JP6972644B2 - Vehicle control device - Google Patents

Description

The present invention relates to a vehicle control device.

Conventionally, as a vehicle control device, a device that executes vehicle travel control such as ACC in which the own vehicle is driven by following the preceding vehicle is known (see, for example, Patent Document 1).

Other documents related to the present invention include Patent Document 2 and Patent Document 3. These documents disclose techniques relating to feedback control used in vehicle control.

Japanese Unexamined Patent Publication No. 2008-296878 Special Table 2009-510316 Gazette Japanese Unexamined Patent Publication No. 10-153611

By the way, in recent years, as a vehicle control device for executing vehicle travel control, a device including a feedback control unit for executing feedback control for following an actual acceleration with respect to a change in a target acceleration of the vehicle travel control has been developed. The feedback control unit includes one integrator that executes the integration operation of the feedback control.

Here, the resistance to the running of the own vehicle (for example, air resistance, etc.) when the own vehicle is running changes depending on the vehicle state of the own vehicle and the running environment state. Therefore, in order to improve the followability of the actual acceleration to the change of the target acceleration of the vehicle driving control, the feedback control is executed by using an integrator suitable for the vehicle state or the driving environment state at the time of executing the vehicle driving control. Is desired. However, conventionally, such a vehicle control device has not been developed. Therefore, in the prior art, it cannot be said that the followability of the actual acceleration to the change of the target acceleration of the vehicle running control is sufficiently good, and it cannot be said that the vehicle running control can be executed accurately.

The present invention has been made in view of the above, and an object of the present invention is to provide a vehicle control device capable of accurately executing vehicle travel control.

In order to achieve the above object, the vehicle control device according to the present invention executes feedback control that follows the actual acceleration of the own vehicle with respect to the change in the target acceleration of the vehicle travel control at the time of executing the vehicle travel control. The feedback control unit is provided, and the feedback control unit is provided with a plurality of integrators that execute the integrating operation of the feedback control, and each of the integrators is adapted to each gear stage of the transmission of the own vehicle and the integrator is described. It is configured to perform the operation, the feedback control unit, the acquires the gear of the vehicle transmission, to enable the integrator adapted to the acquired gear, other of the integration The integrator is disabled and the integrator enabled to perform the feedback control.
In order to achieve the above object, the vehicle control device according to the present invention executes feedback control that follows the actual acceleration of the own vehicle with respect to the change in the target acceleration of the vehicle travel control at the time of executing the vehicle travel control. A feedback control unit is provided, and the feedback control unit includes a plurality of integrators that execute the integrating operation of the feedback control, and each of the integrators is adapted for each vehicle speed of the own vehicle or for each weight of the own vehicle. The integrator is configured to execute the integrator operation, and the feedback control unit acquires the vehicle speed of the own vehicle or the weight of the own vehicle, and obtains the integrator suitable for the acquired vehicle speed or weight. The integrator is enabled, the other integrators are disabled, and the integrator is enabled to perform the feedback control.
In order to achieve the above object, the vehicle control device according to the present invention executes feedback control that follows the actual acceleration of the own vehicle with respect to the change in the target acceleration of the vehicle travel control at the time of executing the vehicle travel control. A feedback control unit is provided, and the feedback control unit includes a plurality of integrators that execute the integrating operation of the feedback control, and each of the integrators is adapted for each road gradient of the road on which the own vehicle travels. The integrator is configured to perform the integrator operation, and the feedback control unit acquires the road gradient of the road on which the own vehicle travels, enables the integrator suitable for the acquired integrator, and enables the integrator. The integrator other than the above is disabled, and the feedback control is performed using the integrator enabled.

According to the present invention, the feedback control can be executed by properly using the integrator of the feedback control suitable for the vehicle state or the driving environment state of the own vehicle at the time of executing the vehicle running control. As a result, it is possible to improve the followability of the actual acceleration with respect to the change in the target acceleration of the vehicle running control. As a result, vehicle travel control can be executed with high accuracy.

It is a functional block diagram of the own vehicle. It is a block diagram for demonstrating the structure of the feedback control part of a vehicle control device. It is a flowchart for demonstrating the detail of feedback control using an integrator.

Hereinafter, the vehicle control device 10 according to the embodiment of the present invention will be described. Specifically, first, the schematic configuration of the own vehicle 1 having the vehicle control device 10 will be described, and then the vehicle control device 10 will be described. FIG. 1 is a functional block diagram showing each function of the own vehicle 1 as a block diagram. The own vehicle 1 includes a vehicle control device 10, a camera 20, a radar sensor 30, sensors 40, and a vehicle traveling system 50.

The camera 20 is a camera capable of photographing the front of the own vehicle 1 at a predetermined angle of view. The camera 20 is set to an angle of view that can capture a lane (white line) and can capture a preceding vehicle traveling in front of the own vehicle 1. The image detected by the camera 20 is transmitted to the vehicle control device 10. The vehicle control device 10 identifies a lane (white line) from the image detected by the camera 20 by using an image processing technique, and also identifies the presence or absence of a preceding vehicle.

The radar sensor 30 detects the distance between the preceding vehicle and the own vehicle 1 by sensing a predetermined area in front of the own vehicle 1. The detection result of the radar sensor 30 is transmitted to the vehicle control device 10. In this embodiment, a radar sensor using a millimeter wave radar is used as an example of the radar sensor 30.

The sensors 40 are sensors other than the radar sensor 30. Specifically, the sensors 40 include a speed sensor that detects the speed (vehicle speed) of the own vehicle 1, a gear stage detection sensor that detects the number of gear stages of the transmission 52, a weight sensor that detects the weight of the own vehicle 1, and the like. Includes. In the present embodiment, the weight of the own vehicle 1 means the weight obtained by adding the weights of the occupants and the cargo to the weight of the main body of the vehicle (that is, the weight of the entire own vehicle 1 including the occupants and the cargo).

The vehicle traveling system 50 is a system for traveling the own vehicle 1 in response to an instruction from the vehicle control device 10. Specifically, the vehicle traveling system 50 includes a vehicle drive system that drives the own vehicle 1 such as the engine 51 and the transmission 52, a brake system 53 that is a system that brakes the own vehicle 1, and the like. .. In this embodiment, a diesel engine is used as an example of the engine 51. Further, AMT (Automated Manual Transmission) is used as an example of the transmission 52. Further, as an example of this AMT, an AMT having a total of 16 gear stages is used.

The vehicle control device 10 is composed of a CPU 11 having a function as a control unit and a microcomputer having a storage device 12 for storing programs and various data used for the operation of the CPU 11. As the storage device 12, a ROM, RAM, or the like can be used.

Subsequently, the details of the control process of the vehicle control device 10 will be described. First, the vehicle control device 10 executes vehicle travel control. As a specific example of this vehicle travel control, the vehicle control device 10 according to the present embodiment executes vehicle travel control for driving the own vehicle 1 by following the preceding vehicle traveling in front of the travel lane of the own vehicle 1.

More specifically, as an example of the above-mentioned vehicle traveling control, the vehicle control device 10 executes ACC (Adaptive Cruise Control; Adaptive Cruise Control). Specifically, this ACC causes the own vehicle 1 to follow the preceding vehicle by automatically traveling the own vehicle 1 within a preset speed range while keeping the distance between the vehicle and the preceding vehicle within a certain range. It is a control to run. In executing this ACC, the vehicle control device 10 controls the vehicle traveling system 50 based on the detection results of the camera 20, the radar sensor 30, and the sensors 40.

When the vehicle control device 10 receives a vehicle travel control start request from the driver of the own vehicle 1, the vehicle control device 10 executes the vehicle travel control described above. Specifically, the driver's seat of the own vehicle 1 is provided with a switch for transmitting the start and stop of the vehicle travel control to the vehicle control device 10. Then, when the driver wishes to start the vehicle travel control, he / she turns on this switch to notify the vehicle control device 10 of the vehicle travel control start request. Upon receiving the start request signal, the vehicle control device 10 starts executing the vehicle travel control. Further, when the driver wishes to end the vehicle travel control, he / she turns off this switch to notify the vehicle control device 10 of the end request of the vehicle travel control. Upon receiving the end request signal, the vehicle control device 10 ends the execution of the vehicle travel control.

Further, the vehicle control device 10 is connected to a setting device (not shown) for the driver to set a speed range (for example, an upper limit speed of 100 km / h or the like) at the time of vehicle travel control. The vehicle control device 10 executes vehicle travel control within the speed range set in this setting device.

Further, the vehicle control device 10 executes feedback control for following the actual acceleration (actual acceleration) of the own vehicle 1 with respect to the change in the target acceleration (target acceleration) of the vehicle travel control when the vehicle travel control is executed. It has a feedback control unit 13. The details of the feedback control unit 13 will be described below with reference to FIG.

As shown in FIG. 2, the feedback control unit 13 according to the present embodiment executes PID control as an example. Specifically, the feedback control unit 13 includes a proportional device 14, an integrator group 15, and a differentiator 17. The feedback control unit 13 is specifically realized by the function of the CPU 11.

The target value (r (t)) of the feedback control shown in FIG. 2 is the target acceleration of the vehicle traveling control. The target acceleration of the vehicle travel control is a target value of acceleration for causing the preceding vehicle to follow the own vehicle 1, and is calculated by the CPU 11 of the vehicle control device 10. Therefore, this target acceleration changes with the passage of time.

The proportional device 14 executes a proportional operation of feedback control. Specifically, the proportional device 14 has a deviation (e (t)) between the target acceleration as the target value (r (t)) of the feedback control and the actual acceleration as the output value (y (t)) of the feedback control. A proportional operation that changes the control instruction value (u (t)) instructed to the control target 18 is executed in proportion to. The control target 18 of this feedback control is the vehicle traveling system 50 described above.

The integrator group 15 executes an integration operation of feedback control in order to eliminate a steady deviation between the target value (r (t)) and the output value (y (t)). Specifically, the integrator group 15 has a control instruction value (u (t)) to the controlled object 18 in proportion to the time integration of the target value (r (t)), the output value (y (t)), and the deviation. ) Is changed. More specifically, the integrator group 15 increases the change in the control instruction value (u (t)) as the state with deviation continues for a long time to eliminate the steady deviation. The details of the integrator group 15 will be described later.

The differentiator 17 executes a feedback control differentiating operation in order to suppress overshoot and hunting. Specifically, the differentiator 17 changes the control instruction value (u (t)) in proportion to the derivative of the deviation to suppress overshoot and hunting.

The control target 18 is PID controlled by the combination of the proportional device 14, the integrator group 15, and the differentiator 17 as described above, so that the target acceleration and the output value (y (t)), which are the target values (r (t)), are controlled. )) Hunting and overshoot can be suppressed while eliminating the steady deviation from the actual acceleration.

The specific content of the feedback control is not limited to the PID control as described above. As another example, the feedback control unit 13 may execute PI control as feedback control. In this case, the feedback control unit 13 is not provided with the differentiator 17. However, when the feedback control unit 13 executes the PID control as in the present embodiment, the transient response characteristic may be superior to the case where the PI control is executed.

Subsequently, the details of the integrator group 15 will be described. The integrator group 15 includes a plurality of integrators (integrators 16-1 to 16-n). Each integrator is configured to execute the feedback control integrator operation according to each vehicle state of the own vehicle 1 or each running environment state of the own vehicle 1 at the time of executing the vehicle travel control. As a specific example of this, each integrator according to the present embodiment is configured to execute an integrator operation according to each vehicle state of the own vehicle 1 at the time of executing the vehicle travel control.

As the vehicle state of the own vehicle 1, in the present embodiment, when the vehicle state of the own vehicle 1 changes, the "resistance to the running of the own vehicle 1" changes when the own vehicle 1 is running. Use the parameters related to the vehicle condition of.

Here, when the gear stage of the transmission 52 changes, the indicated value to the controlled object for achieving the target acceleration changes as the reduction ratio changes. When the gear stage changes, the speed of the own vehicle 1 usually changes accordingly, and as a result, the air resistance during traveling also changes. This air resistance is a kind of resistance to the running of the own vehicle 1. As described above, when the state of the gear stage of the transmission 52 changes, the resistance to the running of the own vehicle 1 also changes. Therefore, in the present embodiment, the state of the gear stage of the transmission 52 of the own vehicle 1 is used as an example of the vehicle state of the own vehicle 1.

As described above, the transmission 52 according to the present embodiment has, as an example, a total of 16 gear stages. Each integrator is configured to perform an integrator operation in conformity with each of the gear stages 1 to 16 of the transmission 52 (that is, with each gear stage). Specifically, the integrator 16-1 (I ₁ ) is fitted to the 1st gear, the integrator 16-2 (I ₂ ) is fitted to the 2nd gear, and the integrator 16-3 (I 1) is fitted to the 3rd gear. ₃ ) is suitable, and the integrator 16-16 (I 16) is suitable for the _{16-speed gear.} In addition, each integrator is set to its integral operation so that the steady-state deviation of the feedback control becomes zero when a gear stage suitable for this is used (that is, it is suitable for each gear stage). ing).

The feedback control unit 13 acquires the vehicle state of the own vehicle 1 at the time of executing the vehicle travel control, specifically, the state of the gear stage of the transmission 52 of the own vehicle 1. Next, the feedback control unit 13 enables the integrator suitable for the acquired gear stage and invalidates the other integrators. Then, the feedback control unit 13 executes feedback control using this enabled integrator. Note that enabling the integrator means making the integrator ready to perform the integral operation, and disabling the integrator means making the integrator unable to perform the integral action. do.

By the feedback control using the integrator as described above, it is possible to execute the feedback control by properly using the integrator suitable for the gear stage of the transmission 52 at the time of executing the vehicle running control.

The feedback control using this integrator will be described in detail using the flowchart of FIG. 3 as follows. The feedback control unit 13 repeatedly executes the flowchart of FIG. 3 when the vehicle travel control is executed.

First, the feedback control unit 13 acquires the vehicle state of the own vehicle 1 at the time of executing the vehicle travel control (step S10). Specifically, in step S10, the feedback control unit 13 acquires the current gear stage state of the transmission 52 by acquiring the detection result of the gear stage detection sensor (sensors 40).

Next, the feedback control unit 13 enables an integrator that matches the vehicle state (gear stage state) acquired in step S10, invalidates the other integrators, and feeds back using the enabled integrator. Control is executed (step S20).

To give a specific example of this step S20, for example, it is assumed that the gear stages acquired in step S10 are three stages. In this case, in step S20, the feedback control unit 13 enables only the integrators 16-3 that match the three stages, and invalidates all the other integrators. The integrator 16-3 is set to integrate operation so that the steady-state deviation of the feedback control becomes zero when the gear stage is three stages (that is, it is suitable for the three-stage gear). .. Then, the feedback control unit 13 executes an integration operation using the enabled integrator 16-3.

When the integrator 16-3 performs the integral operation in this step S20, the proportional device 14 and the differentiator 17 execute the proportional operation and the differentiating operation as usual, respectively. As a result, the controlled object 18 is feedback-controlled (PID controlled) by the proportional device 14, the integrator 16-3, and the differentiator 17.

After the execution of step S20, the feedback control unit 13 executes the flowchart from the start (return). In this way, the flowchart of FIG. 3 is repeatedly executed, and as a result, the feedback control according to step S20 is also repeatedly executed.

According to the present embodiment described above, the feedback control can be executed by properly using an integrator suitable for the vehicle state of the own vehicle 1 at the time of executing the vehicle travel control. As a result, the feedback control unit has only one integrator, and as a result, regardless of the vehicle state of the own vehicle, the feedback control is always performed using the same integrator. It is possible to improve the followability of the actual acceleration to the change of the target acceleration when the vehicle running control is executed. As a result, vehicle travel control can be executed with high accuracy.

(Modification 1 of the embodiment)
The specific example of the vehicle state of the own vehicle 1 is not limited to the state of the gear stage of the transmission 52 described above. To give another example of the vehicle state of the own vehicle 1, for example, the state of the vehicle speed (km / h) of the own vehicle 1, the state of the weight (kgf) of the own vehicle 1, and the like can be used.

Here, the faster the vehicle speed, the greater the air resistance during traveling tends to be. Further, as the weight of the own vehicle 1 is heavier, it is necessary to drive the own vehicle 1 with a larger driving force by the amount of the increase in the weight, so that the resistance to the running of the own vehicle 1 tends to be larger. Therefore, the vehicle speed and the weight are also one of the parameters of the vehicle state in which the resistance of the own vehicle 1 during traveling changes when the vehicle speed and the weight change, as in the above-mentioned gear stage.

When the state of the vehicle speed of the own vehicle 1 is used as the vehicle state, each integrator is configured to execute the integrator operation according to each vehicle speed (specifically, each vehicle speed range) of the own vehicle 1. There is. Specifically, the integrator 16-1 (I ₁ ) is suitable for the range where the vehicle speed is v ₁ or more and _{less than v 2,} and the integrator 16-2 (I ₂ ) is suitable for the range where the vehicle speed is v ₂ or more and _{less than v 3.} ) Is suitable, and the integrator 16-3 (I ₃ ) is suitable for the range where the vehicle speed is v ₃ or more and _{less than v 4} , and so on, and is suitable for each vehicle speed range (that is, for each vehicle speed range). each of the integrator is provided Te _{(Note, v 1 <v 2 <v} 3 ··· <v n).

Then, in step S10 of FIG. 3, the feedback control unit 13 acquires the vehicle speed of the own vehicle 1 based on the detection result of the speed sensor, and in step S20, only the integrator corresponding to the vehicle speed acquired in step S10 is used. Enable and perform feedback control with this integrator. For example, when the vehicle speed of the own vehicle 1 acquired in step S10 is included in the range of _{v 3} or more and _{less than v 4} , the feedback control unit 13 enables only the _{integrator 16-3 (I 3) in step S20.} Then, feedback control is executed by this integrator 16-3 (I _3).

Further, when the state of the weight of the own vehicle 1 is used as the vehicle state, each integrator is configured to execute the integration operation according to the weight of the own vehicle 1 (specifically, each weight range). Has been done. Specifically, the integrator 16-1 (I ₁ ) is suitable for the range where the weight is w ₁ or more and _{less than w 2,} and the integrator 16-2 (I ₂ ) is suitable for the range where the weight is w ₂ or more and _{less than w 3.} ) Fits, integrators 16-3 (I ₃ ) fit in the range where the weight is w ₃ or more and _{less than w 4} , and so on, each integrator fits in each weight range. It is provided (note that w ₁ <w ₂ <w ₃ ... <w _n ).

Then, the feedback control unit 13 acquires the weight of the own vehicle 1 based on the detection result of the weight sensor in step S10 of FIG. 3, and in step S20, only the integrator corresponding to the weight acquired in step S10 is used. Enable and perform feedback control with this integrator. For example, when the weight of the own vehicle 1 acquired in step S10 is included in the range of _{w 3} or more and _{less than w 4} , the feedback control unit 13 enables only the _{integrator 16-3 (I 3) in step S20.} Then, feedback control is executed by this integrator 16-3 (I _3).

Also in this modification, the feedback control can be executed by properly using an integrator suitable for the vehicle state of the own vehicle 1 at the time of executing the vehicle travel control. As a result, when the vehicle travel control is executed, the followability of the actual acceleration to the change in the target acceleration can be improved, and as a result, the vehicle travel control can be executed with high accuracy.

(Modification 2 of the embodiment)
In the above-described embodiment, the feedback control unit 13 may use the traveling environment state of the own vehicle 1 instead of the vehicle state of the own vehicle 1. As a specific example of this driving environment condition,
In this modification, parameters related to the running environment of the own vehicle 1 are used so that the resistance to the running of the own vehicle 1 also changes when the running environment state of the own vehicle 1 changes. More specifically, as an example of this traveling environment state, the state of the road slope of the road on which the own vehicle 1 travels is used. It should be noted that the higher the road gradient is and the larger the gradient value is, the greater the resistance to the traveling of the own vehicle 1 tends to be. In this way, when the road gradient changes, the resistance of the own vehicle 1 to the running also changes.

Specific examples of using the integrator properly based on the state of the road slope are as follows. First, each integrator is configured to perform an integral operation according to each road gradient (specifically, each range of road gradient). For example, the integrator 16-1 (I ₁ ) is suitable for the range where the road gradient is s ₁ or more and _{less than s 2,} and the integrator 16-2 (I ₂ ) is suitable for the range where the road gradient is s ₂ or more and _{less than s 3.} Is suitable, and the integrator 16-3 (I ₃ ) is suitable for the range where the road gradient is s ₃ or more and _{less than s 4} , and so on, each integrator is suitable for each road slope range. (Note that s ₁ <s ₂ <s ₃ <... s _n ) is provided.

The integrator operation of each integrator is set so that the steady deviation of the feedback control becomes zero in the case of a road gradient suitable for the integrator. To give a specific example, for example, the integrator 16-3 (I ₃ ) is constantly feedback-controlled by the integrator operation of the integrator 16-3 when the road gradient is _{included in the range of s 3} or more and _{less than s 4.} It is set so that the deviation is zero.

Further, the vehicle control device 10 stores "map information with a road gradient (map information to which not only the position information of the road but also the information of the road gradient is added)" in the storage device 12 in advance. Further, the sensors 40 include a GPS sensor that detects the position information of the own vehicle 1. In step S10 of FIG. 3, the feedback control unit 13 acquires the current position information of the own vehicle 1 at the time of executing the vehicle travel control based on the detection result of the GPS sensor, and the position acquired in this way. By collating the information with the map information of the storage device 12, the state of the road gradient of the road on which the own vehicle 1 is currently traveling (that is, the state of the current road gradient at the time of executing the vehicle traveling control) is acquired. Next, in step S20, the feedback control unit 13 enables only the integrator corresponding to the road gradient acquired in step S10, and executes feedback control with this integrator.

For example, when the road gradient acquired in step S10 _{is included in the range of s 3} or more and _{less than s 4} , the feedback control unit 13 in step S20, the integrator 16-3 (I _{3) matching this road gradient.} ) Is enabled, other integrators are disabled, and feedback control is performed using this enabled integrator.

According to this modification, the feedback control can be executed by properly using an integrator suitable for the traveling environment state of the own vehicle 1 (as an example, the state of the road gradient) at the time of executing the vehicle traveling control. As a result, when the vehicle travel control is executed, the followability of the actual acceleration to the change in the target acceleration can be improved, and as a result, the vehicle travel control can be executed with high accuracy.

(Modification 3 of the embodiment)
Further, in the above-described embodiments and modifications 1 and 2 of the embodiments, the feedback control unit 13 re-enables the integrator once disabled when the feedback control is repeatedly executed during the execution of the vehicle travel control. In some cases, as the control input value that is first input to this enabled integrator, the control input value that was last input when this enabled integrator was last enabled is inherited and used. You may. To explain this with a concrete example, it is as follows.

For example, in step S20 of FIG. 3, the integrator 16-4 corresponding to the four gear stages of the transmission 52 is enabled, all other integrators are disabled, and the integrator operation is performed by the integrator 16-4. Suppose it was executed. After that, the flowchart of FIG. 3 is executed, and in step S20, the integrator 16-3 corresponding to the three gear stages is enabled, and the integrator operation is executed by the integrator 16-3. (Ie, in this case, integrators 16-4 are disabled). After that, it is assumed that the flowchart of FIG. 3 is executed, and in step S20, the integrator 16-4 corresponding to the four gear stages is enabled again, and the integrator operation is executed by the integrator 16-4.

In this case, the feedback control unit 13 uses the integrator 16- as the control input value input to the integrator 16-4 enabled this time during the feedback control when the integrator 16-4 was previously enabled. The feedback control this time is executed using the control input value input last in 4.

According to this modification, the feedback control can be repeatedly executed while inheriting the control input value input to the integrator. As a result, it is possible to further improve the followability of the actual acceleration to the change in the target acceleration of the vehicle running control. As a result, vehicle traveling control can be executed more accurately.

Although the preferred embodiment of the present invention has been described above, the present invention is not limited to such a specific embodiment, and various modifications and modifications are made within the scope of the gist of the present invention described in the claims. Is possible.

1 Own vehicle 10 Vehicle control device 13 Feedback control unit 14 Proportional device 15 Integrator group 16-1 to 16-n Integrator 17 Differentiator 50 Vehicle running system

Claims (3)

It is provided with a feedback control unit that executes feedback control that follows the actual acceleration of the own vehicle with respect to the change in the target acceleration of the vehicle travel control when the vehicle travel control is executed.
The feedback control unit includes a plurality of integrators that execute the integration operation of the feedback control.
Each of the integrators is configured to perform the integrator operation in conformity with each gear stage of the transmission of the own vehicle.
The feedback control unit acquires the gear stage of the transmission of the own vehicle, enables the integrator suitable for the acquired gear stage , invalidates the other integrators, and enables the integrator. A vehicle control device that executes the feedback control using an integrator. It is provided with a feedback control unit that executes feedback control that follows the actual acceleration of the own vehicle with respect to the change in the target acceleration of the vehicle travel control when the vehicle travel control is executed.
The feedback control unit includes a plurality of integrators that execute the integration operation of the feedback control.
Each of the integrators is configured to perform the integrator operation according to the vehicle speed of the own vehicle or the weight of the own vehicle.
The feedback control unit acquires the vehicle speed of the own vehicle or the weight of the own vehicle, enables the integrator suitable for the acquired vehicle speed or weight , disables the other integrators, and enables the integrator. A vehicle control device that executes the feedback control using the integrator. It is provided with a feedback control unit that executes feedback control that follows the actual acceleration of the own vehicle with respect to the change in the target acceleration of the vehicle travel control when the vehicle travel control is executed.
The feedback control unit includes a plurality of integrators that execute the integration operation of the feedback control.
Each of the integrators is configured to perform the integrator operation according to the road gradient of the road on which the own vehicle travels.
The feedback control unit acquires the road gradient of the road on which the own vehicle travels , enables the integrator that matches the acquired road gradient , and disables and enables the other integrators. A vehicle control device that executes the feedback control using the integrator.

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