JP2013010426A - Acceleration/deceleration controller, and acceleration/deceleration control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve operability in case of integrating a function of a braking operator with an accelerating operator.SOLUTION: The acceleration/deceleration controller controls acceleration and deceleration of a vehicle corresponding to an operation position S of an accelerator pedal 8, wherein the control characteristics of acceleration/deceleration corresponding to an operation position S are changed between a case of increasing operation and a case of decreasing operation. In case of increasing operation, the control characteristics conform to approach-route control characteristics that a target acceleration/deceleration G increases from zero to a predetermined positive-side maximum acceleration/deceleration Gwhen an operation position S of the accelerator pedal 8 increases from an non-operation position Sto a maximum operation position S. In case of decreasing operation, the control characteristics conform to return-route control characteristics that a target acceleration/deceleration G decreases from an upon-detecting-decreasing-operation acceleration/deceleration Gd to a predetermined negative-side minimum acceleration/deceleration Gwhen an operation position S of the accelerator pedal 8 decreases from an upon-detecting-decreasing-operation operation position Sd to the non-operation position S.

Description

  The present invention relates to an acceleration / deceleration control device and an acceleration / deceleration control method.

There is a technical idea in which the function of a brake pedal is integrated into an accelerator pedal, and the vehicle is accelerated or decelerated only by operating the accelerator pedal.
In the prior art of Patent Document 1, the vehicle is decelerated as the accelerator pedal is depressed in a region where the accelerator opening is equal to or less than a predetermined opening, and the vehicle is increased as the accelerator pedal is depressed in a region where the accelerator opening is equal to or greater than the predetermined opening. Is accelerating.

JP 2006-137324 A

In the above prior art, acceleration control is not performed until the accelerator opening is equal to or greater than the predetermined opening. Therefore, in order to accelerate the vehicle from the state where the accelerator opening is 0, the accelerator control is performed by depressing the accelerator pedal to some extent. You have to find where to start. Therefore, there is a possibility that the driver's burden of driving is to find the accelerator depression position at which acceleration is started.
The subject of this invention is improving the operativity in the case of integrating the function of a brake operation element in an accelerator operation element.

In order to solve the above problems, the acceleration / deceleration of the vehicle is controlled according to the operation position of the accelerator operation element, and the acceleration / deceleration control characteristics according to the operation position in the case of the increase operation and the decrease operation are set. Change.
Here, the increase operation is an operation for increasing the operation position of the accelerator operator from the non-operation position toward the maximum operation position. The decrease operation is an operation for decreasing the operation position of the accelerator operator toward the non-operation position within the range excluding the non-operation position after the increase operation.

  According to the acceleration / deceleration control device according to the present invention, by changing the control characteristics of acceleration / deceleration according to the operation position between the increase operation and the decrease operation, the decrease operation can be performed even at the same operation position. In this case, the vehicle can be decelerated, and in the case of an increase operation, the vehicle can be accelerated. Therefore, since the vehicle can be accelerated from the initial stage of the increasing operation, it is not necessary to search for a position where acceleration control is started unlike the prior art, and the operability is improved.

It is a schematic block diagram of an acceleration / deceleration control apparatus. It is a schematic block diagram of a brake actuator. It is a flowchart which shows an acceleration / deceleration control process. It is a map of an outward path control characteristic. It is a map used for the setting of the gradient coefficient ka. It is a map of a return path control characteristic. It is a map of the return path control characteristic from which the inclination of characteristic line L2 and L3 differs. It is a map used for the setting of the gradient coefficient kr. It is a map of a return path control characteristic when operation position Sd at the time of reduction operation detection is small. It is a conceptual diagram of a comparative example. It is an example which shows operation | movement of this embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
<< First Embodiment >>
"Constitution"
FIG. 1 is a schematic configuration diagram of an acceleration / deceleration control apparatus.
The acceleration / deceleration control device includes a wheel rotation sensor 1, an accelerator sensor 2, an acceleration sensor 3, a shift sensor 4, a controller 5, a driving force control device 6, and a brake actuator 7.
The wheel rotation sensor 1 detects the wheel speed of each wheel. The wheel rotation sensor 1 detects, for example, the magnetic lines of force of the sensor rotor by a detection circuit, converts a change in the magnetic field accompanying the rotation of the sensor rotor into a current signal, and inputs the current signal to the controller 5. The controller 5 determines the wheel speed from the input current signal.

The accelerator sensor 2 detects the operation position (depression amount) of the accelerator pedal 8. The accelerator sensor 2 is a potentiometer, for example, and converts the operation position of the accelerator pedal 8 into a voltage signal and inputs it to the controller 5. The controller 5 determines the operation position of the accelerator pedal 8 from the input voltage signal. The accelerator pedal 8 is movable within a range from a non-operation position S ₀ at the time of non-operation to a maximum operation position S _{MAX at} the stroke end.

The acceleration sensor 3 detects the acceleration / deceleration of the vehicle. The acceleration sensor 3 detects, for example, the displacement of the movable electrode relative to the fixed electrode as a change in capacitance, and converts it into a voltage signal proportional to the acceleration / deceleration and inputs it to the controller 5. The controller 5 determines the acceleration / deceleration from the input voltage signal.
The shift sensor 4 detects the shift position of the transmission. The shift sensor 4 includes, for example, a plurality of Hall elements, and inputs each ON / OFF signal to the controller 5. The controller 5 determines the shift position from the combination of the ON / OFF signal.

The controller 5 is composed of, for example, a microcomputer, and executes an acceleration / deceleration control process, which will be described later, based on detection signals from each sensor, and drives and controls the driving force control device 6 and the brake actuator 7.
The driving force control device 6 controls the driving force of the rotational driving source. For example, if the rotational drive source is an engine, the engine output (the number of revolutions and the engine torque) is controlled by adjusting the opening of the throttle valve, the fuel injection amount, the ignition timing, and the like. If the rotational drive source is a motor, the motor output (number of rotations and motor torque) is controlled via an inverter.

FIG. 2 is a schematic configuration diagram of the brake actuator.
The brake actuator 7 is interposed between the master cylinder 10 and the wheel cylinders 11FL to 11RR.
The master cylinder 10 is a tandem type that produces two systems of hydraulic pressure according to the driver's pedaling force. The master cylinder 10 transmits the primary side to the front left and rear right wheel cylinders 11FL and 11RR, and the secondary side transmits the right front wheel and A diagonal split system is used for transmission to the left rear wheel cylinders 11FR and 11RL.

Each wheel cylinder 11FL to 11RR is built in a disc brake that generates a braking force by pressing a disc rotor with a brake pad, or a drum brake that generates a braking force by pressing a brake shoe against the inner peripheral surface of the brake drum. is there.
The brake actuator 7 uses a brake fluid pressure control circuit used for anti-skid control (ABS), traction control (TCS), stability control (VDC: Vehicle Dynamics Control), etc. Regardless, the hydraulic pressure in each of the wheel cylinders 11FL to 11RR can be increased, held and reduced.
The primary side includes a first gate valve 12A, an inlet valve 13FL (13RR), an accumulator 14, an outlet valve 15FL (15RR), a second gate valve 16A, a pump 17, and a damper chamber 18.

  The first gate valve 12A is a normally open valve that can close the flow path between the master cylinder 10 and the wheel cylinder 11FL (11RR). The inlet valve 13FL (13RR) is a normally open valve that can close the flow path between the first gate valve 12A and the wheel cylinder 11FL (11RR). The accumulator 14 communicates between the wheel cylinder 11FL (11RR) and the inlet valve 13FL (13RR). The outlet valve 15FL (15RR) is a normally closed valve that can open the flow path between the wheel cylinder 11FL (11RR) and the accumulator 14. The second gate valve 16A is a normally-closed type valve that can open a flow path that communicates between the master cylinder 10 and the first gate valve 12A and between the accumulator 14 and the outlet valve 15FL (15RR). The pump 17 communicates the suction side between the accumulator 14 and the outlet valve 15FL (15RR), and communicates the discharge side between the first gate valve 12A and the inlet valve 13FL (13RR). The damper chamber 18 is provided on the discharge side of the pump 17 and suppresses pulsation of the discharged brake fluid and weakens pedal vibration.

Similarly to the primary side, the secondary side also has a first gate valve 12B, an inlet valve 13FR (13RL), an accumulator 14, an outlet valve 15FR (15RL), a second gate valve 16B, a pump 17, A damper chamber 18.
The first gate valves 12A and 12B, the inlet valves 13FL to 13RR, the outlet valves 15FL to 15RR, and the second gate valves 16A and 16B are two-port, two-position switching, single solenoid, and spring offset type electromagnetic operations, respectively. It is a valve. The first gate valves 12A and 12B and the inlet valves 13FL to 13RR open the flow path at the non-excited normal position, and the outlet valves 15FL to 15RR and the second gate valves 16A and 16B are at the non-excited normal position. The flow path is closed.

The accumulator 14 is a spring-type accumulator in which a compression spring is opposed to a cylinder piston.
The pump 17 is a positive displacement pump such as a gear pump or a piston pump that can ensure a substantially constant discharge amount regardless of the load pressure.
With the above configuration, the primary side will be described as an example. When the first gate valve 12A, the inlet valve 13FL (13RR), the outlet valve 15FL (15RR), and the second gate valve 16A are all in the non-excited normal position. The hydraulic pressure from the master cylinder 10 is transmitted as it is to the wheel cylinder 11FL (11RR), and becomes a normal brake.

  Even when the brake pedal is not operated, the first gate valve 12A is energized and closed while the inlet valve 13FL (13RR) and the outlet valve 15FL (15RR) are kept in the non-excited normal position. The second gate valve 16A is excited and opened, and the pump 17 is further driven to suck the hydraulic pressure of the master cylinder 10 through the second gate valve 16A, and the discharged hydraulic pressure is set to the inlet valve 13FL (13RR). ) To the wheel cylinder 11FL (11RR) to increase the pressure.

  If the inlet valve 13FL (13RR) is excited and closed when the first gate valve 12A, the outlet valve 15FL (15RR), and the second gate valve 16A are in the non-excited normal position, the wheel cylinder 11FL (11RR) is closed. ) To the master cylinder 10 and the accumulator 14 are blocked, and the hydraulic pressure of the wheel cylinder 11FL (11RR) is maintained.

  Further, when the first gate valve 12A and the second gate valve 16A are in the non-excited normal position, the inlet valve 13FL (13RR) is excited and closed, and the outlet valve 15FL (15RR) is excited and opened. The hydraulic pressure in the wheel cylinder 11FL (11RR) flows into the accumulator 14 and is reduced. The hydraulic pressure flowing into the accumulator 14 is sucked by the pump 17 and returned to the master cylinder 10.

Also on the secondary side, the normal braking, pressure increasing, holding, and pressure reducing operations are the same as the operations on the primary side, and detailed description thereof will be omitted.
Therefore, the controller 5 controls each wheel by drivingly controlling the first gate valves 12A and 12B, the inlet valves 13FL to 13RR, the outlet valves 15FL to 15RR, the second gate valves 16A and 16B, and the pump 17. The fluid pressure in the cylinders 11FL to 11RR is increased / held / reduced.

In the present embodiment, a diagonal split method is used in which the brake system is divided into front left / rear right and front right / rear left, but the present invention is not limited thereto. The front / rear split method may be adopted.
Further, in the present embodiment, the spring-shaped accumulator 14 is adopted, but the present invention is not limited to this, and brake fluid extracted from each wheel cylinder 11FL to 11RR is temporarily stored to efficiently reduce pressure. Therefore, any type such as a weight type, a gas compression direct pressure type, a piston type, a metal bellows type, a diaphragm type, a bladder type, and an in-line type may be used.

  In the present embodiment, the first gate valves 12A and 12B and the inlet valves 13FL to 13RR open the flow path at the non-excited normal position, and the outlet valves 15FL to 15RR and the second gate valves 16A and 16B are non-excited. Although the flow path is closed at the normal excitation position, the present invention is not limited to this. In short, since it is only necessary to open and close each valve, the first gate valves 12A and 12B and the inlet valves 13FL to 13RR open the flow path at the excited offset position, and the outlet valves 15FL to 15RR and the second gate are opened. The valves 16A and 16B may close the flow path at the excited offset position.

Next, acceleration / deceleration control processing executed by the controller 5 every predetermined time (for example, 10 msec) will be described.
FIG. 3 is a flowchart showing the acceleration / deceleration control process.
First, in step S101, it is determined whether or not the switching flag fs has been reset to zero. This switching flag fs indicates the switching state of the control characteristics, and is reset to fs = 0 in the initial setting. When the determination result is fs = 0, the process proceeds to step S102 in order to execute the acceleration / deceleration control according to the forward path control characteristic. On the other hand, when the determination result is fs = 1, the process proceeds to step S117 in order to execute the acceleration / deceleration control according to the return path control characteristic.

Here, the forward control characteristic, which is the control characteristics when increased increased toward the maximum operating position S _MAX operation position S of the accelerator pedal 8 from the non-operation position S ₀ operation (widening depression). The return path control characteristic is a non-operation during a decreasing operation (stepping back) in which the operating position S of the accelerator pedal 8 is decreased toward the non-operating position S ₀ after the increasing operation and after the decreasing operation. This is a control characteristic at the time of re-increasing operation (re-depression) in which the operation position S of the accelerator pedal 8 is increased toward the maximum operation position S _MAX in a range exceeding the position S ₀ .

In step S102, it is determined whether the operation position S of the accelerator pedal 8 is in the non-operating position S _0. When the determination result is S = S ₀ , it is determined that the accelerator pedal 8 is not depressed, that is, the state before depression, and the process proceeds to step S103. On the other hand, the determination result at S> S _0, it is determined that depressing the accelerator pedal 8 proceeds to step S104.
In step S103, a map according to the forward path control characteristic for calculating the target acceleration / deceleration G is set.

FIG. 4 is a map of forward path control characteristics.
The horizontal axis is the operation position S, and the vertical axis is the target acceleration / deceleration G. For the sake of convenience, the target acceleration / deceleration G has a positive value as acceleration and a negative value as deceleration.
In the forward path control characteristic, the target acceleration / deceleration G is maintained at 0 if the operation position S is within the predetermined initial position S ₁ from the non-operation position S ₀ . Here, the section up to the initial position S ₁ corresponds to a so-called loss stroke or play of the accelerator pedal 8 and is a parameter adjusted by an operation feeling. Further, when the operating position S is increased in the range of up to operating position S _MAX from the initial position S _1, the target deceleration G increases in the range from 0 to the maximum acceleration G _MAX of the positive side. Here, a coordinate at which the operation position S is the initial position S ₁ and the target acceleration / deceleration G is 0 is defined as a point A, and a coordinate at which the operation position S is the maximum operation position S _MAX and the target acceleration / deceleration G is the maximum acceleration / deceleration G _MAX. Let it be point B. A straight line connecting the points A and B is defined as a characteristic line L1. The characteristic line L1 may not be linear but may be nonlinear.

The maximum acceleration / deceleration G _MAX is set according to the road surface gradient θ with respect to the traveling direction of the vehicle. Specifically, as shown below, the maximum acceleration / deceleration G _MAX is set by multiplying a predetermined positive reference value Gs _MAX by a gradient coefficient ka.
G _MAX = Gs _MAX × ka
Here, the setting of the gradient coefficient ka will be described.
The traveling direction of the vehicle is detected by the shift sensor 4. If the shift position is in the D range, for example, the forward direction is the traveling direction, and if the shift position is in the R range, the backward direction is the traveling direction. Further, the road surface gradient θ is determined based on the acceleration / deceleration detected by the acceleration sensor 3.

Then, with reference to the map of FIG. 5, the gradient coefficient ka is set according to the road surface gradient θ with respect to the traveling direction.
FIG. 5 is a map used for setting the gradient coefficient ka.
In this map, the gradient coefficient ka is 1 when the road surface gradient θ is 0, the gradient coefficient ka is greater than 1 as the road surface gradient θ is an upward gradient, and the gradient coefficient ka is as the road surface gradient θ is a downward gradient. It is set to be smaller than 1. Therefore, the maximum acceleration / deceleration G _MAX increases (the acceleration increases) as the road surface gradient θ in the traveling direction increases in the upward direction, and the maximum acceleration / deceleration G _MAX decreases as the road surface gradient in the traveling direction increases in the downward direction. (Acceleration decreases).

In this way, a map of the forward path control characteristic is set.
In the subsequent step S104, it is determined whether or not the current operation position S _(n) is _{equal to} or greater than the operation position S _(n-1) one sampling earlier. When the determination result is S _(n) ≥ S _(n-1) , it is determined that the driver has increased or held the operation position S of the accelerator pedal 8, and the process proceeds to step S105. On the other hand, when the determination result is S _(n) <S _(n-1) , it is determined that the driver is decreasing the operation position S of the accelerator pedal 8, and the process proceeds to step S108.

  In step S105, it is determined whether or not the detection flag fd is reset to zero. This detection flag fd represents the detection state of the decrease operation, and is reset to fd = 0 in the initial setting. When the determination result is fd = 0, it is determined that the decrease operation is not detected, and the process proceeds to step S106. On the other hand, when the determination result is fd = 1, it is determined that the decrease operation is detected, and the process proceeds to step S121.

In step S106, the target acceleration / deceleration G is calculated according to the operation position S of the accelerator pedal 8 with reference to the map according to the forward path control characteristic of FIG.
In the subsequent step S107, based on the target acceleration / deceleration G, the driving force control device 6 and the brake actuator 7 are driven and controlled, and then the process returns to a predetermined main program.
Specifically, when the target acceleration / deceleration G is a positive value, the driving force is increased via the driving force control device 6 in order to accelerate the vehicle. On the other hand, when the target acceleration / deceleration G is a negative value, the driving force is limited via the driving force control device 6 and the braking force is increased via the brake actuator 7 in order to decelerate the vehicle.

In step S108, it is determined whether or not the detection flag fd is reset to zero. When the determination result is fd = 0, it is determined that it is immediately after the decrease operation is detected, and the process proceeds to step S109. On the other hand, if the determination result is fd = 1, it is determined that it is not immediately after the decrease operation is detected, and the process proceeds to step S111.
In step S109, the current operation position S _(n) and the target acceleration / deceleration G _(n) are stored as the operation position Sd at the time of detecting the decrease operation and the target acceleration / deceleration Gd at the time of detecting the decrease operation, respectively.

In subsequent step S110, the detection flag is set to 1.
In the following step S111, it is determined whether or not the operation position S is smaller than a value (= Sd−α) obtained by subtracting the set value α from the operation position Sd at the time of detecting the decrease operation. α is a value for avoiding hunting. When the determination result is S ≧ Sd−α, it is determined that there is a possibility that it is not an intentional reduction operation although the reduction operation is detected, and the process proceeds to step S112. On the other hand, when the determination result is S <Sd−α, it is determined that the operation is an intentional reduction operation, and the process proceeds to step S113.
In step S112, the target acceleration / deceleration G _(n-1) before one sampling is set as the current target acceleration / deceleration G _(n), and then the process proceeds to step S107.
In step S113, the detection flag fd is reset to zero.
In the subsequent step S114, a map according to the return path control characteristic for calculating the target acceleration / deceleration G is set.

FIG. 6 is a map of return path control characteristics.
The horizontal axis is the operation position S, and the vertical axis is the target acceleration / deceleration G. For the sake of convenience, the target acceleration / deceleration G has a positive value as acceleration and a negative value as deceleration.
First, the range of S ≦ Sd−α will be described.
In the return path control characteristic, when the operation position S decreases in the range from (Sd−α) to the initial position S ₁ , the target acceleration / deceleration G decreases from the positive value to the negative minimum acceleration / deceleration G _MIN. . If the operation position S is in the range from the initial position S ₁ to the non-operation position S ₀ , the target acceleration / deceleration G maintains the minimum acceleration / deceleration G _MIN . At the boundary where the target acceleration / deceleration G changes from a positive value to a negative value, a dead zone β in which the target acceleration / deceleration G maintains 0 with respect to a change in the operation position S is provided. This dead zone β is determined by the resolution (how much control width can be taken).

Here, a coordinate at which the operation position S is (Sd−α) and the target acceleration / deceleration G is Gd is a point C, and a coordinate at which the operation position S is the initial position S ₁ and the target acceleration / deceleration G is the minimum acceleration / deceleration G _MIN. Let it be point D. Further, a coordinate at which the target acceleration / deceleration G becomes 0 from the positive value according to the decrease in the operation position S is set as a point E, and a coordinate at which the target acceleration / deceleration G becomes 0 to a negative value according to the decrease in the operation position S And A straight line connecting points C and E is defined as a characteristic line L2, and a straight line connecting points F and D is defined as a characteristic line L3.

The characteristic line L2 shows the coordinates of the target acceleration / deceleration Gd when the operation position S is (Sd-α) and the target acceleration / deceleration G is decreasing, and the target acceleration / deceleration G is the minimum acceleration / deceleration when the operation position S is (S ₁ + β). It is set along a straight line connecting the coordinates of _GMIN . Moreover, the characteristic line L3 are the coordinates of the operation position S is (Sd-α-β) at a target acceleration G is reduced operation detection when target acceleration Gd, the target acceleration G is in operating position S is the initial position S ₁ It is set along a straight line connecting the coordinate of the minimum acceleration / deceleration _GMIN .

The characteristic lines L2 and L3 do not have to have the same inclination.
FIG. 7 is a map of return path control characteristics with different slopes of the characteristic lines L2 and L3.
Here, as an example, the slope of the characteristic line L3 is made larger than the slope of the characteristic line L2. That is, when the change amount of the operation position S is the same, the change amount of the target acceleration / deceleration G is larger in the region according to the characteristic line L3 than in the region according to the characteristic line L2. In other words, a slow operation feeling that emphasizes controllability is realized on the acceleration side, and a quick operation feeling that emphasizes lightness is realized on the deceleration side.

Furthermore, the characteristic lines L2 and L3 may not be linear but may be nonlinear.
The minimum acceleration / deceleration G _MIN is set according to the road surface gradient θ with respect to the traveling direction of the vehicle. Specifically, as shown below, the first reference value Gs1 _MIN negative side predetermined, by multiplying the slope coefficient kr, setting the minimum deceleration G _MIN.
G _MIN = Gs1 _MIN × kr
Here, the setting of the gradient coefficient kr will be described.
The traveling direction of the vehicle is detected by the shift sensor 4. If the shift position is in the D range, for example, the forward direction is the traveling direction, and if the shift position is in the R range, the backward direction is the traveling direction. Further, the road surface gradient θ is determined based on the acceleration / deceleration detected by the acceleration sensor 3.

Then, referring to the map of FIG. 8, the gradient coefficient kr is set according to the road surface gradient θ with respect to the traveling direction.
FIG. 8 is a map used for setting the gradient coefficient kr.
In this map, when the road surface gradient θ is 0, the gradient coefficient kr is 1, the gradient coefficient kr is smaller than 1 as the road surface gradient θ is an upward gradient, and the gradient coefficient kr is as the road surface gradient θ is a downward gradient. It is set to be larger than 1. Therefore, as the road surface gradient θ with respect to the traveling direction increases in the upward direction, the minimum acceleration / deceleration G _MIN increases (the deceleration decreases), and as the road surface gradient with respect to the traveling direction increases in the downward direction, the minimum acceleration / deceleration G _MIN decreases. (Deceleration increases).

Further, the minimum acceleration / deceleration G _MIN is set according to the operation position Sd at the time of detecting the decrease operation.
FIG. 9 is a map of the return path control characteristic when the operation position Sd when the decrease operation is detected is small.
That is, when the operation position Sd at the time of the decrease operation detection is less than a predetermined threshold th, the minimum acceleration / deceleration G _MIN is greater than the first reference value Gs1 _MIN (the absolute value is small), the negative second reference value Gs2. Set to _MIN .

Next, the range of S> Sd−α will be described.
If the operation position S is within the range from (Sd−α) to the decrease operation detection operation position Sd, the target acceleration / deceleration G maintains the decrease operation detection target acceleration / deceleration Gd. Further, if the range of the maximum operating position S _MAX operation position S from the reduction operation detection when the operation position Sd, according to the characteristic line L1 of the forward control characteristics described above. If the operation position Sd at the time of the decrease operation detection is the maximum operation position S _MAX , the area according to the characteristic line L1 is inevitably lost.
In this way, the map of the return path control characteristic is set.
In the following step S115, the switching flag fs is set to 1.
In the subsequent step S116, the map according to the return path control characteristic of FIG. 6 is referred to, the target acceleration / deceleration G is calculated according to the operation position S of the accelerator pedal 8, and then the process proceeds to step S107.

At step S117, the determining whether the operating position S is greater than the non-operation position S _0. If the determination result is S> a S _0, it is determined that the operation of the accelerator pedal 8 is not released proceeds to step S116. On the other hand, if the determination result is S = S ₀ , it is determined that the operation of the accelerator pedal 8 has been released, and the process proceeds to step S118.
In subsequent step S118, the target acceleration / deceleration G is returned to 0 at a predetermined change rate by adding ΔG that is predetermined for each calculation cycle to the target acceleration / deceleration G.

In a succeeding step S119, it is determined whether or not the target acceleration / deceleration G has returned to zero. When the determination result is G = 0, the process proceeds to step S120. On the other hand, when the determination result is G ≠ 0, the process proceeds to step S107 as it is.
In step S120, the switching flag fs is reset to 0, and then the process proceeds to step S107.

In step S121, it is determined whether or not the operation position S is equal to or greater than the operation position Sd when the decrease operation is detected. If the determination result is S ≧ Sd, it is determined that the decrease operation is stopped and the increase operation is restored, and the process proceeds to step S122. On the other hand, if the determination result is S <Sd, it is determined that neither the decrease operation is continued nor returned to the increase operation, and the process proceeds to step S112.
In step S122, the detection flag fd is reset to 0, and then the process proceeds to step S106.

<Action>
First, a comparative example will be described.
Conventionally, there is a technical idea of integrating the function of a brake pedal into the accelerator pedal 8 and accelerating or decelerating the vehicle only by operating the accelerator pedal 8, for example, only the operation position (absolute position) of the accelerator pedal 8, Some switch the acceleration / deceleration of the vehicle.
FIG. 10 is a conceptual diagram of a comparative example.
That is, in a region where the operation position is small, the vehicle can be decelerated as the accelerator pedal 8 is depressed, and in a region where the operation position is large, the vehicle can be accelerated as the accelerator pedal 8 is increased. However, since acceleration control is not performed until the operation position becomes a large region, in order to accelerate the vehicle from the state where the operation position is 0, the accelerator pedal 8 is depressed to some extent to find a position where acceleration control is started. There must be. Therefore, there is a possibility that the driver's burden of driving is to find the accelerator depression amount at which acceleration is started.

Next, this embodiment will be described.
In the present embodiment, the acceleration / deceleration of the vehicle is controlled according to the operation position S of the accelerator pedal 8, and the acceleration / deceleration control characteristics according to the operation position S are changed between the increase operation and the decrease operation. Is.
FIG. 11 is an example showing the operation of this embodiment.
First, it is assumed that the driver has not depressed the accelerator pedal 8. At this time, since the accelerator pedal 8 is in the non-operation position S ₀ (determination in S102 is “Yes”), a map is set as a forward control characteristic when the accelerator pedal 8 is depressed from the non-operation position S ₀ ( S103). In this forward path control characteristic, a characteristic line L1 connecting the point A [S ₁ , 0] and the point B [S _MAX , G _MAX ] is set.

Then, assume that the driver depresses the accelerator pedal 8. At this time, when the operation position S of the accelerator pedal 8 increases beyond the initial position S ₁ (determination in S104 is “Yes”), the target acceleration / deceleration G is set along the characteristic line L1 (step S106). ). In this forward path control characteristic, since the target acceleration / deceleration G is always a positive value, the driving force is increased via the driving force control device 6 and the braking force is set to 0 via the brake actuator 7 (S107). The vehicle accelerates according to the target acceleration / deceleration G.

  On a traveling direction gradient road, a vector heading toward the valley side acts on the vehicle by its own weight, and the more the road surface with respect to the traveling direction is an upward gradient, the more difficult the vehicle is accelerated. Conversely, the vehicle is more easily accelerated as the road surface with respect to the traveling direction has a downward slope. Therefore, even if the vehicle is stepped on to the same operation position S as on a flat road, the acceleration intended by the driver is lower on the ascending slope and exceeds the acceleration intended by the driver on the descending slope.

Therefore, the maximum acceleration / deceleration G _{MAX at} the point B that determines the inclination of the characteristic line L1 is set according to the road surface gradient θ. That is, the traveling direction and the road surface gradient of the vehicle are detected, and the maximum acceleration / deceleration G _MAX is increased as the road surface gradient with respect to the traveling direction is increased in the upward direction. Conversely, the maximum acceleration / deceleration is increased as the road surface gradient with respect to the traveling direction is increased in the downward direction. Reduce the speed G _MAX .
As a result, the vehicle is likely to accelerate on an ascending slope, and the vehicle is unlikely to accelerate on a descending slope. Therefore, even if the depression amount of the accelerator pedal 8 is the same, an acceleration equivalent to that on a flat road can be obtained regardless of whether it is an ascending slope or a descending slope. Therefore, even if the accelerator pedal 8 is depressed with the same feeling as that on a flat road, excessive or insufficient acceleration can be suppressed and the acceleration intended by the driver can be achieved.

Next, it is assumed that the driver depresses the accelerator pedal 8. At this time, when the operation position S decreases from a position before the maximum operation position S _MAX (determination in S104 is “No”), the operation position S and the target acceleration / deceleration G at the time when the decrease operation is detected are (S109), and the detection flag fd is set to 1 (S110).
When the operation position S decreases in the range from the operation position Sd at the time of decreasing operation detection to (Sd−α) (determination of S111 is “No”), the target acceleration / deceleration Gd at the time of detection of decreasing operation is maintained (S112). . This is a grace period for determining whether or not the reduction operation is intentional to the driver.

  When the driver depresses the accelerator pedal 8 while maintaining the target acceleration / deceleration Gd at the time of detecting the decrease operation (the determination in S104 is “Yes” and the determination in S105 is “No”), the forward path control characteristic is again obtained. Judge whether to return to. Specifically, if the operation position S is equal to or greater than the operation position Sd at the time of the decrease operation detection, the detection flag fd is reset to 0 because the driver's intentional increase operation (S121), and again according to the forward path control characteristics. The acceleration / deceleration of the vehicle is controlled (S106, S107).

When the operation position S falls below (Sd−α) (the determination in S111 is “Yes”), the map becomes a return path control characteristic when the accelerator pedal 8 is stepped back from the operation position Sd when the decrease operation is detected. Is set (S114). In this return path control characteristic, a characteristic line L2 connecting the point C [Sd, Gd] and the point E, and a characteristic line L3 connecting the point F and the point D [S ₁ , G _MIN ] are set.

Further, the switching flag fs is set to 1 (S115). Therefore, from now on, regardless of whether the operation position S increases or decreases, as long as the operation position S exceeds the non-operation position S ₀ (the determination in S101 is “No” and the determination in S117 is “Yes”). ), The acceleration / deceleration of the vehicle is controlled in accordance with the return path control characteristic (S116, S107). That is, even if there is a re-increase operation (re-depression) that increases the operation position S of the accelerator pedal 8 toward the maximum operation position S _MAX within the range beyond the non-operation position S ₀ after the decrease operation, it follows the return path control characteristics. .

  First, if the operation position S is in the section from the point C to the point E, the target acceleration / deceleration G is set along the characteristic line L2 (S116). In the section along the characteristic line L2, the target acceleration / deceleration G is always a positive value, so that the driving force is increased or decreased via the driving force control device 6 and the braking force is set to 0 via the brake actuator 7. (S107), the acceleration of the vehicle changes according to the target acceleration / deceleration G.

If the operation position S exceeds the operation position Sd at the time of detecting the decrease operation, the target acceleration / deceleration G is set along the characteristic line L1 (S116). Even in the section along the characteristic line L1, the target acceleration / deceleration G is always a positive value. Therefore, by increasing or decreasing the driving force via the driving force control device 6 (S107), The acceleration changes.
If the operation position S is in the dead zone β from the point E to the point F, the target acceleration / deceleration G is set to 0 (S116). That is, the driving force is set to 0 via the driving force control device 6 and the braking force is set to 0 via the brake actuator 7. At this time, the vehicle maintains the traveling state by inertia. In this way, since the dead zone β is provided at the boundary between the deceleration side and the acceleration side, the driver can easily grasp the switching position from the deceleration side to the acceleration side and the switching position from the acceleration side to the deceleration side. Can do.

  If the operation position S is in the section from the point F to the point D, the target acceleration / deceleration G is set along the characteristic line L3 (S116). In the section along the characteristic line L3, the target acceleration / deceleration G is always a negative value. Therefore, the driving force is limited to 0 or less via the driving force control device 6, and the braking force is increased or decreased via the brake actuator 7. By doing so (S107), the deceleration of the vehicle changes according to the target acceleration / deceleration G. If the driving force is set to a negative value of 0 or less, the rotational drive source is driven from the wheel side to cause a deceleration action. Therefore, when the negative target acceleration / deceleration G is relatively large (the absolute value is small), the control is reduced. It is not necessary to generate power.

  On a traveling direction gradient road, a vector heading toward the valley side due to its own weight acts on the vehicle, and as the road surface with respect to the traveling direction is an upward gradient, the vehicle is more easily decelerated. Conversely, the vehicle is less likely to decelerate as the road surface with respect to the traveling direction has a downward slope. Accordingly, even if the operation position S is stepped back to the same level as that on a flat road, the deceleration intended by the driver is exceeded on the ascending slope, and the deceleration intended by the driver is lowered on the descending slope.

Therefore, the minimum acceleration / deceleration G _{MIN at} the point D that determines the inclination of the characteristic line L3 is set according to the road surface gradient θ. That is, the traveling direction and the road surface gradient of the vehicle are detected, and as the road surface gradient with respect to the traveling direction increases in the upward direction, the minimum acceleration / deceleration G _MIN increases (decreases the deceleration) and conversely the road surface gradient with respect to the traveling direction decreases in the downward direction. The larger the value is, the smaller the minimum acceleration / deceleration _GMIN is set (the deceleration is increased).

As a result, the vehicle is less likely to decelerate on an ascending slope, and the vehicle is more likely to decelerate on a descending slope. Therefore, even if the return position of the accelerator pedal 8 is the same, a deceleration equivalent to that on a flat road can be obtained regardless of whether it is an upward gradient or a downward gradient. Therefore, even if the accelerator pedal 8 is stepped back with the same feeling as on a flat road, it is possible to suppress excessive or insufficient deceleration and achieve the deceleration intended by the driver.
Further, the minimum acceleration / deceleration G _MIN is set according to the operation position Sd at the time of detecting the decrease operation. Specifically, when the operation position Sd at the time of decreasing operation detection is less than a predetermined threshold th, the minimum acceleration / deceleration G _MIN is greater than the first reference value Gs1 _MIN (the absolute value is small) on the negative second side. Set the reference value Gs2 _MIN .

That is, when the operation position Sd at the time of detecting the decrease operation is small, the acceleration of the vehicle is low and the vehicle can be sufficiently decelerated even with a small deceleration. On the other hand, if an unnecessarily large deceleration is generated in a state where the acceleration is low, the ride behavior is affected by, for example, pitch behavior. Furthermore, when the vehicle is traveling at a relatively high vehicle speed, the accelerator pedal 8 may be repeatedly depressed and released (returned) to repeatedly turn on / off. In such a scene, it is necessary to generate a large deceleration. Absent. Therefore, when the operation position Sd at the time of decreasing operation detection is less than the threshold th, it is possible to suppress useless deceleration by increasing the minimum acceleration / deceleration _GMIN (decreasing the deceleration). Moreover, the occurrence of pitch behavior can be suppressed.

When the operation position S returns to the non-operation position S ₀ (determination in S117 is “No”), the target acceleration / deceleration G is gradually increased until it returns to 0 (S118). That is, the driving force is reduced to 0 via the driving force control device 6 and the braking force is gradually reduced via the brake actuator 7 (S107).
When the target acceleration / deceleration G returns to 0 (Yes in S119), the switching flag fs is reset to 0 (S120). Then, the driving force is set to 0 via the driving force control device 6 and the braking force is set to 0 via the brake actuator 7. At this time, the vehicle maintains the traveling state by inertia.

As described above, by changing the control characteristics of acceleration / deceleration according to the operation position S between the increase operation and the decrease operation, the vehicle is decelerated at the time of the decrease operation even at the same operation position S. The vehicle can be accelerated during the increase operation. Therefore, since the vehicle can be accelerated from the initial stage of the increase operation, it is not necessary to search for the position where the acceleration control is started unlike the comparative example, and the operability is improved.
In addition, in the increase operation, acceleration characteristics similar to those of a conventional vehicle that is not a one-pedal system can be obtained, and in the decrease operation, acceleration characteristics and deceleration characteristics based on the one-pedal system can be obtained.

In this embodiment, as a braking mechanism for decelerating the vehicle, a hydraulic brake using a hydraulic pressure as a transmission medium is employed. However, the present invention is not limited to this, and the transmission medium may be a cable, a link, or an air pressure. Any other braking mechanism using the above may be adopted. Even if the disc rotor is clamped by a brake pad or a friction brake that presses a brake shoe against the inner surface of the brake drum, an electromagnetic brake that generates a braking force by a magnetic resistance and a braking force that generates an air resistance Any other braking mechanism such as an aerodynamic brake that generates power and a regenerative brake that generates braking force by power generation may be adopted.
Further, in the present embodiment, the accelerator pedal 8 operated by the driver with his / her foot has been described. However, the present invention is not limited to this, and the present embodiment may be applied to an accelerator lever operated by the driver's hand. .
From the above, the accelerator pedal 8 corresponds to the “accelerator operator”, and the acceleration / deceleration control process corresponds to the “acceleration / deceleration control means”.

"effect"
(1) According to the acceleration / deceleration control device of the present embodiment, the control characteristic of the target acceleration / deceleration G corresponding to the operation position S is changed between the increase operation and the decrease operation.
In this way, by changing the control characteristic of the target acceleration / deceleration G according to the operation position S between the increase operation and the decrease operation, the vehicle can be operated at the same operation position S even during the decrease operation. It is possible to decelerate and accelerate the vehicle during an increase operation. Therefore, since the vehicle can be accelerated from the initial stage of the increase operation, it is not necessary to search for the position where the acceleration control is started unlike the prior art, and the operability is improved.

(2) According to the acceleration / deceleration control device of this embodiment, in the case of an increase operation, when the operation position S of the accelerator pedal 8 increases from the non-operation position S ₀ to the maximum operation position S _MAX , the target acceleration / deceleration G is The forward path control characteristic increases from 0 to a predetermined positive maximum acceleration / deceleration G _MAX .
In this way, during the increase operation, the same acceleration characteristic as that of a conventional vehicle that is not a one-pedal system can be obtained.

(3) According to the deceleration control device of the present embodiment, when the reduction operation, when the operating position S of the accelerator pedal 8 is reduced from reduction operation detection when the operation position Sd to a non-operation position S _0, target acceleration G follows the return path control characteristic which decreases from the decrease operation detection when target acceleration Gd to the minimum acceleration G _MIN predetermined negative.
Thus, at the time of the reduction operation, acceleration characteristics and deceleration characteristics based on the one pedal system can be obtained.

(4) According to the acceleration / deceleration control device of the present embodiment, in the case of a re-increasing operation, if the operating position S of the accelerator pedal 8 exceeds the non-operating position S ₀ and is within the range up to the operating position Sd at the time of detecting the decreasing operation. The acceleration / deceleration of the vehicle is increased along the return path control characteristic. Further, if the range of operating position S is reduced operation detection when the operation position Sd of the accelerator pedal 8 to a maximum operating position S _MAX, increasing the acceleration of the vehicle along the forward control characteristics.
In this way, acceleration characteristics and deceleration characteristics based on the one-pedal method can be obtained even during the re-increasing operation.

(5) According to the acceleration / deceleration control device of the present embodiment, the maximum acceleration / deceleration G _MAX is increased as the road surface increases in the traveling direction of the vehicle, and the road surface decreases in the traveling direction of the vehicle. The _{larger the value} is, the smaller the maximum acceleration / deceleration G _MAX is.
In this way, by making the maximum acceleration / deceleration G _MAX variable according to the road surface gradient, even if the accelerator pedal 8 is depressed with the same feeling as on a flat road, excessive or insufficient acceleration is suppressed, and the acceleration intended by the driver Can be achieved.

(6) According to the acceleration / deceleration control apparatus of the present embodiment, the minimum acceleration / deceleration G _MIN is increased as the road surface rises with respect to the traveling direction of the vehicle, and the road surface descends with respect to the traveling direction of the vehicle. The smaller is the minimum acceleration / deceleration _GMIN .
In this way, by making the maximum acceleration / deceleration G _MAX variable according to the road surface gradient, even if the accelerator pedal 8 is stepped back with the same feeling as on a flat road, the excessive or insufficient deceleration is suppressed, and the driver's The intended deceleration can be achieved.

(7) According to the acceleration / deceleration control apparatus of the present embodiment, the minimum acceleration / deceleration _GMIN is increased as the operation position Sd during the decrease operation detection is smaller.
As described above, by making the minimum acceleration / deceleration G _MIN variable according to the operation position Sd at the time of detecting the decreasing operation, it is possible to suppress unnecessary deceleration and to prevent occurrence of pitch behavior and the like.

(8) According to the acceleration / deceleration control method of the present embodiment, the target acceleration / deceleration G is controlled in accordance with the operation position S of the accelerator pedal 8, and the operation position S is set in the increase operation and the decrease operation. The control characteristic of the target acceleration / deceleration G is changed accordingly.
In this way, by changing the control characteristic of the target acceleration / deceleration G according to the operation position S between the increase operation and the decrease operation, the vehicle can be operated at the same operation position S even during the decrease operation. It is possible to decelerate and accelerate the vehicle during an increase operation. Therefore, since the vehicle can be accelerated from the initial stage of the increase operation, it is not necessary to search for the position where the acceleration control is started unlike the prior art, and the operability is improved.

<Modification>
In this embodiment, when the operation position S is returned to the non-operation position S ₀ during the reduction operation, the target acceleration / deceleration G is gradually returned to 0. However, the present invention is not limited to this. For example, even after the operation position S is returned to the non-operation position S ₀ , the minimum acceleration / deceleration G _MIN is maintained, and when the subsequent increase operation is detected, the target acceleration / deceleration G is returned to 0, and the operation position S is the initial position S ₁ the target acceleration G from the time beyond may be increased to the positive side.

DESCRIPTION OF SYMBOLS 1 Wheel rotation sensor 2 Acceleration sensor 3 Acceleration sensor 4 Shift sensor 5 Controller 6 Driving force control apparatus 7 Brake actuator 8 Accelerator pedal 10 Master cylinder 11FL to 11RR Each wheel cylinder 12A and 12B Gate valve 13FL to 13RR Inlet valve 14 Accumulator 15FL to 15RR Outlet valve 16A, 16B Gate valve 17 Pump 18 Damper chamber fd Detection flag fs Switching flag Gd Target acceleration / deceleration G _MAX at the time of decrease operation detection _MAX maximum acceleration / deceleration G _MIN minimum acceleration / deceleration Gs1 _MIN first reference value Gs2 _MIN second reference value Gs _MAX Reference value ka Gradient coefficient kr Gradient coefficient S Operation position S ₀ Non-operation position S ₁ Initial position Sd Decreasing operation detection operation position S _MAX maximum operation position th Threshold value α Setting value β Dead band

Claims (8)

An accelerator operator that can be operated by the driver in the range from the non-operating position to the maximum operating position;
Acceleration / deceleration control means for controlling the acceleration / deceleration of the vehicle according to the operation position of the accelerator operator,
An operation for increasing the operation position of the accelerator operation element from the non-operation position toward the maximum operation position is defined as an increase operation, and the operation position of the accelerator operation element is within a range excluding the non-operation position after the increase operation. Is defined as a decreasing operation,
The acceleration / deceleration control means includes
An acceleration / deceleration control apparatus that changes control characteristics of the acceleration / deceleration according to the operation position between the increase operation and the decrease operation. Define a positive acceleration / deceleration as acceleration, a negative value as deceleration,
The acceleration / deceleration control means includes
When detecting the increase operation,
When the operating position of the accelerator operating element increases from the non-operating position to the maximum operating position, the vehicle acceleration / deceleration follows a forward path control characteristic that is a characteristic that increases from 0 to a predetermined positive maximum acceleration / deceleration. The acceleration / deceleration control apparatus according to claim 1. Define a positive acceleration / deceleration as acceleration, a negative value as deceleration,
The operation position and the acceleration / deceleration at the time when the decrease operation is detected are set as the operation position at the time of detection of the decrease operation and the acceleration / deceleration at the time of detection of the decrease operation, respectively.
The acceleration / deceleration control means includes
When detecting the decrease operation,
When the operation position of the accelerator operation element decreases from the operation position at the time of the decrease operation detection to the non-operation position, the acceleration / deceleration of the vehicle increases from the acceleration / deceleration at the time of the decrease operation detection to a predetermined minimum negative acceleration / deceleration speed. The acceleration / deceleration control apparatus according to claim 1 or 2, wherein the acceleration / deceleration control apparatus conforms to a return path control characteristic which is a decreasing characteristic. An operation for increasing the operation position of the accelerator operator toward the maximum operation position in a range excluding the non-operation position after the decrease operation is defined as a re-increase operation.
The acceleration / deceleration control means includes
When detecting the re-increasing operation,
If the operation position of the accelerator operator exceeds the non-operation position and is within the range up to the operation position at the time of detection of the decrease operation, the acceleration / deceleration of the vehicle is increased along the return path control characteristics,
The acceleration / deceleration of the vehicle is increased along the forward path control characteristic if the operation position of the accelerator operation element is in a range from the operation position at the time of the decrease operation detection to the maximum operation position. The acceleration / deceleration control device described. The acceleration / deceleration control means includes
The maximum acceleration / deceleration is increased as the road surface rises with respect to the traveling direction of the vehicle,
The acceleration / deceleration control apparatus according to any one of claims 1 to 4, wherein the maximum acceleration / deceleration is decreased as the road surface is inclined downward with respect to the traveling direction of the vehicle. The acceleration / deceleration control means includes
The minimum acceleration / deceleration is increased as the road surface is ascending with respect to the traveling direction of the vehicle,
The acceleration / deceleration control device according to any one of claims 1 to 5, wherein the minimum acceleration / deceleration is decreased as the road surface is inclined downward with respect to the traveling direction of the vehicle. The acceleration / deceleration control means includes
The acceleration / deceleration control apparatus according to any one of claims 3 to 6, wherein the minimum acceleration / deceleration is increased as the operation position at the time of detecting the decrease operation is smaller. The accelerator operator can be operated in the range from the non-operating position to the maximum operating position.
An operation for increasing the operation position of the accelerator operation element from the non-operation position toward the maximum operation position is an increase operation, and the operation position of the accelerator operation element is set within a range excluding the non-operation position after the increase operation. The operation to decrease toward the non-operation position is defined as a decrease operation,
The acceleration / deceleration of the vehicle is controlled according to the operation position of the accelerator operation element, and the control characteristic of the acceleration / deceleration according to the operation position is changed between the increase operation and the decrease operation. A characteristic acceleration / deceleration control method.

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