Source: https://patents.google.com/patent/DE102017129570A1/en
Timestamp: 2020-02-19 20:22:46
Document Index: 642453265

Matched Legal Cases: ['Application No. 2009', 'Application No. 2005', 'Application No. 2008', 'Application No. 2009', 'Application No. 2010', 'Application No. 2014', 'Application No. 2006', 'arts 10', 'arts 10', 'arts 10']

DE102017129570A1 - Lane change assistance device for a vehicle - Google Patents
Lane change assistance device for a vehicle
DE102017129570A1
DE102017129570A1 DE102017129570.4A DE102017129570A DE102017129570A1 DE 102017129570 A1 DE102017129570 A1 DE 102017129570A1 DE 102017129570 A DE102017129570 A DE 102017129570A DE 102017129570 A1 DE102017129570 A1 DE 102017129570A1
DE102017129570.4A
2016-12-26 Priority to JP2016-251658 priority Critical
2016-12-26 Priority to JP2016251658A priority patent/JP6579334B2/en
2017-12-12 Application filed by Toyota Motor Corp filed Critical Toyota Motor Corp
2018-06-28 Publication of DE102017129570A1 publication Critical patent/DE102017129570A1/en
A driving support ECU detects that a turn signal signal of the turn signal signal lever is off (S14: Yes). When a timer value Tx representing an ON-shift duration in which the tap-stop signal remains on, an assist request confirmation duration Tref is reached (S19: Yes) and after the detection of the tap-stop signal, an LCA start condition is satisfied (S20: Yes), the driving support control unit starts LCA. The drive assist control unit does not determine the tap monitor signal until the LCA is completed. After completing the LCA, the driving support control unit restarts the process steps from S11. This will cause the LCA to stop running even if the tap is continued.
The present invention relates to a lane change assist device configured to execute a lane change assist control which is a control for assisting a lane change driving operation.
Like in the Japanese Laid-Open Patent Application No. 2009-274594 is proposed, a lane change assistance device is known, which is adapted to perform a lane change assistance control, which is a control for assisting a steering operation (steering wheel operation) for changing the lane. The lane change assist device uses, for example, an electrically assisted steering system for providing / generating steering torque to a steering mechanism to thereby change the lanes traveled by the own vehicle without steering operation of the driver.
The in the Japanese Laid-Open Patent Application 2009-274594 The proposed lane change assisting apparatus detects an operation performed by the driver on a turn signal signal lever and starts the lane change assist control in response to the operation performed on the turn signal signal lever.
The lane change assistance control is started when, based on a monitoring result of the environment sensors monitoring the environment of the own vehicle, it is determined that the own vehicle can safely change lanes. It may happen here that the driver overestimates the lane change assistance device (or relies too much on it) and / or no longer self-monitors the own vehicle environment, so that it can happen that the driver fully adopts the decision process about the start of the lane change assistance control Lane change assistance control leaves. For example, if the driver performs an operation for requesting lane change assistance longer, the lane change assistance control is started at a time when the lane change assistance control device determines that the own vehicle can safely change the lane. In this case, the driver may optionally extend the operation of the lane change assistance request as if pre-reserving the lane change assistant. However, when the operation of the lane change assistance request continues for a long time, there may be a case where a driver unintentional lane change (for example, a continuation / extra lane change) is executed. That is, it could be that the lane change assistance control for the change to a secondary lane not intended by the driver is started again after the own vehicle has already made the lane change once.
The present invention has been developed to solve the above-mentioned problem, and an object of the invention is to provide a lane change assist device which prevents the start of lane change assist control not intended by the driver.
In order to achieve the above object, according to an embodiment of the present invention, there is provided a lane change assisting apparatus for a vehicle, comprising:
lane change assistance request recognition means (10, 40, S16-S19) for detecting a driver side request for lane change assistance in response to an operation performed on a lane change assistance requesting operation unit (41);
an environmental monitoring means (10, 11) for monitoring an environment of the own vehicle;
a lane change assistance control means (10, 20, S21) for accepting the lane change assistance request and starting the lane change assistance control for lane change when, in a situation where the lane change assistance request recognition means has recognized the lane change assistance request (S19: Yes), the environment monitoring means determines that Own vehicle can safely change the tracks traveled by the own vehicle (S20: Yes); and
Non-operation detecting means (S14: Yes) for detecting a non-operation state in which the operation on the operation unit for requesting the lane change assistance is not performed;
wherein the lane change assistance control means is adapted to:
Accepting the lane change assistance request when a condition precedent is satisfied (S14: yes, S16: yes), wherein the condition of precedence is a condition set to be satisfied when the lane change assistance request recognition means is in a situation in which the Non-operation detection means has detected the no-operation state recognizing operation performed on the operation unit for requesting the lane change assistance; and
when the lane change assistance control means accepts the lane change assistance request, executing the lane change assistance control for causing the lane change of the own vehicle from a current lane currently being traveled by the own vehicle to a lane immediately adjacent to the current lane (S21, S22).
In this case, it is desirable that the lane change assistance request detection means is configured to recognize the lane change assistance request when the operation performed on the lane change assistant requesting unit continues beyond a preset assistance request confirmation period or longer (S19: Yes).
In the lane change assisting apparatus according to the embodiment of the present invention, the lane change assistance request recognizing means recognizes the lane change assistance request of the driver in response to the operation performed on the operation unit for requesting lane change assistance. For example, the lane change assistance request recognition means recognizes the lane change assistance request when the operation performed on the lane change assistant requesting unit continues beyond a preset assistance request confirmation period or longer. Thus, the driver's intention to claim / obtain the lane change assistance can be properly recognized.
The environment monitoring means monitors the environment of the own vehicle. The environment monitoring means detects, for example, relative information (a distance, a relative speed, and a relative position) between a three-dimensional object (for example, another vehicle) existing in the vicinity of the own vehicle and the own vehicle. The lane change assistance control means accepts the lane change assistance request when, in a situation where the lane change assistance request recognition means has recognized the lane change assistance request, the environment monitoring means determines that the own vehicle can safely change the lane (for example, when a vehicle distance between the own vehicle and the other vehicle is properly ensured taking into account the relative speed between them). Then, the lane change assistance control means starts the lane change assistance control for changing the lane traveled by the own vehicle. The lane change assist control means supplies / generates, for example, a steering torque for a steering mechanism for steering a steering wheel, thereby controlling a traveling direction of the own vehicle. Accordingly, the driver performs the control action on the operating unit for requesting the lane change assistance in order to initiate the safe lane change of the own vehicle by using the lane change assistance.
When the driver overestimates (or gives too much confidence) to the lane change assist requesting operation (referred to as "lane change assist request operation"), as in pre-reserving the lane change assistant, a situation in which the lane change assist request is detected lasts will, continue. Here can be the case that the lane change is contrary to the driver's intention (for example, as a repeated and redundant lane change). Due to this, the lane change assist device according to the embodiment of the present invention includes the non-operation detecting means.
The non-operation detecting means detects the non-operating state in which the operation on the operation unit for requesting the lane change assistance is not performed. The lane change assistance control means accepts the lane change assistance request when a prerequisite condition is satisfied, the condition precedent being a condition set to be satisfied when the lane change assistance request recognition means is in a situation in which the non-operation detection means is the non-operation state detects the operation performed on the operation unit for requesting the lane change assistance operation, and performs, if the Lane change assistance control means accepts the lane change assistance request, the lane change assistance control (related to a lane) to cause the lane change of the own vehicle from a currently traveled by the own vehicle current lane to an immediately adjacent to the current lane track.
According to an embodiment of the present invention, even if the driver resumes the operation for requesting the lane change assistance on the operation unit, the lane change does not proceed because the lane change assistance control is completed / terminated when the own vehicle moves the lane from the current lane immediately adjacent to the current lane changes lane. As a result, the one embodiment of the present invention can prevent the start of the lane change assistance control process not intended by the driver.
A feature of an embodiment of the present invention is that the lane change assistance control means is adapted to not accept the lane change assistance request during a period from the start of the lane change assistance control to the completion of the lane change assistance control even if the lane change assistance request detection means detects the lane change assistance request Lane Change Assist detected operation (S20: Yes, S21, S22: No).
According to the one embodiment of the invention, when the driver performs the operation on the operation unit for requesting the lane change assistance during execution of the lane change assistance control, the lane change assistance request is not accepted in response to this operation. Accordingly, even if the driver omits the environmental monitoring of the own vehicle and continues the operation on the operation unit during execution of the lane change assistance control as if pre-reserving the further / extra lane change, the lane change assistance control to the next adjacent lane is not started. The one embodiment of the present invention can prevent the driver from performing the operation by overestimating the lane change assist device (by placing too much trust in the device).
A feature of an embodiment of the present invention is that the on-lane assistance apparatus for a vehicle further comprises a turn signal control means (10, 30, S51-S54) for driving an operation of a turn signal to start the intermittent lighting (flashing) of the turn signal. when the lane change assist control is started, and turn off the turn signal when a turn signal turn-off condition set to be satisfied before completion of the lane change assist control is satisfied,
wherein the lane change assistance control means is adapted to not accept the lane change assistance request during a period from the start of lane change assist control until the turn signal turn off condition is satisfied, even though the lane change assistance request recognition means recognizes the operation performed on the lane change assist operation control unit (S21, S31 : No, S22: No).
According to one embodiment of the present invention, the turn signal control means controls the operation of the turn signal (hereinafter referred to as "turn signal lamp" or "turn signal lamp") to start the intermittent lighting of the turn signal when the lane change assist control is started and to turn off the turn signal, when the turn signal switch-off condition set to be satisfied before completion of the lane change assist control is satisfied. For example, it is desirable that the turn signal switch off condition is set to be satisfied when the own vehicle reaches a position still distant from a target position in the widthwise direction of the own vehicle to complete the lane change assist control.
The driver usually recognizes at turn off the turn signal that the lane change assist control is completed. The lane change assistance request in response to the operator action taken after turning off the turn signal on the keypad thus represents an intention of the driver to obtain new lane change assistance. The operator action executed before the turn signal is turned off, however, may be a driver operation. in which he pre-reserves the repeated lane change assistance with too much confidence in the lane change assistance device.
Due to this circumstance, the lane change assistance request is made by the lane change assistance control means in response to an operation on the operation unit to request the lane change assistance request Lane change assistance during a period from the start of the lane change assistance control until the fulfillment of the turn signal switch-off condition is not accepted. This one embodiment of the present invention can prevent the driver's operation from being carried out in the lane change assist device in the course of excessive confidence.
In addition, it is difficult for the driver to finally recognize a termination timing of the lane change assist control, while it is possible for the driver to finally recognize a turn-off timing of the turn signal. Therefore, according to the one embodiment of the present invention, the driver can appropriately recognize a point in time from which he can request a next lane change assistance control.
In the above description, for ease of understanding of the invention, the reference numerals used in the embodiments of the present invention are added in parentheses and assigned to the respective constituent features of the invention according to the embodiments. However, the respective constituent features of the invention are not limited to the embodiments defined by the reference numerals.
1 FIG. 10 is an outline diagram schematically illustrating a lane change assisting apparatus for a vehicle according to an embodiment of the present invention. FIG.
2 FIG. 10 is a plan view showing the arrangement positions of environmental sensors and a camera sensor. FIG.
3 is a view illustrating track-related vehicle information.
4 is a view illustrating the operation of a direction signal signal lever.
5 is a view illustrating a Lenkhilfssteuerzustand and a trajectory (trajectory) of the own vehicle.
6 FIG. 10 is a flowchart illustrating a power steering control routine of the embodiment. FIG.
7 Fig. 10 is a flowchart showing a flashing control of a turn signal of the embodiment.
8th Fig. 13 is a view showing a turn-off permission distance.
9 FIG. 14 is a part of a flowchart for illustrating the steering assist control routine of a modification example.
10 Fig. 16 is a view illustrating a display screen.
Hereinafter, a lane change assist apparatus for a vehicle according to an embodiment of the present invention will be described with reference to the accompanying drawings.
The lane change assist device according to the embodiment of the present invention is applied to a vehicle (which will hereinafter be referred to as "own vehicle" for differentiation from other vehicles) and includes, as in FIG 1 shown, a control unit for driving assistance (driving support ECU) 10 , a control unit for electrically assisted steering (power steering ECU) 20 , an instrument control unit (instrument ECU) 30 , a steering control unit (steering ECU) 40 , an engine control unit (engine ECU) 50 , a brake control unit (brake ECU) 60 and a navigation control unit (navigation ECU) 70 ,
These ECUs are electric control units each comprising a microcomputer as a main part, and are connected to each other via a control device network (CAN). 100 Send and receive information. The microcomputer mentioned here includes a CPU, a ROM, a RAM, a nonvolatile memory, an interface I / F, and the like. The CPU executes instructions stored in the ROM (programs and routines) to realize various functions. Some or all of the ECUs may be integrated in one ECU.
Furthermore, there are several types of vehicle condition sensors 80 , which are designed to detect a vehicle condition, and a plurality of types of driving condition sensors 90 , which are designed to detect a driving condition, with the CAN 100 connected. Examples of vehicle condition sensors 80 Among others, a vehicle speed sensor configured to detect a running speed of the vehicle, a front-rear G sensor configured to detect an acceleration in a longitudinal direction of the vehicle, a side G sensor configured to detect an acceleration in a lateral direction of the vehicle and a Yaw rate sensor designed to detect a yaw rate of the vehicle.
Examples of driving condition sensors 90 Among others, an accelerator operation sensor configured to detect an operation amount of an accelerator pedal, a brake actuation sensor configured to detect an operation amount of a brake pedal, a brake switch configured to detect the presence or absence of the brake pedal operation, a steering angle sensor configured for detecting a steering angle, a steering torque sensor configured to detect a steering torque, and a shift position sensor configured to detect a shift position of a transmission.
From the vehicle condition sensors 80 and the driving condition sensors 90 Information acquired (hereinafter referred to as "sensor information") is sent to the CAN 100 Posted. The to the CAN 100 transmitted sensor information can be used in each ECU in an appropriate manner. The sensor information is information of a sensor connected to a specific ECU and can be sent from the specific ECU to the CAN 100 be transmitted. The accelerator pedal operation sensor can be used, for example, with the engine ECU 50 be connected. In this case, the sensor information representing the accelerator operation becomes the engine ECU 50 to the CAN 100 Posted. The steering angle sensor can be used, for example, with the steering ECU 40 be connected. In this case, the steering angle representative sensor information from the steering ECU 40 to the CAN 100 Posted. The same goes for the other sensors. In addition, an embodiment can be used in which the sensor information without the interposition of the CAN 100 be sent and received in direct communication between special ECUs.
The driving support ECU 10 is a control device serving as a control center for executing driving assistance functions for a driver and executing lane change assist control, lane keeping assistance control, and adaptive cruise control. As in 2 are an environmental sensor in the center 11FC , an environment sensor on the front right 11FR , an environment sensor front left 11FL , an environment sensor in the back right 11RR and a rear left environment sensor 11RL with the driving support ECU 10 connected. The environmental sensors 11FC . 11 FR, 11 FL, 11RR and 11RL are radar sensors and are always configured identically, except that the sensors have different detection ranges. The following are the environmental sensors 11FC . 11FR . 11FL . 11RR and 11RL referred to as "environmental sensors 11" when it is not necessary to distinguish them in detail from each other.
Each of the environmental sensors 11 includes a radar transceiver and a signal processor (not shown). The radar transceiver emits a radio wave in a millimeter waveband (hereinafter referred to as "millimeter wave") and receives a millimeter wave (ie, a reflected wave) from a three-dimensional object (e.g., other vehicles, pedestrians, Bicycles and buildings) is reflected. Each time a predetermined period of time elapses, the signal processor acquires information (hereinafter referred to as "surrounding information") including, for example, a distance between the own vehicle and the three-dimensional object, a relative velocity between the own vehicle and the three-dimensional object, and a relative position (direction) of the vehicle Represent a three-dimensional object in relation to the own vehicle, for example, based on a phase difference between the transmitted millimeter wave and the received reflected wave, a damping level of the reflected wave and a period of time from the transmission of the millimeter wave to the reception of the reflected wave. Then, the signal processor sends the environment information to the driving support ECU 10 , The environment information may be used to detect a front-rear direction component and a side-direction component in the distance between the own vehicle and the three-dimensional object and a front-rear direction component and a side direction component in the relative velocity between the own vehicle and the three-dimensional object.
As in 2 shown, the environmental sensor is the center front 11FC arranged in a central front region of a vehicle body and detects a located in the front region of the own vehicle three-dimensional object. The ambient sensor on the front right 11FR is in a front right Corner region of the vehicle body arranged and detects predominantly located in the right front area of the own vehicle three-dimensional object. The environment sensor front left 11FL is disposed in a front left corner area of the vehicle body, and mainly detects a three-dimensional object located in the left front area of the own vehicle. The environment sensor in the back right 11RR is arranged in a rear right corner region of the vehicle body and mainly detects a located in the right rear portion of the own vehicle three-dimensional object. The environmental sensor rear left 11FL is disposed in a rear left corner area of the vehicle body and mainly detects a three-dimensional object located in the left rear area of the own vehicle. The following is the environment sensor 11 captured three-dimensional object sometimes referred to as "object".
The environmental sensors 11 are in this embodiment radar sensors, but other sensors such as distance sonars can be used instead.
At the driving support ECU 10 is also a camera sensor 12 connected. The camera sensor 12 includes a camera unit and a lane detection unit configured to analyze image data obtained from an image pickup of the camera unit to recognize a white line (s) of a road. The camera sensor 12 (Camera unit) photographs a landscape ahead of the own vehicle. The camera sensor 12 (Lane detection unit) supplies information regarding the detected white line (s) to the driving support ECU 10 ,
As in 3 represents / sets the driving support ECU 10 a track center line CL, which corresponds to a widthwise central position between the right and left white lines WL of a track traveled by the own vehicle, from the camera sensor 12 supplied information. The lane centerline CL is used as a target driving line in the lane keeping assistance control to be described later. In addition, the driving support ECU calculates 10 the curvature Cu of a curve of the track centreline CL.
Further, the driving support ECU calculates 10 the position and the direction of the own vehicle in the lane delimited by the right and left white lines WL. As in 3 represented calculates the driving support ECU 10 For example, a distance Dy in the lane width direction between a reference point P (eg, position of the center of gravity) of an own vehicle C and the lane center line CL, ie, the distance Dy by which the own vehicle C deviates in the lane width direction from the track center line CL (offset). This distance Dy is called "lateral deviation Dy". In addition, the driving support ECU calculates 10 an angle between the direction of the track center line CL and the direction in which the vehicle C faces, that is, an angle θy by which the orientation of the vehicle C in the horizontal plane deviates from the direction of the track center line CL. This angle θy is referred to as "yaw angle θy". Hereinafter, information (Cu, Dy, and θy) representing the curvature Cu, the lateral deviation Dy, and the yaw angle θy will be referred to as "lane-related information."
In addition, the camera sensor delivers 12 to the driving support ECU 10 also information regarding the white line (s), for example, the type of the detected white line (solid line or broken line), a distance (track width) between the adjacent right and left white lines and the shape of the white line, not just about the vehicle's own lane, but also about adjacent lanes. With a continuous white line, the vehicle is prevented from crossing the white line and thus from changing lanes. Otherwise, for example, when the white line is broken (white line formed at intermittent intervals), the vehicle is allowed to cross the line for lane change. The lane-related vehicle information (Cu, Dy, and θy) and the information related to the white line (s) are collectively referred to as "lane information."
In this embodiment, the driving support ECU calculates 10 the track related vehicle information (Cu, Dy, and θy). Alternatively, the camera sensor 12 be configured to calculate the lane-related vehicle information (Cu, Dy and θy) and the calculation result to the driving support ECU 10 to deliver.
In addition, the camera sensor 12 also recognize a three-dimensional object ahead of the own vehicle on the basis of the image data. Thus, not only track information but also front-side environment information can be detected by the calculation. In this case, for example, a synthesis processor (not shown) may be provided which is designed to be the one from the center front environment sensor 11FC , from the environmental sensor front right 11FR and environmental information acquired from the front left environmental sensor 11 FL and the camera sensor 12 synthesized detected environment information to generate front-end environment information with high detection accuracy. The environment information generated by the synthesis processor may be sent to the drive assist ECU as vehicle related front side environment information 10 to be delivered.
With the driving support ECU 10 is a buzzer (buzzer) 13 connected. The buzzer 13 receives as input a buzzer sound output signal from the driving support ECU 10 and generates a sound. The driving support ECU 10 leaves the buzzer 13 for example, sound when the driving support ECU 10 inform the driver of a driving assistance situation or if the driving assistance ECU 10 alerted the driver.
In this embodiment, the buzzer 13 with the driving support ECU 10 connected, but the buzzer 13 may be connected to other ECUs, such as a dedicated notification ECU (not shown), and the buzzer 13 can be triggered by the notification ECU. In this case, the driving support ECU sends 10 a buzzer sound output command to the notification ECU.
In place or in addition to the buzzer 13 In addition, a vibration generator for emitting a vibration to notify the driver may be provided. The vibration generator is provided on a steering wheel, for example, to set the steering wheel in vibration and thus alert the driver.
The driving support ECU 10 performs the lane change assist control, lane keeping assistance control, and adaptive cruise control based on the environmental sensors 11 supplied environmental information by the camera sensor 12 track information obtained from the white line detection, of the vehicle condition sensors 80 detected vehicle state, of the driving condition sensors 90 detected driving condition and the like.
With the driving support ECU 10 is a driver-operated adjustment control unit 14 connected. The adjustment control unit 14 is an operation unit for executing settings and so forth with respect to whether the lane change assist control, the lane keeping assist control and the adaptive cruise control are respectively to be executed. The driving support ECU 10 receives as input a setting signal from the setting operation unit 14 to determine whether the respective control is to be executed. In this case, if the execution of the adaptive cruise control is not selected, the lane change assist control and the lane departure warning control are automatically set to non-execution. In addition, if the execution of the lane keeping assistance control is not selected, the lane change assistance control is also automatically set to non-execution.
The adjustment control unit 14 also has a function for inputting parameters and the like, which represent the preference of the driver in the execution of the above-mentioned control.
The power steering ECU 20 is a control device for an electrically assisted steering device. Hereinafter, the power steering ECU will be referred to as "EPS-ECU 20". The EPS-ECU 20 is with a motor drive 21 connected. The motor drive 21 is with a steering motor 22 connected. The steering motor 22 is incorporated in a "steering mechanism comprising the steering wheel, a steering shaft coupled to the steering wheel, a steering gear mechanism, and the like" (not shown) of the vehicle. The EPS ECU 20 detects the driver input into the steering wheel (not shown) input steering torque with a built-in steering shaft torque sensor and controls the energization of the motor drive 21 based on the steering torque to the steering motor 22 head for. The auxiliary motor is controlled as described above so that the steering torque is applied to the steering mechanism and thus the steering action of the driver is supported.
In addition, if the EPS-ECU 20 from the driving support ECU 10 over the CAN 100 receives a steering command controls the EPS-ECU 20 the steering motor 22 for generating a steering torque with a control amount expressed in the steering command. This steering torque represents a torque applied to the steering mechanism in response to the steering command of the driving support ECU 10 is to be applied, which does not require steering operation (steering wheel operation) of the driver, unlike when applying a steering assist torque to facilitate the steering operation for the driver, as described above.
The instrument ECU 30 is with a display unit 31 and a right and a left direction signals 32 (meaning direction indicator lamps, sometimes referred to as "directional lamps"). The display unit 31 For example, it is a multiple-information display installed in front of a driver's seat, and displays various kinds of information in addition to the values measured by the instruments, such as a vehicle speed. For example, if the instrument ECU 30 from the driving support ECU 10 receives a display command corresponding to the driving assist state, shows the instrument ECU 30 an instructed in the display command Display screen on the display unit 31 at. As a display unit 31 For example, instead of or in addition to the multiple information display, a head-up display (not shown) may be used. When using the head-up display, a dedicated ECU for controlling the display on the head-up display is preferably provided.
The instrument ECU 30 further comprises a turn signal drive circuit (not shown). When the instrument ECU 30 over the CAN 100 receives a turn signal signal command causes the instrument ECU 30 the intermittent lighting of the direction of travel signal instructed by the direction signal flashing command right or left arranged 32 , While the instrument ECU 30 the intermittent flashing of the direction signal 32 also sends the instrument ECU 30 to the CAN 100 Turn signal flashing information indicating that the turn signal 32 is in an intermittently lit (flashing) state. Thereby, other ECUs can control the intermittent flashing state of the turn signal 32 detect.
The steering ECU 40 is with a direction signal signal lever 41 and a hands-off sensor 42 connected. The direction signal signal lever 41 is an operation unit for intermittently driving (blinking) the turn signal 32 and is mounted in a steering column. The direction signal signal lever 41 It is mounted in such a way that it can be swiveled in the right-handed operating direction (clockwise) as well as in the left-handed operating direction (counterclockwise) with a two-stage actuating path.
As in 4 is the turn signal signal lever 41 configured so that it is selectively in both the right-handed operating direction and in the left-handed operating direction between a first operating position P1L (P1R), in which the direction signal signal lever 41 a first travel is moved out of a neutral position PN (a first angle θW1 is rotated about a support axis O), and a second operating position P2L (P2R) which is a position in which the travel direction signal lever 41 a second travel, which is greater than the first travel, is rotated out of the neutral position PN (a second angle θW2 (> θW1) about the support axis O), and passes further than the first operating position P1L (P1R). The neutral position PN is a position that comes about in a state where the turn signal signal lever 41 is not actuated, that is, a position in which the direction signal 32 is off.
When the driver turns the direction signal lever 41 in the first operating position P1L (P1R) brings, the driver feels this by clicking the direction signal signal lever 41 , Will the to the direction signal signal lever 41 applied actuation force is removed in this state, the direction signal signal lever 41 via a return mechanism (not shown), such as a spring, mechanically returned to the neutral position PN. When the driver turns the direction signal lever 41 into the second operating position P2L (P2R) becomes the turn signal lever 41 Further, by a mechanical locking mechanism (not shown) held in the second operating position P2L (P2R), even if the operating force is removed.
The direction signal signal lever 41 includes a first switch 411L ( 411R ), which is only activated when the turn signal signal lever 41 is set to the first operating position P1L (P1R), and a second switch 412L ( 412R ), which only switches on when the turn signal signal lever 41 is set to the second operating position P2L (P2R).
The first switch 411L ( 411R ) sends an ON signal to the steering ECU 40 while the turn signal signal lever 41 in the first operating position P1L (P1R), and the second switch 412L ( 412R ) sends an ON signal to the steering ECU 40 while the turn signal signal lever 41 is in the second operating position P2L (P2R). The operation positions and switches having the reference numerals set in parentheses in the above description stand for the operating positions and switches related to the counterclockwise operation direction.
When in a state where the turn signal signal lever 41 is held in the second operating position P2L (P2R), the steering wheel is reversely rotated back to the neutral position or the driver the turn signal signal lever 41 in the direction to the neutral position of the direction lever 41 operated back, the lock of the locking mechanism is released and the direction signal signal lever 41 returned to the neutral position PN. That is, when the turn signal signal lever 41 is set in the second operating position P2L (P2R), the direction signal signal lever acts 41 generally in the same way as a turn signal signal flasher device so far. The following is the operating action with which the direction signal signal lever 41 is set to the first operating position P1L (P1R), as a "tap" denotes, and the operating action with which the direction signal signal lever 41 is set to the second operating position P2L (P2R), referred to as "push-through".
Such a designed direction signal signal lever for switching a switching signal with two-stage actuating travel is, for example, from the laid open Japanese Patent Application No. 2005-138647 known. This previously known embodiment can also be used in this embodiment.
The steering ECU 40 sends to the driving support ECU 10 a monitor signal indicating the presence / absence of the tap operation on the turn signal lever 41 that is, an on / off state of the first switch 411L ( 411R ), and a monitor signal indicating the presence / absence of the push-through operation on the turn signal lever 41 that is, an on / off state of the second switch 412L ( 412R ). Hereinafter, the monitor signal that is the on / off state of the first switch 411L ( 411R ), and the monitor signal indicating the on / off state of the second switch 412L ( 412R ), referred to as "push-through monitoring signal". The tap-monitoring signal and the push-through monitoring signal each include a signal for identifying the operation direction (right / left) of the turn signal signal lever 41 ,
The steering ECU 40 also causes the intermittent lighting of that direction signal 32 located on a side corresponding to the direction in which the direction signal signal lever 41 is pressed while the first switch 411L ( 411R ) is turned on. The steering ECU 40 sends to the instrument ECU 30 a turn signal blink command for designating the operation direction (right / left) of the turn signal signal lever 41 so that the intermittent flashing of the turn signal 32 to effect, while the first switch 411L ( 411R ) is turned on. While the instrument ECU 30 receives the turn signal signal command causes the instrument ECU 30 the intermittent illumination of the direction signal 32 located on the side corresponding to the designated direction. This allows the driver to tap the direction signal signal lever 41 Run to the turn signal 32 to light up intermittently.
If a period in which the first switch 411L ( 411R ) is turned on, is shorter than a preset minimum flashing time (that is, when the flashing number of the turn signal 32 smaller than the minimum number of blinks), the steering ECU 40 the direction signal flashing command over the minimum flashing time to the instrument ECU 30 Send to ensure the minimum number of flashing. In this case, it is only important that the driver anti-phasing at the direction signal signal lever 41 immediately executes, so that the direction signal 32 for a set number of times (minimum number of flashes) intermittently lit. When the first switch 411L ( 411R ) is turned on, the steering ECU 40 In addition, the direction signal flashing command to the instrument ECU over a period corresponding to a set flashing number 30 send, so the turn signal 32 as many times as flashes, regardless of the amount of time over which the first switch 411L ( 411R ) is turned on.
While the second switch 412L ( 412R ) is turned on, causes the steering ECU 40 also the intermittent illumination of the direction signal 32 which is located on a side corresponding to the direction of actuation. In this case, the steering ECU sends 40 while the second switch 412L ( 412R ) is switched on, to the instrument ECU 30 a turn signal blink command for designating the operation direction (right / left). While the instrument ECU 30 receives the turn signal signal command causes the instrument ECU 30 the intermittent illumination of the direction signal 32 located on the side corresponding to the designated direction. When executing the push-through operation on the direction signal signal lever 41 therefore takes the intermittent lighting up the direction signal 32 from the beginning of the push-through operation to the execution of the return operation on the direction signal signal lever 41 or on the steering wheel.
The driving support ECU 10 receives the tap-monitoring signal and the push-through monitoring signal. The driving support ECU 10 measures an on-duration of the tap-monitoring signal (duration of the time span over which the first switch 411L ( 411R ) is turned on, that is, duration of the time while wr the direction signal signal lever 41 is held in the first operating position P1L (P1R)) and determines whether the ON duration is as long as or longer than a pre-set assist request confirmation period (eg, one second). When the ON-duration of the tap-monitoring signal is equal to or longer than the assist-request-confirmation period, the drive-assist ECU sets 10 determines that the driver is currently making a request for lane change assistance.
The tap operation of the direction signal signal lever 41 So is an operation to request the lane change assistance request operation, with which the driver requests the lane change assistant. When the tap operation continues beyond the assist request confirmation period or longer, the driver's lane change assistance request is confirmed. That is, when the tap operation continues beyond the assist request confirmation period or longer, the drive assist ECU detects 10 the lane change assistance request of the driver. The lane change assistance control described later is started based on the recognition of the lane change assistance request.
When the push-through monitoring signal is on (when the turn signal signal lever 41 is set in the second operating position P2L (P2R)), also leads the driving support ECU 10 the power steering control (LTA and LCA as described later) is not enough. That is, when the push-through monitoring signal is turned on during the execution of the steering assist control, the drive assist ECU switches 10 the steering assist control and does not turn on the steering assist control in a situation in which the push-through monitoring signal is turned on.
In this embodiment, when the push-through operation is on the turn signal lever 41 is executed, the direction signal signal lever 41 locked in this position, even if the driver takes away the operating force. Alternatively, it can be provided that, even when executing the push-through operation, similar to the tapping operation, the direction signal signal lever 41 by a mechanical return mechanism (not shown) is automatically reset to the neutral position when removing the operating force of the driver. In this case, the configuration sends the steering ECU 40 even if the second switch 412L ( 412R ) is switched from the ON state to the OFF state, the direction signal flashing command for the turn signal 32 on the side corresponding to the direction of actuation, until it is determined on the basis of the steering angle that the steering wheel returns to the vicinity of the neutral position.
The hands-off sensor 42 is an appropriately designed sensor to detect that the driver does not have his hands on the steering wheel. The hands-off sensor 42 sends over the CAN 100 to the driving support ECU 10 a hands-off detection signal indicating whether the driver is holding the steering wheel. During the execution of the lane change assist control and the lane keeping assistance control, when a state in which the driver does not have hands on the steering wheel exceeds a preset manual off determination period or more, the drive assist ECU comes 10 to conclude that a "hands-off condition" actually exists. When the driving support ECU 10 that is, if the hands-off state is true, the drive assist ECU controls 10 the buzzer 13 to warn the driver. This alarm is called a "hands-off warning".
The engine-ECU 50 is with a motor actuator 51 connected. The motor actuator 51 is an actuator (actuator) for changing an operating state of an internal combustion engine 52 , In this embodiment, the internal combustion engine 52 a spark-ignited multi-cylinder engine with gasoline injection and includes a throttle valve for the adjustment of an intake air quantity. The motor actuator 51 includes at least one throttle valve actuator for changing an opening degree of the throttle valve. The engine-ECU 50 can the motor actuator 51 drive and thereby one of the internal combustion engine 52 change generated torque. That of the internal combustion engine 52 generated torque is transmitted via a transmission (not shown) to the drive wheels (not shown). The engine-ECU 50 can thus the motor actuator 51 control to control a driving force of the own vehicle and thereby to change an acceleration state (acceleration).
The brake ECU 60 is with a brake actuator 61 connected. The brake actuator 61 is provided in a hydraulic circuit between a "master cylinder (not shown) configured to pressurize a working fluid in response to a pedaling force applied to a brake pedal" and "friction brake mechanisms 62 provided on the left / right front / rear wheels". The friction brake mechanism 62 includes a wheel-mounted brake disc 62a and a brake caliper fixed to a vehicle body 62b , The brake actuator 61 is designed to apply a hydraulic pressure to one in the caliper 62b wheel cylinder is applied, according to a statement of the brake ECU 60 to adjust to press the wheel cylinder with the hydraulic pressure and thereby a brake pad to the brake disc 62a to push and generate a friction braking force. The brake ECU 60 so can the brake actuator 61 control and thereby regulate the braking force of the own vehicle.
The navigation ECU 70 includes a GPS receiver 71 which is adapted to receive a GPS signal for detecting a current position of the own vehicle, a map database 72 with map information stored in it and the like and a touch screen (touch panel display) 73 , The Navigation ECU 70 identifies the position of the own vehicle at the current time based on the GPS signal and performs various computing processes based on the position of the own vehicle and in the map database 72 stored map information and the like, thereby by means of the touch panel 73 to carry out a route guidance.
The in the map database 72 Stored map information includes road information. The road information includes parameters (eg, road curvature radius or curvature as the cornering degree of the road, and roadway width) that represent the shape of the road for each road section. Further, the road information includes road type information for discriminating whether a road is used exclusively for road traffic and information about the number of lanes.
<Driving and control ECU control operations 10 >
Next are those of the driving support ECU 10 described control and regulatory processes described. In a situation where both the lane keeping assistance control and the adaptive cruise control are executed, the driving support ECU performs 10 the lane change assistance control when the lane change assistance request is confirmed. Against this background, first the lane keeping assistance control and the adaptive cruise control will be described.
<Lane Keeping Assistance Control (LTA)>
The lane keeping assistance controller provides the steering torque to the steering mechanism so that the position of the own vehicle in the vicinity of the target line is kept within a "lane traveled by the own vehicle" and thereby the driver's steering action is assisted. In this embodiment, the target driving line is the lane centerline CL, but as the target driving line, a line offset in the road width direction by a predetermined distance from the track centerline CL may also be used.
Hereinafter, the lane keeping assistance control will be referred to as Lane Trace Assist ("LTA"). The LTA is well known (see for example the Japanese Laid-Open Patent Application No. 2008-195402 , the Japanese Laid-Open Patent Application No. 2009-190464 , the Japanese Laid-Open Patent Application No. 2010-6279 and the Japanese Patent Publication No. 4349210 ), but the actual LTA is denoted by different names. Below is a brief description of the LTA.
The driving support ECU 10 is designed to execute the LTA when the LTA is operated by a control action on the setting control unit 14 is requested. When requesting the LTA, the driving support ECU calculates 10 every time after a predetermined time (calculation period), a target steering angle θlta * according to the formula expression ( 1 ) based on the above-mentioned vehicle-related vehicle information (Cu, Dy, and θy). θ lta * = Klta1 ⋅ Cu + Klta2 ⋅ θ y + Klta3 ⋅ Dy + Klta4 ⋅ Σ D y
Klta1, Klta2, Klta3 and Klta4 in formula (1) are control amplifications. The first term on the right side is a steering angle component that is determined according to the road curvature Cu and feeds forward. The second term on the right side is a steering angle component that is feedback-controlled, so that the yaw angle θy is decreased (so that the direction difference of the own vehicle to the track center line CL becomes smaller). That is, the second term on the right side is a steering angle component calculated by the feedback control in which the target value of the yaw rate θy is set to zero. The third term on the right side is a steering angle component that feedback-operates, so that the lateral deviation Dy, which is a positional offset (position difference) in the road width direction between the own vehicle and the track centerline CL, is reduced. That is, the third term on the right side is a steering angle component calculated by the feedback control in which the target value of the side difference Dy is set to zero. The fourth term on the right side is a steering angle component that is feedback-connected, so that an integral value ΣDy of the lateral deviation Dy is reduced. That is, the fourth term on the right side is a steering angle component calculated by the feedback control in which the target value of the integral value ΣDy is set to zero.
A target steering angle θlta * becomes an angle to which the own vehicle has to steer to the left, for example, when the track center line CL describes a left turn (curved to the left), the Own vehicle with respect to the track center line CL laterally deviates to the right / is offset and points in a direction to the right of the track center line CL. Further, a target steering angle θlta * becomes an angle to which the own vehicle has to steer rightward when the track centerline CL describes a right turn (curved rightward), the own vehicle deviates laterally leftward from the track centerline CL, and in FIG pointing to the left of the track center line CL direction. Therefore, when using the formula (1), the calculation must be performed only with the symbols corresponding to the right / left direction.
From the driving support ECU 10 will be sent to the EPS-ECU 20 outputting a command signal representing the target steering angle θlta * resulting from the calculation. The EPS-ECU 20 controls the drive of the steering motor 22 so that the steering angle follows the target steering angle θlta * (whose value assumes). In this embodiment, the driving support ECU outputs 10 to the EPS-ECU 20 the command signal representing the target steering angle θlta *, but the driving support ECU 10 For calculating the target steering angle θlta *, it can calculate a target torque and send it to the EPS-ECU 20 output a command signal representing the target torque resulting from the calculation.
The LTA is used only to assist the driver's driving action so that the driving position of the own vehicle follows the lane center line CL. Therefore, even when the LTA is being carried out, "hands-free" driving is not permitted and the driver must hold the steering wheel (steering wheel operation is not necessary).
Above is a short description of the Lane Keeping Assist (LTA).
When a vehicle immediately precedes the own vehicle, the adaptive cruise control (distance cruise control) based on the surrounding information ensures that the own vehicle follows the preceding vehicle while keeping a predetermined distance between the preceding vehicle and the own vehicle. Without the presence of a preceding vehicle, the adaptive cruise control causes the driving of the own vehicle with a constantly adjusted vehicle speed. Hereinafter, the adaptive cruise control is referred to as "ACC" (Adaptive Cruise Control). The ACC itself is well known (see for example the Japanese Laid-Open Patent Application No. 2014-148293 , the Japanese Laid-Open Patent Application No. 2006-315491 , the Japanese Patent Publication No. 4172434 and the Japanese Patent Publication No. 4929777 ). Below is a brief description of the ACC.
The driving support ECU 10 is designed so that it executes the ACC, if this by an operator action on the setting control unit 14 is requested. That is, the driving support ECU 10 is designed so that when requested by the ACC on the basis of the environmental sensors 11 captured environmental information selects a vehicle as a follow-up target. The driving support ECU 10 determines, for example, whether a relative position of the detected object (n) identified by a side distance Daccy (n) and a vehicle distance Daccx (n) of the object (n) is within a predetermined following target vehicle range. The following target vehicle range is defined so that the lateral distance decreases as the distance between the vehicles (vehicle distance) increases. The driving support ECU 10 then selects the object (s) as the successive target vehicle when the relative position of the object indicates that the object is in the subsequent target vehicle range for a period of time equal to or greater than a predetermined time period.
Further, the driving support ECU calculates 10 a desired acceleration Gacc * according to one of the formulas ( 2 ) and ( 3 ). In formula (2) and formula (3), Vaccx (a) is a relative velocity of a following target vehicle (a), Kaccl and Kacc2 are predetermined positive gains (coefficients) and ΔDacc is a vehicle spacing difference (= Daccx (a) -Dacc *) for whose detection the "target vehicle distance Dacc * is subtracted from a vehicle distance Daccx (a) of the following target vehicle (a)". To calculate the target vehicle distance Dacc *, a driver uses the setting operation unit 14 set target vehicle distance Tacc * is multiplied by the vehicle speed V of the own vehicle (that is, Dacc * = Tacc * * V).
The driving support ECU 10 uses formula (2) for determining the target acceleration Gacc * when the value (Kacc1 * ADacc + Kacc2 * Vaccx (a)) is positive or "0". Kaccal is a positive gain (coefficient) for acceleration and is set to a value equal to or less than "1".
The driving support ECU 10 uses formula (3) for determining the target acceleration Gacc * when the value (Kacc1 * ΔDacc + Kacc2 * Vaccx (a)) is negative. Kaccdl is a gain (coefficient) for deceleration and is set to "1" in this example. GACC * ( For acceleration ) = Kacca1 ⋅ ( KAcc1 ⋅ Δ Dacc + KAcc2 ⋅ Vaccx ( a ) )
GACC * ( For Slowdown ) = Kaccd1 ⋅ ( KAcc1 ⋅ Δ Dacc + KAcc2 ⋅ Vaccx ( a ) )
If there is no object in the following target vehicle area, the driving support ECU determines 10 the target acceleration Gacc * based on a target speed Tacc * set according to the target vehicle distance and the vehicle speed V so that the vehicle speed V corresponds to the set target speed.
The driving support ECU 10 uses the engine-ECU 50 for controlling the motor actuator 51 and uses the brake ECU as needed 60 for controlling the brake actuator 61 in such a way that the acceleration of the own vehicle corresponds to the desired acceleration Gacc * (ie assumes its value).
While the ACC is reading the driving support ECU 10 also from the navigation ECU 70 Information that represents the curvature of the road as a predetermined leading distance to the position of the own vehicle (pre-detection of the road curvature), and sets for the own vehicle, an upper speed limit, which decreases with increasing the curvature (narrowing of the curve), thereby the vehicle speed so to limit that the vehicle speed of the own vehicle does not exceed the upper speed limit. In the following, this regulation is referred to as "speed management".
The above is a brief description of adaptive cruise control (ACC).
<Lane Change Assistance Control (LCA)>
The lane change assist control refers to the following control. After monitoring the environment of the own vehicle and determining that the own vehicle can safely change the lane, the lane change assistance controller provides / generates a steering torque to the steering mechanism so that the lane change assistance control causes the own vehicle to be moved from the lane in which it is currently traveling Monitoring the environment of the own vehicle to the adjacent lane changes. This supports the steering action of the driver (lane change operation). The lane change assistance control can thus cause the own vehicle to change its lane without steering action (steering wheel operation) of the driver. In the following, the lane change assistance control is called "LCA" (Lane Change Assist).
Similar to the LTA, the LCA is the control of a lateral position with respect to the lane of the own vehicle which is executed in place of the LTA when the lane change assistance request is accepted while the LTA and the ACC are being executed. Hereinafter, the LTA and the LCA will be collectively referred to as "steering assist control", and the state of the assist steering control will be referred to as "assist steering state".
<Calculation of the target trajectory>
When the driving support ECU 10 executing the LCA calculates the driving support ECU 10 a desired trajectory of the own vehicle on the basis of the current time from the camera sensor 12 provided trace information and based on the vehicle state of the own vehicle. The target trajectory is a trajectory along which the own vehicle travels over the target lane change time period from the lane currently being traveled by the own vehicle (referred to as "output lane") to a widthwise central position (referred to as "final page target position") of the vehicle Direction of Lane change assistance request predetermined lane adjacent the outgoing lane (referred to as "destination lane"). The desired trajectory has, for example, a shape as in 5 illustrated. The target trajectory is represented by means of a side target position y (t) of the own vehicle with respect to the track center line CL of the output track (see 3 ), where "t" is an elapsed time (duration) from the start time (start time of operation) of the LCA.
In this embodiment, the target lane change period is set to be variable in relation to the lateral movement distance of the own vehicle to the final page target position (hereinafter referred to as "necessary side clearance.") If the track width is 3.5 m as in the case of general traffic roads, the This example corresponds to the case where the own vehicle is positioned at the start timing of the LCA on the lane centerline CL of the output lane 12. For example, with a lane width of 4.0 m, the target lane change period is set to one of the lane change lenghts Track width set corresponding value, in this example to 9.1 seconds (= 8.0x4.0 / 3.5).
In addition, when the lateral position of the own vehicle with respect to the track center line CL of the output track is offset toward the lane change side at the start of the LCA, the target lane change period is set to decrease correspondingly with increasing lateral displacement (lateral deviation Dy). On the other hand, at the start of the LCA, when the lateral position of the own vehicle with respect to the track center line CL of the output track has an offset away from the lane change side, the target lane change period is set to increase correspondingly with increasing lateral displacement (lateral deviation Dy). For example, if the lateral deviation is 0.5 m, the increasing / decreasing correction amount of the target lane change period may be 1.14 seconds (= 8.0 × 0.5 / 3.5).
In this embodiment, a lateral target position y is calculated according to a page target position function y (t) expressed in formula (4). The page position function y (t) is a fifth order function using the elapsed time t. y ( t ) = a ⋅ t 5 + b ⋅ t 4 + c ⋅ t 3 + d ⋅ t 2 + e ⋅ t + f
The calculation of the constants a, b, c, d, e and f in formula (4) is based on the running state of the own vehicle, the lane information, the target lane change time duration and so on at the time of calculation. In this embodiment, a pre-stored vehicle model is used, and the running state of the own vehicle, the lane information, and the target lane change period are input to the vehicle model. The abovementioned constants a, b, c, d, e and f are thus calculated so that a soft setpoint trajectory can be obtained. The calculated constants a, b, c, d, e and f are substituted into the formula (4) to obtain the page target function y (t). The elapsed time t from the start time of the LCA is set in the page target position function y (t), whereby the page target position at the appropriate time can be determined. In this case, f represents an initial side position of the own vehicle when t = 0 is satisfied, that is, when the LCA is started, and thus f is set to a value equal to the lateral deviation Dy.
The page target position y can be set by any method. Apart from the above-mentioned calculation method, for example, the driving support ECU 10 prestore a plurality of lateral position functions y (t) each having the constants a to f set for each necessary lateral distance as required for laterally moving the own vehicle to the final page target position, and the driving support ECU 10 For example, at the start of the LCA, one of the multiple lateral position functions y (t) may select a lateral position function y (t) corresponding to the required lateral distance and the used target lane change time period.
In addition, the landing page position y does not have to be calculated using the function of fifth order and can be determined by means of an appropriately set function.
<Calculation of the target steering angle>
The driving support ECU 10 runs the LTA before starting the LCA. In the LTA, the target steering angle is calculated as described above, and the steering torque is generated so that the actual steering angle coincides with (matches) the target steering angle. Also in the LCA will be similar to in the LTA the target steering angle of the driving support ECU 10 calculated and the steering torque is generated so that the actual steering angle coincides with the target steering angle (matches).
When calculating the target steering angle for the LCA, only the nominal values of the curvature, the yaw angle and the lateral deviation must be changed in the calculation formula of the target steering angle of the LTA. That is, in the LTA, the target value of the curvature is set to the curvature of the track traveled by the own vehicle, and the target values of yaw angle and lateral deviation are set to zero. On the other hand, in the LCA, a target curvature Cu *, a target yaw angle θy *, and a target lateral deviation Dy * are determined based on the shape of the target trajectory expressed by formula (4).
The driving support ECU 10 Each time a predetermined time period (calculation time) elapses, a target steering angle θlca * is calculated as a control amount of the LCA based on the formula (5). θ lca * = Klca1 ⋅ Cu * + Klca2 ⋅ ( θ y * - θ y ) + Klca3 ⋅ ( Dy * - Dy ) + Klca 4 ⋅ Σ ( Dy * - Dy )
In formula (5), for θy and Dy, the values (Cu, Dy and θy) included in the lane-related information at the present time (at the time of calculation) are used. Klca1, Klca2, Klca3 and Klca4 are regular reinforcements.
The first term on the right side is a steering angle component that feeds forward and is determined according to the road curvature Cu * determined by the shape of the target trajectory. The second term on the right side is a steering angle component that is feedback-reducing, so that the difference between the target yaw rate θy * determined by the shape of the target trajectory and the actual yaw rate θy decreases. The third term on the right side is a steering angle component that is feedback-reducing, so that the difference between the target lateral deviation Dy * determined by the shape of the target trajectory and the actual lateral deviation Dy decreases. The fourth term on the right side is a steering angle component that is feedback-connected, so that an integral value Σ (Dy * -Dy) of the difference between the target lateral deviation Dy * and the actual lateral deviation Dy is reduced. In this way, the target steering angle θlca * is calculated as a control amount of the LCA, and thereby a smooth transition from the LTA to the LCA can be achieved.
The driving support ECU 10 sends every time the driving support ECU 10 calculates the target steering angle θlca *, a steering command representing the target steering angle θlca * to the EPS-ECU 20 , In this way, the own vehicle moves when changing lanes along the target trajectory.
<Steering assist control routine>
The following is the description of the steering assist control for changing control states of LTA and LCA. 6 shows one of the driving support ECU 10 to be performed Lenkhilfssteuerroutine. When an ignition switch is turned on, the driving support ECU leads 10 the power steering control routine repeatedly.
Upon activation of the steering assist control routine, the driving support ECU determines 10 in step S11, whether the preset LTA start condition is satisfied.
For example, the LTA start condition is satisfied when the following conditions are all met.
1-1. Execution of the LTA was over the adjustment control unit 14 selected.
1-2. The ACC is currently running.
1-4. The white lines were recognized.
1-5. A push-through operation of the direction signal signal lever 41 was not recognized.
The LTA start condition is not limited to the above conditions and can be set as needed.
If the LTA start condition is not satisfied (S11: No), the drive assist ECU sets 10 proceeds to process step S12 and turns off the steering assist control state to LTA. The LTA OFF state is a control state in which the LTA is not executed. In the LTA OFF state, therefore, the driver must manually perform a steering action (steering wheel operation).
When the driving support ECU 10 sets the power steering control state to the state LTA OFF, the driving support ECU returns 10 back to step S11. The driving support ECU 10 repeats these operations (S11 to S12) until the LTA start condition is satisfied.
If the LTA start condition is satisfied (S11: Yes), in step S13, the drive assist ECU 10 the steering assist control state to LTA ON. The state LTA ON represents a control state in which the LTA is executed. That is, the driving support ECU 10 starts the LTA.
Subsequently, the driving support ECU determines 10 whether that's from the steering ECU 40 Sent tap monitoring signal "OFF" is (whether both first switches 411L and 411R are in the OFF state). The state in which the tap-monitoring signal is "OFF" represents the state in which the driver does not execute the tap operation, that is, the state in which the lane change assistance request operation is not executed. In other words, this state represents the state in which the non-operating state of an embodiment of the present invention is recognized.
When the tap-monitoring signal is "OFF", the driving support ECU sets 10 the processing proceeds to step S15. On the other hand, if the tap-monitoring signal is not "OFF", the driving support ECU repeats 10 the determination step of step S14 with execution of the LTA. This sets the driving support ECU 10 the processing proceeds to step S15 only if the tap-monitoring signal is "OFF".
When the driving support ECU 10 detects that the tap monitor signal is "OFF" (S14: Yes), puts the driving support ECU 10 in step S15, the steering assist control state to an LCA-acceptable state. When the steering assist control state is the LCA acceptable state, the state LTA continues to ON, and the determination processes (S16-S19) directed to the acceptance of the LCA are repeated.
When the steering assist control state is set in the LCA acceptable state, the driving support ECU determines 10 whether the tap operation signal is "ON" (whether the first switches 411L respectively. 411R in an ON state). The driving support ECU 10 performs these two steps S14 and S16 so that the driving support ECU 10 in a situation where the turn signal signal lever 41 was in the idle state, can determine whether the lane change request operation operation is being executed.
If the tap monitoring signal is not "ON" (S16: No), the driving support ECU is set 10 in step S17, a value of a timer (referred to as "timer value Tx") for counting an ON period in which the tap monitoring signal is "on" all the time (an ON-switching period during which the first switches 411L respectively. 411R remain in the on state) back (Tx = 0) and returns to step S15. In a first execution of the determination process of step S16, the determination result of step S16 is inevitably "no", since it is determined in step S14 that the tap-monitoring signal is "OFF". Thus, the timer value Tx is inevitably reset.
These processes are repeated, and when the tap-monitoring signal is on ("ON"), the driving support unit increases 10 in step S18, the timer value Tx by "1". Subsequently, the driving support ECU determines 10 in step S19, whether the timer value Tx is equal to or greater than an assist request confirmation period Tref.
The assistance request confirmation period Tref is a period for confirming the driver side request of the lane change assistant. For example, the assistance request confirmation period Tref is set to about one second.
When the timer value Tx does not reach the assistance request confirmation duration Tref (when the duration of a tap operation of the turn signal signal lever 41 does not reach the assistance request confirmation period Tref by the driver) repeats the driving support ECU 10 the process with step S15. As a result, the LTA continues unchanged.
If, during the repetition of these processes, the tap-monitoring signal is turned off (when the driver taps the turn-signal lever 41 finished) before the timer value Tx reaches the assistance request confirmation period Tref sets the driving support ECU 10 the timer value Tx back (S16: No, S17).
On the other hand, when the timer value Tx reaches the assistance request confirmation period Tref (S19: Yes), the driving support ECU determines 10 in step S20, whether an LCA start condition is satisfied. When the timer value Tx reaches the assistance request confirmation period Tref, the driving support ECU comes 10 As a result, the driver has requested the lane change assistance. In other words, when the timer value Tx reaches the assistance request confirmation period Tref, the driving support ECU recognizes 10 the lane change assistance request of the driver.
For example, the LCA start condition is satisfied when the following conditions are all met.
2-1. Execution of the LCA was via the setting control unit 14 selected.
2-2. The white line on one side, which corresponds to the direction of travel signal operation (white line serves as the boundary line between output lane and destination lane), is a broken line.
2-3. The determination of whether the LCA can be performed comes to YES (from the environmental sensors) based on environmental monitoring 11 if no object (other vehicle or the like) has been identified as an obstacle that damages the lane and it is determined that the own vehicle can safely change lanes).
2-4. The road is a road for exclusive use by motor transport (from the navigation ECU 70 detected road type information indicates a road dedicated to traffic only).
The condition 2 - 3 is satisfied, for example, if the vehicle distance between the own vehicle and another vehicle traveling in the destination lane is adequately secured taking into account a relative speed between the vehicles.
The LCA start condition is not limited to the above conditions and can be set as needed.
If the LCA start condition is not satisfied, the drive assist ECU returns 10 to step S15 to repeat the above process. This is how the driving support ECU counts 10 the duration of the tap operation on the direction signal signal lever 41 and determines whether the LCA start condition is satisfied or not.
If the LCA start condition is satisfied (S20: Yes), the drive assist ECU sets 10 the process proceeds to step S21, and sets the steering assist control state to a state LCA. This completes the driving support ECU 10 the previously performed LTA and starts the LCA. In other words, when the LCA start condition is satisfied, the driving support ECU decreases 10 in step S20, the driver's lane change assistance request to start the LCA.
When the driving support ECU 10 the LCA starts, leaves the drive support ECU 10 the buzzer 13 Temporarily sound to inform the driver about the start of the LCA. The driving support ECU 10 can, for example, on the display of the display unit 31 display a screen to inform the driver about the start of the LCA. In this case, the driving support ECU sends 10 a display command indicating the LCA start to the instrument ECU 30 , The instrument ECU 30 shows the driver notification of the start of the LCA on the display unit 31 according to the display command.
When the driving support ECU 10 the LCA starts, causes the driving support ECU 10 after expiration of a predetermined hold duration (standby duration) starting from the acceptance of the lane change assistance request, the vehicle is changed over to the destination lane. A condition in which the direction signal 32 flashes intermittently without significant lane change operation (flashing), lasts in this way for a predetermined period of time. The steering control performed during this hold time is identical to the LTA.
The driving support ECU 10 sets a target steering angle θlca * and sends a steering command representing the target steering angle θlca * to the EPS-ECU 20 while the driving support ECU 10 executes the LCA. In this way, the own vehicle moves when changing lanes along the target trajectory.
The driving support determines whether an LCA completion condition is satisfied in step S22 after the start of the LCA.
The LCA completion condition is satisfied when a time elapsed from the start of the LCA reaches a target lane change period. The target lane change period is a period during which the own vehicle reaches the target lane, in other words, a period in which the vehicle makes lane change by a single lane. The LCA termination condition therefore implies an LCA termination condition for a simple lane change from the output lane to the lane (destination lane) immediately adjacent to the output lane. The driving support ECU 10 repeats the determination process of step S22 until the LCA completion condition is satisfied. If the LCA completion condition is satisfied (S22: Yes), the drive assist ECU closes 10 the LCA and provisionally terminates the power steering control routine. After the lapse of a predetermined short period of time after the preliminary completion of the steering assist control routine, the driving support ECU starts 10 the power steering control routine new. Thereby, when the LTA start condition is satisfied at a time of restarting the power steering control routine, the LTA is started. In other words, instead of the LCA, the LTA is executed. In this case, the driving support ECU determines 10 in steps S14 and S16, whether to start the lane change assistance request operation. When after the completion of the one-lane LCA (LCA for one-lane change), the lane change assist request operation is re-executed (when the tap operation is performed after the turn signal signal direction lever 41 returned to the neutral position), the LCA can be restarted to a next adjacent track.
The driving support ECU 10 determines whether a preset LTA cancellation condition is met while the driving support ECU 10 executes the LTA (S15-S20). If the LTA abort condition is met (for example, if the LTA start condition is no longer met), the drive assist ECU may 10 to return the process to step S12. The driving support ECU 10 determines whether a preset LCA cancellation condition is met while the driving support ECU 10 executes the LCA (S21-S22). If the LCA cancellation condition is met (for example, if the LCA start condition ceases to exist), the driving support ECU may 10 in the process, go back to step S11.
10 shows as an example a screen display 31a (referred to as "LTA screen 31a") displayed during the execution of the LTA on the display unit 31 is displayed, and a screen display 31b (referred to as "LCA screen 31b") displayed during the execution of the LCA on the display unit 31 is pictured. The LTA screen 31a and the LCA screen 31b each represent a state in which the own vehicle travels between a left white line and a right white line in a lane. On the LTA screen 31a are displayed outside the left white line and the right white line virtual walls W. On the walls W, the driver can recognize that there is a state in which the own vehicle is controlled to travel within the lane. The walls W, however, are on the LCA screen 31b not displayed and in place of the walls W will be on the LCA screen 31b a trajectory Z shown. The driving support ECU 10 Switches between the LTA screen 31a and the LCA screen 31b in response to an execution state of the power steering control. In this way, the driver can easily see if the LTA or the LCA is being executed.
The driving support ECU 10 performs a turn signal flashing control routine in parallel to the steering assist control routine. The from the driving support ECU 10 running direction signal flashing control routine is in 7 illustrated.
Upon activation of the turn signal flashing control routine, the driving support ECU determines 10 in step S51, if the LCA has been started. In this determination process, the driving support ECU 10 only determine if the LCA start condition has occurred or not. The driving support ECU 10 repeats the determination process of step S51 until the LCA is started.
With and after the start of the LCA starts the driving support ECU 10 in step S52 therewith, the flashing command of the turn signal 32 according to the direction of travel signal actuation direction to the instrument ECU 30 to send. The intermittent flashing (flashing) of the direction signal 32 is started in response to a flashing command from the steering ECU 40 sends when the tap operation on the direction signal signal lever 41 is executed before the LCA is started. Even if (after) the steering ECU 40 stops sending the flashing command, the intermittent flashing of the turn signal is required 32 in response to the driver assistance ECU 10 Flashing command sent in step S52.
Then, the driving support ECU determines 10 in step S53, whether a turn signal switch off condition is satisfied. The turn signal switch off condition is satisfied when the following conditions 3 - 1 and 3 - 2 both are fulfilled.
3-1. The own vehicle has already crossed the white line.
3-2. The lateral distance between the current position of the own vehicle and the final side target position is equal to or smaller than a turn-off permission distance.
The condition 3 - 1 is met, for example, if it is determined that the reference point P of the own vehicle has crossed over the white line (broken line) serving as the boundary between the output lane and the target lane. In addition, the condition 3 - 2 met when a condition is detected in which, as in 6 1, a side-facing distance Dyr from the reference point P of the own vehicle C to a track centerline CL 'of the target track assumes a value equal to or less than a turn-off permission distance Doff that is greater than zero. The lateral direction distance Dyr is a track width direction distance from the current position of the host vehicle to the final target position, that is, the required distance distance remaining in the track width direction until completion of the LCA, and thus this lateral direction distance Dyr is hereinafter referred to as "residual distance Dyr". The driving support ECU 10 Each time after a predetermined period of time (calculation time), the remaining distance Dyr is calculated from the reference point P of the own vehicle to the track centerline CL 'of the target track and compares the remaining distance Dyr with the turn-off permission distance Doff so as to determine whether the above-mentioned condition 3 - 2 is satisfied. The test for the existence of condition 3 - 1 used reference point P is not limited to the position of the center of gravity and has as the only requirement that it is a pre-set special position (a specific point) of the own vehicle. Moreover, in determining whether the reference point P crosses the white line, it only has to be determined whether the reference point P crosses a predetermined line, for example, an inner line, an outline or a center line of the white line.
The turn-off permission distance Doff is set to a value greater than zero (eg, 50 cm) such that the turn signal 32 is turned off before the LCA is completed.
The driving support ECU 10 repeats the determination process of step S53 until the turn signal switch-off condition is satisfied. When the turn signal switch off condition is satisfied (S53: Yes), the drive assist ECU stops 10 in step S54, with the transmission of the flashing command of the turn signal 32 and temporarily terminates the turn signal flashing control routine. Upon expiration of a predetermined short period of time after the provisional termination of the turn signal flashing control routine, the drive assist ECU starts 10 the turn signal flashing control routine.
5 shows an example of the trajectory of the own vehicle when executing the LCA. At a time tl, the intermittent flashing of the turn signal becomes 32 in response to the tapping operation of the direction signal signal lever 41 started. At a time t2 at which the duration of the tap operation reaches the assistance request confirmation period Tref, the drive assist ECU recognizes 10 the lane change assistance request.
When the LCA start condition is given, the drive assist ECU takes 10 the lane change assistance request, starts the LCA and begins the flashing command of the turn signal 32 to the instrument ECU 30 to send. A standby state with inhibition of the lane change process of the own vehicle lasts until the lapse of the standby duration starting from the start of the LCA. The steering control performed during this hold time is identical to the LTA.
At a time t3 at which the standby duration ends, the own vehicle begins to drive off the setpoint trajectory. When the own vehicle has crossed the white line and the remaining distance Dyr becomes equal to or less than the turn-off permission distance Doff (time t4), the turn signal is turned off. Subsequently, when the own vehicle reaches the final page target position (time t5), the LCA is completed.
When the lane change assist request is detected and it is determined that the own vehicle can safely change the lane due to an environment condition of the own vehicle, the LCA is executed. This may result in the driver overestimating (or over-reliant on) the lane change assist device and / or neglecting / neglecting autonomous monitoring of one's own vehicle environment. So it may be that the driver is the decision making process about the start of the Lane change assistance control fully relinquishes the lane change assist device. For example, the driver may be the tapping operation of the turn signal signal lever 41 extended (that is, the driver the turn signal signal lever 41 in the first operating position P1L (P1R) leaves), as if he wants to pre-reserve the lane change assistant. However, if the tap operation is continued for a long time, there may be the case that a driver's unintentional lane change (for example, an extra lane change) is executed. Thus, it may be that the lane change assistance control to an adjacent lane is unintentionally restarted by the driver after the own vehicle has made the lane change.
Against this background, the lane change assist device according to the present embodiment is configured to:
Confirm that the lane change request operation on the turn signal lever 41 is not executed (S14);
Determining whether the lane change assistance request operation (the tap operation) is being executed (S16) under the condition that it is confirmed that the lane change assistance request operation is on the turn signal lever 41 not executed (S14: Yes).
In addition, in a situation where it has been recognized that the time period of the lane change request operation is equal to or greater than the assistance request confirmation period Tref, the LCA start condition is satisfied, the lane change assist device assumes the lane change assistance request to perform the LCA by one track (FIG. wherein the LCA causes the subject vehicle to change from the output track to the track immediately adjacent to the output track). In addition, the lane change assisting device does not assume the new lane change assistance request operation during the LCA since the lane change assisting device does not determine whether the lane change assistance request operation is executed during the LCA (S20-S22).
Therefore, the lane change assist device of this embodiment assumes the lane change assistance request only when the following two conditions are satisfied.
• The tap of the turn signal lever 41 starts in a situation where the tap operation is not recognized, and the duration of the tap operation is as long as or longer than the assist request confirmation period Tref.
• The LCA start condition is fulfilled.
The lane change assist device is configured to respond to the lane change assist request in response to the tap operation to the turn signal signal lever 41 during a period of time from the start of the LCA until the completion of the LCA is executed (started) is not accepted.
In this way, the LCA is not further executed (extended) even if the lane change request operation on the turn signal lever 41 is continued (the direction signal signal lever 41 is operated so that it is held in the first operating position P1L (P1R)) The driver must therefore every time he wants to take the LCA assistant, a new operation to request the lane change assistance on the direction signal signal lever 41 To run.
If the driver does not monitor the surroundings of the own vehicle and, during the execution of the LCA, the lane change assistance request operation on the turn signal lever 41 continues as if pre-reserving the further lane change, the LCA will not start to lane change (to) to the next adjacent lane. Thereby, the lane change assist device can prevent the driver from executing the lane change assistance request operation in the context of overestimation of the lane change assist device (or over-reliance on the lane change assist device).
According to the lane change assist apparatus for a vehicle according to this embodiment, the LCA is not further executed when the driver performs the lane change assistance request operation longer. Therefore, according to the present embodiment, the driver unintentional LCA is not started even if the lane change assistance request operation of the driver is due to overestimation of the apparatus. The lane change assist device may prevent the driver from performing an improper operation due to overestimation of the lane change assist device. In addition, the lane change assist device can prevent the driver from neglecting to monitor the own vehicle environment.
In addition, the lane change assist device can prevent the start of the LCA in the event of technical errors including the following errors. Such an error is an error (pad error) in which a pad of the first switch 411L ( 411R ) remains in a position which, in a situation in which the tap operation is not performed, the "ON" state of the first switch 411L ( 411R ) causes. Another error is an error (communication error) in which the tap-stop signal remains in the "ON" state due to the communication error.
In addition, it may happen that the driver, if he wants to perform the lane change manually, the direction signal signal lever 41 completely pushed through according to the lane change direction. That is, the flashing of the turn signal 32 can be effected without starting the lane change assistant. Therefore, by selecting the Betätigungsweges on the direction signal signal lever 41 automatic lane change or manual lane change are selected. This makes it possible to achieve a very high level of user-friendliness. In addition, to trigger the lane change assistance request, the turn signal signal lever 41 is used, so that a special control unit for the request for lane change assistance is unnecessary. This enables a reduction in costs and space savings.
In order for the lane change assistance request to be assumed as such, it is also necessary that the tap action of the direction signal signal lever 41 over the Assistance Request Confirmation Duration Tref or longer. As a result, the driver's intention to claim the lane change assistance can be recognized correctly
<Modification Example of Power Steering Control Routine>
In the above embodiment, a "condition that the LCA has been completed" is set as a prerequisite condition for restarting the LCA (referred to as "restart permission condition"). In contrast, in this modification example, a "condition that the turn signal 32 "OFF" is (or already turned off) "set as a restart permission condition. The direction signal 32 is switched off immediately before the completion of the LCA. In this modification example, after turning off the turn signal 32 is executed (started) lane change assistance request operation as an operation to request a lane change assistance. The LCA is started when the LCA start condition in a situation in which the duration of the turn-off the turn signal 32 started lane change assistance request operation is equal to or greater than the assistance request confirmation period Tref.
9 Fig. 10 is a part of a flowchart for illustrating the power steering control routine of the modification example. The power steering control routine of the modification example is the same routine as the power steering control routine of the embodiment (FIG. 6 ), except that steps S31 to S38 are added. In 9 only the steps following the step S20 (the steps added to the steering assist control routine of the embodiment) are shown (omitting the steps S11-S19 included in the embodiment). Now, the added steps will be described.
When the driving support ECU 10 In step S21, the LCA starts, determines the driving support ECU 10 in step S31, if the turn signal switch off condition is satisfied. That is, when the remaining distance Dyr reaches or falls below the turn-off permission distance Doff, the drive assist ECU comes 10 in step S31, to a determination result "Yes".
In step S31, the driving support ECU 10 determine if the direction signal 32 is turned off because the direction signal 32 is turned off when the turn signal switch-off condition is satisfied.
The driving support ECU 10 The process proceeds to step S22 and determines whether the LCA completion condition is met while the turn signal switch off condition is not satisfied. If the turn signal switch off condition is satisfied, the drive assist ECU determines 10 in step S32, whether that is from the steering ECU 40 sent stop watch signal is "OFF". This determination step is identical with step S14. If the tap-monitoring signal is not "OFF", the driving support ECU sets 10 The process proceeds to step S22 and determines whether the LCA completion condition is met.
The driving support ECU 10 repeats these steps, and when it is detected during a period from the occurrence of the turn signal OFF condition to the occurrence of the LCA completion condition that the tap monitor signal is "OFF" (S32: Yes), the drive assist ECU determines 10 in Step S33, if the tap-monitoring signal is "ON". The driving support ECU 10 performs these steps S32 and S33 to allow the ECU 10 in the non-operating state of the direction signal signal lever 41 may determine whether the lane change assistance request operation is executed after the occurrence of the turn signal switch-off condition.
If the tap monitoring signal is not "ON" (S33: No), the driving support ECU is set 10 the timer value Tx for counting the ON-duty of the tap-back signal back (Tx = 0) and the process to step S22.
If the tapping watch signal is turned on during the repetition of these processes (S33: Yes), the driving support unit increases 10 in step S35, the timer value Tx by "1". Subsequently, the driving support ECU determines 10 in step S36, whether the timer value Tx is equal to or greater than the assist request confirmation period Tref.
When the timer value Tx does not reach the assistance request confirmation duration Tref (when the duration of a tap operation of the turn signal signal lever 41 has not reached the assistance request confirmation period Tref by the driver) sets the driving support ECU 10 proceed to step S22. As a result, the LTA continues unchanged.
During the repetition of these steps, if the timer value Tx reaches the assistance request confirmation period Tref during the time from the completion of the turn signal turn-off condition until the fulfillment of the LCA completion condition, the drive assist ECU determines 10 in step S37, if the LCA start condition is satisfied. The recognition of the lane change assistance request takes place with and after reaching the assistance request actuation duration by this timer value Tx.
When the LCA start condition is satisfied (S37: Yes), the driving support ECU changes 10 in step S38, the target lane from the current target lane to a target lane adjacent to the current target lane in a direction corresponding to the direction of actuation of the direction signal signal lever 41 equivalent. Then the driving support ECU starts 10 the LCA again to this newly changed destination lane and returns the process to step S21. The steering assist control state is accordingly set to the state LCA ON, in which the target lane is set to the newly changed target lane. The flashing of the direction signal 32 will be started at this time. That is, the LCA restart condition is satisfied in step S37 only when the turn signal switch off condition is satisfied.
According to this power steering control routine of the modification example, the power is turned off after turning off the turn signal 32 executed lane change assistance request operation treated as an operation to request the new lane change assistance. The driver usually thinks that turning off the turn signal will complete the LCA.
The lane change assistance request in response to a start of the tap operation of the turn signal signal lever 41 after switching off the direction signal 32 thus represents an intention of the driver to claim the new lane change assistance. An already made execution of the tap operation of the direction signal signal lever 41 on the other hand, before a turn-off time of the turn signal can be an operator action with which he pre-reserves the next lane change assistance by relying too much on the (and overestimating) the lane change assist device.
In view of the above, in the power steering control routine of this modification example, the tap operation that occurs during the period from the start of the LCA to the completion of the turn signal turn-off condition becomes the turn signal lever 41 is not adopted as a lane change request. The steering assist control routine of this modification example can therefore prevent the driver from improper operation by overestimation (excessive reliance on the lane change assist device).
In addition, it is difficult for the driver to finally recognize a termination timing of the LCA, but it is possible for the driver to finally recognize a turn-off timing of the turn signal. Thereby, the driver can properly recognize a point in time from which he can request a next lane change assistance control.
In the above, the lane assist devices for a vehicle according to the embodiment and modification example have been described, but the present invention is not limited to the above embodiment and the above modification example, but various changes are possible within the scope without departing from the subject matter of the invention.
For example, in the embodiment, the execution of the LCA is made on the assumption that the steering assist control state is the state LTA ON (state in which the LTA is executed), but this requirement is not mandatory.
In the embodiment, the operation for requesting the lane change assistant by means of the direction signal signal lever 41 executed, but the lane change assistance request operation can by means of an addition to the direction signal signal lever 41 provided operating unit for the lane change assistance request done (for example via an operating unit which is provided in a touch panel unit of the steering device).
In the embodiment, the turn signal becomes 32 switched off before completion of the LCA, but the turn signal switch-off condition can be adjusted as needed (for example, the turn signal 32 switched off at the same time as the completion of the LCA).
JP 2009274594 [0002, 0003]
JP 2005138647 [0053]
JP 2008195402 [0069]
JP 2009190464 [0069]
JP 20106279 [0069]
JP 4349210 [0069]
JP 2014148293 [0076]
JP 2006315491 [0076]
JP 4172434 [0076]
JP 4929777 [0076]
Lane change assist device for a vehicle, comprising: lane change assistance request recognition means (10, 40, S16-S19) for detecting a driver side request for lane change assistance in response to an operation performed on a lane change assistance requesting operation unit (41); an environmental monitoring means (10, 11) for monitoring an environment of the own vehicle; a lane change assistance control means (10, 20, S21) for accepting the lane change assistance request and starting the lane change assistance control for lane change when, in a situation where the lane change assistance request recognition means has recognized the lane change assistance request (S19: Yes), the environment monitoring means determines that Own vehicle can safely change the tracks traveled by the own vehicle (S20: Yes); and Non-operation detecting means (S14: Yes) for detecting a non-operation state in which the operation on the operation unit for requesting the lane change assistance is not performed; in which the lane change assistance control means is adapted to: Accepting the lane change assistance request when a prerequisite condition is satisfied, wherein the condition precedent is a condition that is satisfied when the lane change assistance request detection means detects, in a situation in which the non-operation detection means has detected the no-operation condition, the requesting operation unit the lane change support detected operating action recognizes (S14: Yes, S16: Yes); and when the lane change assistance control means accepts the lane change assistance request, executing the lane change assistance control for causing the lane change of the own vehicle from a current lane currently being traveled by the own vehicle to a lane immediately adjacent to the current lane (S21, S22).
Lane change assistance device for a vehicle Claim 1 wherein the lane change assistance request detecting means is adapted to recognize a lane change assistance request when the operation performed on the lane change assistant requesting unit continues beyond a preset assistance request confirming duration or more (S19: Yes).
Lane change assistance device for a vehicle Claim 1 or 2 wherein the lane change assistance control means is adapted to not accept the lane change assist request during a period from the start of the lane change assist control until the completion of the lane change assist control, even if the lane change assistance request recognition means recognizes the operation performed on the lane change assist operation control unit (S20: Yes, S21, S22: No).
Lane change assistance device for a vehicle Claim 1 or 2 , further comprising: a turn signal control means (10, 30, S51-S54) for driving an operation of a turn signal (32) to start the intermittent lighting of the turn signal when the lane change assist control is started, and turn off the turn signal when a turn signal Is satisfied, which is set to be satisfied before completion of the lane change assist control, wherein the lane change assistance control means is adapted to not accept the lane change assistance request during a period from the start of lane change assist control until the turn signal turn off condition is satisfied, even though the lane change assistance request recognition means detects the operation performed on the lane change assistance requesting operation unit (S21, S31: No, S22: No).
DE102017129570.4A 2016-12-26 2017-12-12 Lane change assistance device for a vehicle Pending DE102017129570A1 (en)
JP2016-251658 2016-12-26
JP2016251658A JP6579334B2 (en) 2016-12-26 2016-12-26 Vehicle lane change support device
DE102017129570A1 true DE102017129570A1 (en) 2018-06-28
ID=62509968
DE102017129570.4A Pending DE102017129570A1 (en) 2016-12-26 2017-12-12 Lane change assistance device for a vehicle
US (1) US20180178713A1 (en)
JP (1) JP6579334B2 (en)
DE (1) DE102017129570A1 (en)
2016-12-26 JP JP2016251658A patent/JP6579334B2/en active Active
2017-12-12 DE DE102017129570.4A patent/DE102017129570A1/en active Pending
2017-12-20 US US15/848,107 patent/US20180178713A1/en active Pending
US20180178713A1 (en) 2018-06-28
JP2018103768A (en) 2018-07-05
JP6579334B2 (en) 2019-09-25
JPWO2011158347A1 (en) 2013-08-15 Driving assistance device
CN101218135B (en) 2010-09-29 Method and system for assisting a driver of a motor vehicle in identifying suitable parking spaces for the vehicle
DE102005013886A1 (en) 2005-10-27 Cruise control / regulating system
CN1707548A (en) 2005-12-14 Driving control apparatus