arm 31 and a lower arm 32, and a coil spring 33. And a shock absorber comprising a damper such as a hydraulic damper 34. The wheel support device and the shock absorber shown in the figure are merely examples, and the suspension unit 30 may have any type of wheel support device and shock absorber. The hydraulic damper 34 shown in the figure is a damping force variable damper with a built-in actuator. The suspension unit 30 transmits control status information to the suspension control device 20. In the example shown in the figure, the suspension control device 20 has an independent configuration, but the functions of the suspension control device 20 can be attached to the suspension unit 30.

  In the present embodiment, the step learning system includes a step detection unit, a storage unit, a comparison unit, a storage processing unit, and a step control unit from the viewpoint of function. The level difference detecting means detects a level difference on the road, and includes functions such as a level difference detection processing unit 21 and a level difference detection sensor 22. The storage means stores the step information of the step area detected by the step detection means together with the reliability information of the step information, and includes the function of the storage media unit 19 and the like. Further, the comparison means compares the step information of the step area stored in the storage means with the step information of the step area detected by the step detection means. The current position detection unit 16 and the step area calculation process The function of the part 17 etc. is included. Further, the storage processing unit corrects the step information of the step area stored in the storage unit based on the comparison result by the comparison unit, and includes a current position detection unit 16, a step area calculation processing unit 17, and the like. Includes functionality. Further, the step control means performs the step control based on the step information of the step area stored in the storage means, and changes the control amount according to the reliability information. The damping force control unit 25, The functions of the suspension unit 30 and the like are included.

  Next, the operation of the level difference learning system having the above-described configuration will be described.

  FIG. 1 is a diagram showing an operation for correcting position information of a stepped area in an embodiment of the present invention, FIG. 3 is a diagram showing an operation for combining learning requests in the embodiment of the present invention, and FIG. 4 is an implementation of the present invention. It is a figure which shows the operation | movement of the same spot determination in the form of.

  When the vehicle travels on a step on the road, for example, by reducing the damping force, the characteristics of the suspension unit 30 can be changed to a soft setting, that is, a soft setting, thereby improving the riding comfort. . However, even if the characteristics of the suspension unit 30 are changed after detecting that there is a level difference, it will not be in time, so a sufficient effect cannot be obtained. Therefore, in order to obtain a sufficient effect, it is necessary to change the characteristics of the suspension unit 30 to a soft setting in advance. In order to change the characteristics of the suspension unit 30 in advance, step information is stored in advance in the map database unit 15 of the navigation device 10, and based on the step information and the current position of the vehicle, the vehicle travels forward. It may be possible to determine that there is a step within the predetermined distance range, but creating a map data file or road data file that stores step information on all the steps on the road is expensive, and the file Since the storage capacity of the system becomes enormous, it is practically difficult. In addition, it is conceivable to detect a step within a predetermined distance range ahead of the traveling direction of the vehicle with an imaging device such as a camera attached to the vehicle or a radar device such as a millimeter wave radar. That will be costly.

  Therefore, in the present embodiment, when the suspension control device 20 detects a step, a signal indicating that the step has been detected is transmitted to the navigation device 10 as a learning request, and the step area detected by the navigation device 10 in response to the learning request. Are stored in the storage media unit 19 for learning. The step area is a range where a step exists on the road. The step information is information relating to a step area including position information of a start point and an end point of the step area.

  When the step information is stored in the storage media unit 19 and travels on a road having the corresponding step area, the navigation device 10 transmits the stored step information of the step area to the suspension control device 20 in advance. Therefore, the suspension control device 20 can change the characteristics of the suspension unit 30 to a soft setting in advance based on the step information received from the navigation device 10. In this case, as described above, the cost does not increase and the storage capacity of the file does not become enormous, and the riding comfort can be improved.

  By the way, when a plurality of learning requests from the suspension control device 20 are transmitted at short intervals, the navigation device 10 stores the step information of the step area detected in response to all the learning requests as it is in the storage media unit 19, When the suspension control device 20 changes the characteristics of the suspension unit 30 based on the stored step information of the step area, the characteristics of the suspension unit 30 change at short intervals, so that the driver and passengers of the vehicle feel uncomfortable. End up. Further, the storage data stored in the storage media unit 19 increases, and the storage capacity of the storage media unit 19 is compressed.

  Therefore, in the present embodiment, step area integration processing for integrating adjacent step areas is performed, and as shown in FIG. 3, when the interval between the learning request areas as the detected step areas is short, a plurality of steps are integrated. The learning area is created as a stepped area where the learning areas are collectively learned. The step area is a section where a step exists on the road, and its length is measured along the traveling direction of the vehicle. In FIG. 3, the horizontal axis represents the distance along the traveling direction of the vehicle, and the vertical axis represents the presence or absence of a learning request transmitted from the suspension control device 20. Line A indicates a learning request, line B indicates a learning area, and C indicates a value for which the learning request is present. A1 to A5 indicate learning request areas as detected step areas, and B1 and B2 indicate learning areas as learned step areas. Then, assuming that a plurality of learning requests from the suspension control device 20 are transmitted at short intervals as shown in FIG. 3A, the navigation device 10 has a learning area as shown in FIG. B1 and B2 are created and stored in the storage media unit 19. That is, as in the learning request areas A1 to A3, when the interval between adjacent learning request areas is less than a preset threshold, for example, less than 30 [m], a single learning area is created by integration. . Further, as in the learning request areas A3 and A4, the integration is not performed when the interval between adjacent learning request areas is equal to or greater than a threshold value. As a result, a learning area B1 in which the learning request areas A1 to A3 are integrated and a learning area B2 in which the learning request areas A4 and A5 are integrated are created as stepped areas.

  In addition, when the step at the same location on the road is traveled a plurality of times, storing the step information of the step area detected according to the learning request every time the travel is performed in the storage media unit 19 increases the stored data. The storage capacity of the media unit 19 is compressed.

  Therefore, in the present embodiment, as shown in FIG. 4, the learning request area as the detected step area is compared with the step area already stored in the storage media unit 19, that is, the learning area, The same point determination is performed to determine whether or not the step area is at the same point. When the step area is at the same point, the storage medium unit 19 does not store the step area. Here, in FIG. 4, the horizontal axis indicates the distance along the traveling direction of the vehicle, and the vertical axis indicates the presence / absence of a learning request transmitted from the suspension control device 20. C indicates a value for which a learning request is present, line D indicates a learning area as a step area already stored in the storage media unit 19, and line E indicates a current learning request area as a step area detected this time. Is shown. Further, D1 and D2 indicate learning areas as stored step areas, and E1 to E3 indicate current learning request areas, that is, new learning areas. When the current learning request area from the suspension controller 20 overlaps with a learning area as a stored step area such as D1 as in E1, the step at the same point as the learning area It is determined that it is an area, and is not newly stored in the storage media unit 19. Further, even if the current learning request area from the suspension control device 20 does not overlap any learning area such as E2, the distance from the learning area as a stored step area such as D2 is the matching distance error. Is within the same area as the learning area, it is not stored in the storage media unit 19 anew. The matching distance error is the maximum distance of errors generated during map matching, and is, for example, 30 [m]. The current learning request area from the suspension control device 20 does not overlap any learning area like E3, and the distance from the learning area as a stored step area such as D2 is the matching distance. When it is larger than the error, it is determined that the step area is not the same as the learning area, and is stored in the storage media unit 19 as a new learning area.

  Further, the same point determination is performed, and if the step area is at the same point, the position information of the step area is corrected. In this case, as shown in FIG. 1, the position information of the start and end points of the learning area as the stored step area already stored in the storage media unit 19, and the current learning as the step area detected this time An averaging process is performed to average the position information of the start point and end point of the request area, and the position information of the start point and end point obtained by the averaging process is used as the position information of the start point and end point of the step area after correction. The stored learning area as the step area is updated with the corrected learning area as the corrected step area. In the averaging process, the weighted average can be calculated by weighting the position information of the start point and the end point of the stored step area stored in the storage media unit 19. In FIG. 1, the horizontal axis indicates the distance along the traveling direction of the vehicle, and the vertical axis indicates the presence or absence of a learning request transmitted from the suspension control device 20. F1 indicates a learning area as a step area already stored in the storage media unit 19, F2 indicates a current learning request area as a step area detected this time, and F3 indicates a correction as a step area after correction. The post-learning area is shown.

  Thus, as the correction of the position information of the step area is repeated, the variation in the position information of the start and end points of the step area detected by the navigation device 10 can be leveled, so learning as a stored step area The position information of the start point and end point of the area becomes accurate. That is, the reliability of the learned position information of the step area is improved. Therefore, the number of corrections for the position information of the step area is stored in the storage media unit 19 as reliability information for indicating the reliability of the learned position information of the step area, and the step information is notified to the suspension control device 20. In addition, the suspension control device 20 notifies the suspension unit 30 of the suspension unit 30 according to the number of corrections, that is, according to the reliability information of the learned position information of the stepped area. The characteristics can be changed. In a learning area where the number of corrections is large and the positional information is considered to be highly reliable, the damping force control unit 25 increases the control amount to change the characteristics of the suspension unit 30 relatively large, and the number of corrections is small. In the learning area where the reliability of the position information is considered to be low, the damping force control unit 25 reduces the control amount and changes the characteristics of the suspension unit 30 to be relatively small in consideration of the deviation of the control timing. The vehicle driver and passengers do not feel discomfort, and appropriate suspension control can be effectively performed for the steps.

  Next, processing for executing the step learning system will be described.

  FIG. 5 is a flowchart showing a procedure of processing for executing the level difference learning system according to the embodiment of the present invention.

  First, the suspension control device 20 executes a step detection process. Here, the level difference detection process is a process in which the level difference detection processing unit 21 of the suspension control device 20 detects that the vehicle has traveled on the level difference based on the detection signal of the level difference detection sensor 22. In this case, the level difference detection processing unit 21 repeatedly executes the level difference detection process at a predetermined cycle, for example, every 10 [msec], and determines whether or not a level difference is detected each time it is executed. A step detection ON signal is transmitted to the navigation device 10 when the step changes from a state where the step is not detected to a detected state, and a step detection occurs when the step changes from a state where the step is detected to a state where it is not detected. An OFF signal is transmitted to the navigation device 10. Therefore, the step detection ON signal corresponds to the start point of the learning request area as the detected step area such as A1 to A5 shown in FIG. 3A, that is, the leading edge of the pulse, and the step detection OFF signal is This corresponds to the end point of the learning request area as the detected stepped area such as A1 to A5 shown in FIG. 3, that is, the trailing edge of the pulse.

  Subsequently, the navigation device 10 executes a step information storage process. Here, the step information storage processing is processing in which the current position detection unit 16 and the step area calculation processing unit 17 of the navigation device 10 access the storage media unit 19 and store the detected step area in the storage media unit 19. It is. In this case, as shown in FIG. 3B, adjacent step areas are integrated, and a learning area as a learned step area is created and stored. Further, as shown in FIG. 4, the same spot determination is performed, and if the detected step area is not a step area at the same point as the learning area that is already stored, the detected step area is stored as a learning area. If the detected step area is a step area at the same point as the already stored learning area, the detected step area is not stored, and the learning request counter for the already stored learning area is not stored. The count value is increased by 1, that is, incremented.

  In addition, the navigation device 10 executes a step information notification process. Here, the step information notification processing is based on the current position of the vehicle acquired from the current position detection unit 16 and the learning area information acquired from the storage media unit 19 by the step information notification processing unit 18 of the navigation device 10. This is a process of transmitting step information of a learning area as a learned step area within a predetermined range in the forward direction of the vehicle to the suspension control device 20. In this case, the step information notification processing unit 18 determines the road type of the road where the step area exists, and only the step information of the learning area in which the count value of the learning request counter is equal to or greater than the threshold corresponding to the road type is the suspension control device 20. Send to.

  Subsequently, the suspension control device 20 executes a damping force control process. Here, the damping force control process is a process in which the damping force control unit 25 of the suspension control device 20 reduces the damping force of the suspension unit 30 and improves the riding comfort based on the step information received from the navigation device 10. is there. Note that when the vehicle is turning, the damping force of the suspension unit 30 is not changed because it affects the stability of the vehicle.

Next, a flowchart will be described.
Step S1: The suspension control device 20 executes a level difference detection process.
Step S2 The navigation device 10 executes a step information storage process.
Step S3 The navigation device 10 executes a step information notification process.
Step S4: The suspension control device 20 executes a damping force control process.

  Next, a subroutine for level difference detection processing in step S1 will be described.

  FIG. 6 is a flowchart showing a subroutine of level difference detection processing in the embodiment of the present invention.

  In this case, the step detection process is repeatedly executed at a predetermined timing, for example, once every 10 [msec]. First, the step detection processing unit 21 of the suspension control device 20 detects the vertical acceleration of the vehicle body based on a detection signal from the step detection sensor 22. And the level | step difference detection process part 21 extracts the high frequency component of a vertical acceleration.

  Subsequently, the level difference detection processing unit 21 determines whether or not the level difference detection flag is ON. Here, in the step detection process that is repeatedly executed, the step detection processing unit 21 detects a step in the current step detection process without detecting a step in the step detection process executed last time. It is supposed to be turned on. Then, the step detection flag is kept ON, and the step detection flag is turned OFF when no step is detected in the step detection process. For this reason, the fact that the step detection flag is ON means that the vehicle is traveling in the step area and has detected a step in at least the previous step detection process. In addition, the fact that the step detection flag is OFF instead of ON means that the vehicle is not traveling in the step area and has not detected a step in the step detection process up to the previous time.

  When the step detection flag is not ON, that is, when the step detection flag is OFF, the step detection processing unit 21 determines whether the high-frequency component of the vertical acceleration is equal to or greater than a predetermined value 1 as the first predetermined value. to decide. Here, the predetermined value 1 is the magnitude of the vertical acceleration at which it can be determined that the vehicle has traveled on a step, and can be arbitrarily set. If the high-frequency component of the vertical acceleration is not equal to or greater than the predetermined value 1, the process is terminated as it is. If the high frequency component of the vertical acceleration is greater than or equal to the predetermined value 1, the step detection processing unit 21 turns on the step detection flag. And a level | step difference detection ON signal is transmitted to the navigation apparatus 10, and a process is complete | finished.

  Further, when it is determined whether or not the step detection flag is ON and the step detection flag is ON, the step detection processing unit 21 has a high frequency component of vertical acceleration that is less than a predetermined value 2 as a second predetermined value. Determine whether or not. Here, the predetermined value 2 is a magnitude of the vertical acceleration that can be determined that the vehicle has stopped traveling on the level difference, and is a value that is smaller than the predetermined value in order to provide hysteresis. Can be set. If the high-frequency component of the vertical acceleration is not less than the predetermined value 2, the process is terminated as it is. When the high frequency component of the vertical acceleration is less than the predetermined value 2, the step detection processing unit 21 turns off the step detection flag. And a level | step difference detection OFF signal is transmitted to the navigation apparatus 10, and a process is complete | finished.

Next, a flowchart will be described.
Step S1-1: The vertical acceleration of the vehicle body is detected based on the detection signal from the step detection sensor 22.
Step S1-2: Extract high frequency components of vertical acceleration.
Step S1-3: It is determined whether or not the step detection flag is ON. If the step detection flag is ON, the process proceeds to step S1-7. If the step detection flag is not ON, the process proceeds to step S1-4.
Step S1-4: It is determined whether or not the high-frequency component of the vertical acceleration is a predetermined value 1 or more. If the high frequency component of the vertical acceleration is greater than or equal to the predetermined value 1, the process proceeds to step S1-5. If the high frequency component of the vertical acceleration is not equal to or greater than the predetermined value 1, the process ends.
Step S1-5: The level difference detection flag is turned ON.
Step S1-6 The step detection ON signal is transmitted to the navigation device 10, and the process is terminated.
Step S1-7: It is determined whether or not the high frequency component of the vertical acceleration is less than a predetermined value 2. If the high-frequency component of the vertical acceleration is less than the predetermined value 2, the process proceeds to step S1-8. If the high-frequency component of the vertical acceleration is not less than the predetermined value 2, the process ends.
Step S1-8: The level difference detection flag is turned off.
Step S1-9 The step detection OFF signal is transmitted to the navigation device 10 and the process is terminated.

  Next, a step information storage subroutine in step S2 will be described.

  FIG. 7 is a flowchart showing a subroutine of step information storage processing in the embodiment of the present invention.

  First, the navigation apparatus 10 determines whether or not the step learning request is ON, that is, whether the signal received from the step detection processing unit 21 is a step detection ON signal or a step detection OFF signal. If the step learning request is ON, that is, a step detection ON signal, it is determined whether or not the start point has been registered. That is, it is determined whether or not the start point of the learning request area as a detected step area such as A1 to A5 shown in FIG. If it has already been registered, the process ends. If not registered, step area start point registration is performed, the detected step area start point is registered, and the process ends.

  If the step learning request is determined to be ON and not ON, that is, if the step detection OFF signal is received, the navigation device 10 determines whether or not the step area start point has been registered. That is, it is determined whether or not the start point of the detected step area such as A1 to A5 shown in FIG. If it has not been registered, the process ends. If registered, the step area end point is registered, and the end point of the detected step area is registered.

  Subsequently, the navigation device 10 determines whether there is another step area in a predetermined range before the current step area. That is, within a predetermined range on the near side of the traveling direction of the vehicle from the step area where the end point is registered in the current step information storing process, for example, within a range within 30 [m] from the start point of the step area. It is determined whether there is another registered step area. If there is another step, that is, if there is another step area already registered, the step areas are combined. That is, in FIG. 3, the end point is registered in the current step information storage process as if the learning area B1 that combines the learning request areas A1 to A3 and the learning area B2 that combines the learning request areas A4 and A5 are created. A step area is combined with other already registered step areas to create a single learning area. When there is no other step, that is, when there is no other step area already registered, the step areas are not combined.

  Subsequently, the navigation device 10 determines whether there is a step area that is already registered in the storage media unit 19 and whose distance is within a predetermined value. That is, as shown in FIG. 4, the detected step area is compared with the step area already stored in the storage media unit 19, that is, the learning area, and it is determined whether or not the step area is at the same point. The same point is determined. If there is a distance within a predetermined value, that is, a step area at the same point, the registered step information is corrected based on the current learning request information. That is, the position information of the start point and end point of the step area already registered in the storage media unit 19 is corrected based on the position information of the start point and end point of the current learning request area. Specifically, the position information of the start point and end point of the step area F1 already stored in the storage media unit 19 as shown in FIG. 1, the start point of the current learning request area F2 as the step area detected this time, and Averaging processing with the end point position information is performed to obtain the start point and end point position information such as the corrected step area F3. Subsequently, the number of corrections for the corresponding learning area is incremented, and the process ends. In this case, the detected step area is not stored in the storage media unit 19 and the count value of the correction count counter for counting the number of corrections of the learning area already stored in the storage media unit 19 is increased by one.

  If there is no distance within the predetermined value, that is, if it is not the step area at the same point, the step area is newly registered in the storage media unit 19 and the process is terminated. In this case, the detected step area is stored in the storage media unit 19 as a new learning area such that the learning request area shown in FIG. 3 is E3.

Next, a flowchart will be described.
Step S2-1: It is determined whether or not the step learning request is ON. If the step learning request is ON, the process proceeds to step S2-2. If the step learning request is not ON, the process proceeds to step S2-4.
Step S2-2: It is determined whether or not the start point has been registered. If the start point has been registered, the process ends. If the start point has not been registered, the process proceeds to step S2-3.
Step S2-3: Step area start point registration is performed, and the process ends.
Step S2-4: It is determined whether or not the step area start point has been registered. If the step area start point has been registered, the process proceeds to step S2-5. If the step area start point has not been registered, the process ends.
Step S2-5: Step area end point registration is performed.
Step S2-6: It is determined whether there is another step area within a predetermined range before the current step area. If there is another step area in the predetermined range before the current step area, the process proceeds to step S2-7. If there is no other step area in the predetermined range before the current step area, the process proceeds to step S2-8.
Step S2-7: Combine the step areas.
Step S2-8: It is determined whether there is a step area that has already been registered in the storage media unit 19 and whose distance is within a predetermined value. If there is a step area that is already registered in the storage media unit 19 and the distance is within the predetermined value, the process proceeds to step S2-9, and a step area that is already registered in the storage media unit 19 and the distance is within the predetermined value. If not, the process proceeds to step S2-11.
Step S2-9: The registered step information is corrected based on the current learning request information.
Step S2-10 The number of corrections for the corresponding learning area is incremented, and the process is terminated.
Step S2-11 The step area is newly registered in the storage media unit 19, and the process is terminated.

  Next, a step information notification subroutine in step S3 will be described.

  FIG. 8 is a flowchart showing a subroutine of step information notification processing in the embodiment of the present invention.

  First, the navigation device 10 reads the step information of the road ahead of the current position from the storage media unit 19. In this case, based on the current position of the vehicle acquired from the current position detection unit 16, step information of the learned step area on the road ahead in the traveling direction of the vehicle is acquired from the storage media unit 19. Subsequently, it is determined whether or not there is a step area in front. In this case, it is determined whether or not there is a learned step area that is within a predetermined range ahead of the traveling direction of the vehicle.

  Then, if there is no step area ahead, the process is terminated. When there is a step area ahead, the navigation device 10 transmits step information to the suspension control device 20 and ends the process. In this case, the correction number of the step information is also transmitted.

Next, a flowchart will be described.
Step S3-1: Read the step information on the road ahead of the current position from the storage media unit 19.
Step S3-2: It is determined whether or not there is a step area ahead. If there is a step area ahead, the process proceeds to step S3-3. If there is no step area ahead, the process ends.
Step S3-3: The step information (including the number of corrections) is transmitted to the suspension controller 20, and the process is terminated.

  Next, the subroutine of the damping force control process in step S4 will be described.

  FIG. 9 is a flowchart showing a subroutine of damping force control processing in the embodiment of the present invention.

  First, the damping force control unit 25 of the suspension control device 20 determines whether or not it has received front step information from the navigation device 10, that is, a step for a learned step area within a predetermined range in front of the traveling direction of the vehicle. It is determined whether information has been received. If the step information has not been received, the process is terminated as it is. When step information is received, the damping force control unit 25 determines whether or not the vehicle is turning. In this case, the damping force control unit 25 determines whether or not the vehicle is turning based on the detection signal of the steering sensor 27. If the damping force control unit 25 is connected to a yaw rate sensor or lateral acceleration sensor (not shown), it is determined whether the vehicle is turning based on detection signals from the yaw rate sensor and lateral acceleration sensor. You can also

  Then, when the vehicle is turning, the process is ended as it is. Further, when the vehicle is not turning, the damping force control unit 25 reduces the damping force of the suspension unit 30 according to the number of corrections of the step information notified from the navigation device 10 to improve the riding comfort, and ends the processing. To do. Here, if the number of corrections is large, it is considered that the positional information of the learned step area is highly reliable and the control timing shift is small, so the control amount is increased and the characteristics of the suspension unit 30 are changed relatively large. May be. Therefore, the amount of decrease in damping force is increased. Further, if the number of corrections is small, the reliability of the learned position information of the stepped area is considered to be low, and the control timing is considered to be largely shifted. Therefore, the control amount is reduced, and the characteristics of the suspension unit 30 are relatively improved. It is necessary to change only small so that the driver and passengers of the vehicle do not feel uncomfortable. Therefore, the amount of decrease in damping force is reduced.

Next, a flowchart will be described.
Step S4-1: It is determined whether or not forward step information has been received from the navigation device 10. When the front step information is received from the navigation device 10, the process proceeds to step S4-2. When the front step information is not received from the navigation device 10, the process is terminated.
Step S4-2: It is determined whether or not the vehicle is turning. If it is turning, the process ends. If it is not turning, the process proceeds to step S4-3.
Step S4-3 In accordance with the number of corrections of the step information notified from the navigation device 10, the damping force of the suspension unit 30 is reduced to improve the riding comfort, and the processing is terminated.

  Thus, in the present embodiment, when the suspension control device 20 detects a step on the road while the vehicle is traveling, the navigation device 10 learns the presence of the detected step area. In this case, the navigation device 10 performs the same point determination when the step area is detected, and corrects the position information for the step area at the same point. For this reason, the learned position information of the step area becomes accurate by leveling variations, and the reliability is improved. Further, the storage capacity of the storage data stored in the storage media unit 19 can be reduced, and the storage capacity of the storage media unit 19 is not compressed.

  Furthermore, the suspension control device 20 changes the characteristics of the suspension unit 30 by changing the control amount according to the number of corrections, that is, according to the reliability information of the learned position information of the step area. Thus, suspension control can be appropriately performed. That is, in the step area where the number of corrections is large and the positional information is considered to be highly reliable, the suspension control device 20 increases the control amount and changes the characteristics of the suspension unit 30 relatively, so that the vehicle moves up the step. The shock received when traveling can be appropriately absorbed. In addition, in the step area where the number of corrections is small and the reliability of the position information is considered to be low, the suspension control device 20 reduces the control amount and changes the characteristics of the suspension unit 30 to be relatively small. However, the driver or passenger of the vehicle does not feel uncomfortable.

  Furthermore, since the navigation apparatus 10 combines the detected plurality of step areas into a single step area when the interval is short, the storage capacity of the storage data stored in the storage media unit 19 can be reduced. The storage capacity of the storage media unit 19 is not compressed. In addition, the characteristics of the suspension unit 30 do not change at short intervals, and suspension control can be performed appropriately for the steps.

  In addition, this invention is not limited to the said embodiment, It can change variously based on the meaning of this invention, and does not exclude them from the scope of the present invention.

It is a figure which shows the operation | movement which correct | amends the positional information on the level | step difference area in embodiment of this invention. It is a block diagram which shows the structure of the level | step difference learning system in embodiment of this invention. It is a figure which shows the operation | movement which couple | bonds the learning request | requirement in embodiment of this invention. It is a figure which shows the operation | movement of the same spot determination in embodiment of this invention. It is a flowchart which shows the procedure of the process which performs the level | step difference learning system in embodiment of this invention. It is a flowchart which shows the subroutine of the level | step difference detection process in embodiment of this invention. It is a flowchart which shows the subroutine of the level | step difference information storage process in embodiment of this invention. It is a flowchart which shows the subroutine of the level | step difference information notification process in embodiment of this invention. It is a flowchart which shows the subroutine of the damping force control process in embodiment of this invention.

Explanation of symbols

16 Current position detection unit 17 Step area calculation processing unit 19 Storage media unit 21 Step detection processing unit 22 Step detection sensor 25 Damping force control unit 30 Suspension unit

Claims (5)

(A) a step detecting means for detecting a step on the road;
(B) storage means for storing step information of the step area detected by the step detection means together with reliability information of the step information;
(C) Step learning that includes step control based on step information of a step area stored in the storage unit and that changes a control amount in accordance with the reliability information. system. (A) comparison means for comparing step information of the step area stored in the storage means with step information of the step area detected by the step detection means;
(B) further comprising storage processing means for correcting step information of the step area stored in the storage means based on the comparison result by the comparison means;
(C) The step learning system according to claim 1, wherein the storage unit stores the number of corrections of the step information as reliability information. The step learning system according to claim 2, wherein the storage processing unit includes a counter and increments the number of corrections for a step area in which step information is stored in the storage unit. 3. The storage processing unit corrects the step information by performing an averaging process on the step information of the step area stored in the storage unit and the step information of the step area detected by the step detection unit. Level difference learning system according to 3. 4. The step learning system according to claim 2, wherein the step control means increases the control amount when the number of corrections is large.

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