JP2018043720A - Slide suppression control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vehicle control device capable of determining quickly and correctly, whether or not it is in a state in which a vehicle requires control intervention to slip by a vehicle control device and improving safety property.SOLUTION: A vehicle control device comprises: vehicle motion estimation means 13 for estimating a motion state of a vehicle or wheels on the basis of at least any of a position of the vehicle or wheels, speed and acceleration; slip estimation means 14 for estimating a slip state of the vehicle to a road surface on the basis of the estimation result; and slip suppression control means 15 for giving an instruction to a vehicle drive device 1 according to the estimated slip state. The slip estimation means 14 has a delay compensation device for performing a delay compensation, and outputs plural different estimation results for the delay compensation. The slip suppression control means 15 applies an instruction for correcting the slip state by a result of a prescribed determination including a comparison of the plural estimation results.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a slip suppression control device that controls the behavior of a vehicle such as an automobile.

Conventionally, the following invention has been proposed as a control method of a slip suppression control device.
ABS control that changes the threshold value for starting ABS according to the amount of change in pedaling force (Patent Document 1).
ABS control that adjusts the upper limit of wheel deceleration according to the amount of change in pedaling force (Patent Document 2).
An ABS control method using a drive motor (Patent Document 3).
-Braking force control for preventing the vehicle from being oversteered or understeered (Patent Document 4).
A method of calculating the deviation between the standard yaw rate obtained based on the vehicle speed and the steering angle and the actual yaw rate detected by the yaw rate sensor, and controlling the operation of the driving force distribution device and the skid prevention device according to this deviation (Patent Document) 5).

JP-A 64-63448 JP-A-4-293654 JP 2001-97204 A JP 2011-162145 A JP H9-86378

For example, in an anti-lock control device, in order to shorten the braking distance of a vehicle, it is required to quickly and accurately determine that a wheel has a slip tendency.
For example, when the slip ratio is estimated and the slip tendency is judged by comparison with a threshold value, the slip ratio threshold value is influenced by an estimation error of a road surface condition, an estimation error / noise of a wheel speed sensor, etc. in order to prevent malfunction. Therefore, it is necessary to make a judgment with the slip tendency sufficiently strengthened. The noise can be removed by, for example, a low-pass filter, but the delay by the low-pass filter becomes a detection delay.

  When adjusting the severity of judgment of the slip tendency according to changes in the pedaling force as in Patent Documents 1, 2, and 3, for example, when the tire shifts to the slip tendency due to a moderate brake pedaling force increase from a high load, Alternatively, when the brake pedal force changes from a small change to a slip tendency due to road surface fluctuations, there is a problem that the timing for starting the antilock brake operation is delayed by the above processing. In addition, even if the vehicle operator does not intend, the brake pedal force may change greatly due to the vibration of the vehicle or the trembling of the foot that operates the pedal. There is a possibility that the start timing must be designed conservatively.

Further, for example, in the skid prevention control device, in order to effectively stabilize the behavior of the vehicle, it is required to quickly and accurately determine that the vehicle is in an oversteer or understeer tendency.
For example, when the yaw rate of the vehicle is detected using an acceleration sensor and it is determined that there is an oversteer or understeer tendency by comparison with a threshold value such as a reference yaw rate, the reference yaw rate or the like may be used to prevent malfunction. The threshold value needs to be set to a value that can determine that the oversteer or understeer tendency is sufficiently strong in consideration of the influence of the estimation error of the road surface condition, the estimation error of the acceleration sensor, noise, and the like. The noise can be removed by, for example, a low-pass filter, but there is a problem that the delay by the low-pass filter becomes a delay for detecting that there is an oversteer or understeer tendency.

  An object of the present invention is to provide a vehicle control device that can quickly and accurately determine whether or not the vehicle requires a control intervention for slip by the vehicle control device, and that improves safety.

The slip suppression control device of the present invention is a slip suppression control device 12, 12A, 12B that controls the vehicle drive devices 1, 1A, 1B capable of generating at least one of the longitudinal force and turning force of the vehicle,
Vehicle motion estimation means 13, 13B for estimating the motion state of the vehicle or wheel based on at least one of the position, speed, and acceleration of the vehicle or wheel;
Based on the estimation results of the vehicle motion estimation means 13 and 13B, a slip estimation means 14 for estimating a slip state of the vehicle in a predetermined direction with respect to a road surface in contact with the vehicle;
Slip suppression control means 15, 15A, 15B for giving commands to the vehicle drive devices 1, 1A, 1B according to the slip state estimated by the slip estimation means 14,
The slip estimation means 14 has one or more delay compensators that perform delay compensation for the estimation results of the vehicle motion estimation means 13 and 13B, and a plurality of mutually different delay compensation results are estimated as the slip condition estimation results of the vehicle. Output the estimation result,
The slip suppression control means 15, 15 </ b> A, 15 </ b> B corrects the slip state in the vehicle drive devices 1, 1 </ b> A, 1 </ b> B based on a result of a predetermined determination including a comparison of the plurality of estimation results output from the slip estimation means 14. Give a directive to
The “predetermined determination” is an appropriately determined determination.

According to this configuration, the slip estimation unit 14 has one or more delay compensators that perform delay compensation on the estimation result of the vehicle motion estimation unit, and a plurality of mutually different delay compensations are obtained as the estimation result of the slip state of the vehicle. The estimation result of is output. The slip suppression control means 15, 15 </ b> A, 15 </ b> B gives a command to the vehicle drive devices 1, 1 </ b> A, 1 </ b> B according to a result of a predetermined determination including a comparison of the output plurality of estimation results.
Since a plurality of different estimation results are compared for delay compensation in this way, it can be accurately determined that the vehicle is in a slip tendency, and even if the threshold value is reduced, determination can be made without error, so that determination can be made quickly. As a result, it is possible to quickly and accurately determine whether or not the vehicle is in a state requiring control intervention for slip by the vehicle control devices 8 and 8A, and the safety of the vehicle can be improved.

In the present invention, the slip estimation means 14 has two or more delay compensators having different frequency characteristics as the delay compensator, and the slip suppression control means 15, 15A, 15B include the plurality of estimation results. The comparison may be performed by using either the difference between the estimation results via the different delay compensators or the integrated value of the differences.
By providing two or more delay compensators with different frequency characteristics in this way, and using the difference between the estimation results of these two or more delay compensators, the wheels tend to slip even more quickly and accurately. Can be judged. Since the slip determination is fast, the deviation of the vehicle motion with respect to the normative behavior is small, and a more desirable slip state can be maintained. The difference may be compared as it is, but if an integrated value is obtained and the integrated value is compared, it can be determined more accurately that the wheel is in a slip tendency.

In the present invention, the slip suppression control means 15, 15A, 15B compares the plurality of estimation results between the slip estimation result via the delay compensator and the estimation result not via the delay compensator. You may make it carry out by either the difference or the integrated value of this difference.
Thus, compared with the case where the slip estimation result via the delay compensator and the difference between the estimation result without the delay compensator are judged by comparison between the estimation result without the delay compensator and the threshold value, It is possible to quickly and accurately determine that the vehicle is slipping.

In the present invention, the delay compensator may be a state estimator including an error correction feedback element between an estimated output via an equation of motion and an output from the delay compensator.
In the case of such a state estimator, it can be determined more quickly and accurately that there is a tendency to slip.

In the present invention, the delay compensator may be a low-pass filter that attenuates frequencies exceeding a predetermined frequency.
If it is a low-pass filter, the delay compensator can have a simple configuration.

In the present invention, the vehicle drive device 1 is at least one of a device that applies rotational torque independently to each wheel provided in the vehicle, and a device 1B that provides a turning angle to the wheel,
The vehicle motion estimation means 13, 13B is a means for estimating at least one of a yaw rate of the vehicle or a value corresponding to a yaw rate and a side slip angle of the vehicle or a value corresponding to a side slip angle;
As the estimation result of the slip state of the vehicle, the slip estimation unit 14 estimates the result of the vehicle motion estimation unit 13 or 13B, and a value corresponding to the yaw rate obtained by a predetermined calculation regardless of the vehicle motion estimation unit 13. And an estimation result based on a comparison with at least one of a side slip angle of the vehicle or a value corresponding to a side slip angle,
The slip suppression control means 15 may be a skid prevention control means 15B that gives a command to the vehicle drive devices 1, 1A, 1B so that the comparison result of the slip estimation means 14 becomes small.
In the case of this configuration, when performing the skid prevention control, it is possible to quickly and accurately determine whether or not the vehicle requires a control intervention with respect to the slip by the vehicle control device 8, and safety is improved.

  A slip suppression control device of the present invention is a slip suppression control device that controls a vehicle drive device capable of generating at least one of a longitudinal force and a turning force of a vehicle, and includes at least the position, speed, and acceleration of the vehicle or wheels. Vehicle motion estimation means for estimating the motion state of the vehicle or wheel based on any of the above, and slip estimation means for estimating a slip state of the vehicle in a predetermined direction with respect to a road surface in contact with the vehicle based on the vehicle motion estimation means; And a slip suppression control means for giving a command to the vehicle drive device according to the slip state estimated by the slip estimation means, and the slip estimation means performs delay compensation for the estimation result of the vehicle motion estimation means. One or more delay compensators are provided, and a plurality of different estimation results for delay compensation are output as the slippage estimation state of the vehicle, and the slip suppression is performed. The braking / control unit gives a command to correct the slip state to the vehicle drive device according to a result of a predetermined determination including a comparison of the plurality of estimation results output from the slip estimation unit. It is possible to quickly and accurately determine whether or not the control intervention for the slip is necessary, thereby improving safety.

It is a block diagram which shows the conceptual structure of the slip suppression control apparatus which concerns on one Embodiment of this invention. It is a block diagram which shows the conceptual structure of the anti-lock brake control apparatus which is a slip suppression control apparatus which concerns on other embodiment of this invention. It is explanatory drawing of an effect | action of the anti-lock brake control apparatus. (A), (B) is a graph which shows each example of the anti-lock control waveform of the anti-lock brake control apparatus, respectively. It is a flowchart of the operation example of the anti-lock control means in the anti-lock brake control device. It is a block diagram which shows the structural example of the filter which is a delay compensator of the antilock brake control apparatus. It is a block diagram which shows the other structural example of the filter which is a delay compensator of the antilock brake control apparatus. It is explanatory drawing which shows the example of the frequency characteristic of the filter. It is explanatory drawing of an example of the brake device used as the control object of the anti-lock brake control device. It is a block diagram which shows the conceptual structure of the skid prevention control apparatus which is a slip suppression control apparatus which concerns on other embodiment of this invention.

A first embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows a slip suppression control system for a vehicle such as an automobile. The vehicle control device 8 includes a slip suppression control device 12 and a drive device control means 11.
The vehicle operation means 9 includes, for example, an accelerator pedal, a brake pedal, a steering, and the like. Alternatively, the vehicle operation unit 9 may be, for example, a vehicle integrated control device for an automatically driven vehicle, and may generate a basic propulsion force or a turning force command based on a travel route of the vehicle.
The acceleration estimating means 19A may be, for example, an acceleration sensor. The position estimating means 19A may be a GPS sensor, for example.
The vehicle drive device 1 may be, for example, a drive motor, a friction brake, or a steering device. If the vehicle drive device 1 is a drive-by-wire system that is driven by an electrical signal without mechanical coupling, slip suppression control can be performed smoothly.

The slip suppression control device 12
Normative behavior generating means 21 for estimating a normative vehicle behavior with respect to a predetermined operation input;
Vehicle motion estimation means 13 for estimating any one or more of the position, speed, and acceleration of the vehicle;
Slip estimation means 14 for estimating the slipping state of the vehicle with respect to the contact surface using the estimation result of the vehicle motion estimation means 13;
And a slip suppression control means 15 for giving a command to the vehicle drive device 1 in accordance with the slip state of the vehicle estimated by the slip estimation means 14.
The slip estimator 14 includes a slip estimator 16 that estimates the slip state of the vehicle with respect to the ground plane, and one or more delay compensators 17a and 17b that perform delay compensation for the estimation result of the vehicle motion estimator. Then, as the estimation result of the slip state of the vehicle, a plurality of estimation results different from each other for delay compensation are output,
The slip suppression control unit 15 gives a command to the vehicle drive device 1 according to a result of a predetermined determination including a comparison of the plurality of estimation results output from the slip estimation unit 14.

  The anti-slip control device 12 may be, for example, an anti-lock control device that prevents wheel lock at the time of braking, or a traction control device that prevents wheel spin at the time of starting, and excessive oversteer during turning. Or the skid prevention control apparatus which prevents an understeer may be sufficient.

  FIG. 2 shows an embodiment in which the slip suppression control device 12 according to the embodiment of FIG. 1 is embodied as an antilock brake control device 12A in a brake control device 8A that is a kind of the vehicle drive device 1, and a vehicle such as an automobile. The entire brake system is shown. The brake device 1A is installed on all the wheels of the vehicle, that is, two left and right wheels that are front wheels and two left and right wheels that are rear wheels. The brake device 1 </ b> A includes a brake rotor 3 disposed coaxially with the wheel 2, a friction material 4 in contact with the brake rotor 3, and a friction material drive mechanism 5 that operates the friction material 4. The brake rotor 3 may be a disk type or a drum type. The friction material 4 includes a brake pad or a brake shoe. The friction material drive mechanism 5 may be electric or hydraulic, but the illustrated example is an electric brake device. The electric motor 6 and the rotation of the motor 6 are reciprocated linearly by the friction material 4. It is mainly composed of a ball screw device that converts motion and a linear motion mechanism 7 such as a planetary roller screw mechanism. FIG. 9 shows a specific example of the brake device 1A. As shown in FIG. 9, the friction material drive mechanism 5 of the brake device 1 </ b> A may transmit the rotation of the motor 6 to the linear motion mechanism 7 via a speed reduction mechanism 5 a such as a gear train.

  In FIG. 2, a brake control device 8A is provided for each brake device 1A. A braking command input from a brake operating means 9A such as a brake pedal is distributed to each brake control device 8A from a braking command distribution means 11A provided in an ECU (electronic control unit) 10 that controls the entire vehicle, and brake control is performed. The brake device 1A is controlled by the device 8A.

  Each brake control device 8A includes a brake operation basic control means 11A for controlling the friction material driving mechanism 5 in accordance with a braking command given from a braking command distribution means 11A provided in the ECU 10, and an antilock brake control device 1A. ing. The anti-lock brake control device 12A may be provided in the ECU 10 or the like, but is provided in each brake control device 8A in this embodiment.

  The anti-lock brake control device 12A includes a wheel motion estimation unit 13, a slip estimation unit 14, and an anti-lock control unit 15A. The slip estimation unit 15A includes a slip estimation unit 16 and a first delay compensator. A filter 17a and a second filter 17b are provided. In the following description, the first filter 17a may be referred to as a filter (1), and the second filter 17b may be referred to as a filter (2).

  The wheel motion estimation means 13 is a means for estimating any one or more of the rotation angle, angular velocity, and angular acceleration of the wheel 2. The wheel motion estimation means 13 estimates the angle, angular velocity, angular acceleration, and the like by, for example, wheel rotation detection means 19D installed on a wheel bearing (not shown) of the wheel 2 and an axle. The angular velocity becomes a wheel speed if converted into a wheel. As a method for detecting the wheel speed, a method of measuring an edge interval at a pulse output of about 30 to 50 per rotation is common in a commercial vehicle. For example, a general rotary encoder or resolver is used as the wheel rotation detection means. It may be used as 19D.

The slip estimation means 15A is a means for estimating the slip state of the wheel 2 with respect to the contact surface using the estimation result of the wheel motion estimation means 13, and basically, the slip estimation unit 16 determines the vehicle speed ω _V A slip ratio S1, which is a ratio to the wheel speed ω, is estimated. Vehicle speed ω _V is obtained from the speed estimating means 19C. Speed estimating unit 19C is not directly limited to the sensor for detecting the vehicle speed omega _V, it may be one that detects the vehicle speed omega _V from the rotational speed of the driven wheels.

As a specific derivation formula for the slip ratio S1, for example, the non-slip state may be 0 and the complete slip state where the wheel is locked may be 1.
S1 = (ω _V −ω) · ω _V ⁻¹

  The filters (1) and (2), which are the filter delay compensators, are means for performing delay compensation for the estimation result of the wheel motion estimation means 13, and in this embodiment, for the estimation result of the slip estimation unit 16 Delay compensation. Each of the filters (1) and (2) includes, for example, a state estimator including an error correction feedback element between an estimated output through an equation of motion described later with reference to FIG. 6 and an actual output, that is, an output from the delay compensator. Or a low-pass filter as shown in FIG. The low-pass filter is a filter that attenuates frequencies exceeding a predetermined frequency. The two filters (1) and (2) have the same configuration except that they have different frequency characteristics, and the first filter (1) has higher frequency characteristics than the second filter (2).

  The anti-lock control means 15A gives a command to the friction material drive mechanism 5 to reduce the braking force according to a result of a predetermined determination including a comparison of the plurality of estimation results output from the slip estimation means 14. In this case, the antilock control unit 15A compares the estimation results of the plurality of filters (1) and (2), or the difference between the estimation results via the different filters (1) and (2), or This is done by comparing one of the integrated values of the differences with a threshold value. A specific processing example of the antilock control means 15A will be described later with reference to FIG. In the anti-lock control means 15A, the command to reduce the braking force may be given to the friction material drive mechanism 5 via the brake operation basic control means 11A, or directly without solving the brake operation basic control means 11A. Alternatively, the friction material driving mechanism 5 may be provided.

  The operation of the above configuration will be described. FIG. 3 shows the calculated value of the slip ratio by the slip estimation unit 16 and the waveform of the slip ratio through the filters (1) and (2). Here, as the responsiveness of the filters (1) and (2), the filter (1) is a faster filter than the filter (2). Further, the difference between the filter (1) and the filter (2) is shown in FIG. Here, the stronger the rising tendency of the slip ratio, the greater the difference between the filter (1) and the filter (2). Therefore, the slip tendency can be determined from the difference. Note that, in addition to the difference, the slip ratio ratio output by the filter (1) and the filter (2), the integrated value of the difference, or the like may be used for the determination of the slip tendency.

  In the same figure, the example which determines the excessive slip state of a wheel is shown in an enlarged view. For example, when the threshold value is directly applied to the derived slip ratio, the threshold value is determined in consideration of various estimation errors such as the influence of noise and road surface condition, and overslip is determined at the timing a in the figure. In addition, when a threshold value is applied to the filter (1), the influence of noise is alleviated with respect to the determination of a, and overslip is determined at the timing of b. On the other hand, for example, in the case where the difference threshold value of the filter (1) and the filter (2) is used as an AND condition in addition to the threshold value of the filter (1), the amount of slip tendency is determined as described above. Since the threshold value can be set strictly for the above-mentioned a and b, it is possible to detect at the timing c in the figure.

  In this example, the trend determination of two lines is performed, but the trend determination may be performed by comparing three or more lines having different response speeds. In that case, the degree of freedom in determining the tendency is improved by a plurality of patterns such as the vertical relationship of each line.

FIG. 4 shows an example of the antilock control waveform. FIG. 6A shows an example in which this embodiment is applied and overslip determination is performed at the timing c in FIG.
FIG. 6B shows an example by simple threshold comparison as shown in FIG. Compared with FIG. 6B, the over-slip determination is faster in FIG. 6A, so that the deviation of the wheel speed from the vehicle speed is small and a more desirable slip state, that is, a slip state in which the maximum braking force can be obtained. Can hold.

FIG. 5 shows an example of the operation performed by the antilock control means 15A. In the figure, the slip ratio and the filter calculation are processes performed by the slip estimation means in FIG.
In step S1, the slip estimation unit 16 (FIG. 2) derives the slip rate S1.
The derived slip rate S1 is compared with the threshold value S1 _LIMR (step S2), and if the slip rate S1 is equal to or greater than the threshold value S1 _LIMR , it is determined that the slip is excessive (step S8). If it is determined that the slip is excessive, a command to reduce the braking force is given to the brake device 1A.

If the slip ratio S1 is not _{equal to} or greater than the threshold S1 _LIMR in step S2, the slip ratio S1 _LPF1 is derived by the filter (1) (step S3), and the slip ratio S1 _LPF2 is derived by the filter (2) (step S4). The difference ΔS1 is calculated (step S5). This difference ΔS1 is compared with the first threshold value S1 _th1 (step S6). If the difference ΔS1 is not equal to or greater than the first threshold value S1 _th1 , the process returns to repeat the process of FIG.

If the difference ΔS1 is greater than or equal to the first threshold value S1 _th1 , the difference ΔS1 is compared with the second threshold value S1 _th1 (step S7), and if it is not greater than or equal to the second threshold value S1 _th2 , return is made and the processing of FIG. repeat. If it is equal to or greater than the second threshold value S1 _th2 , it is determined that the slip is excessive (step S8), and a command to reduce the braking force is given to the friction device 1A to the brake device 1A.

  Thus, in order to compare the estimation results obtained by performing a plurality of different delay compensation for the slip rate, it is possible to accurately determine that the wheel 2 is in a slip tendency, and even if the threshold value is reduced, the determination is not erroneous. Therefore, it can be judged quickly. As a result, the braking distance of the vehicle can be shortened.

FIG. 6 shows a configuration example of the filter (1) 17a and the filter (2) 17b. Since the first and second filters (1) and (2) are the same except that their constants are different from each other, only one filter (1) will be described. The filter (1) in the figure is an example constituting a state estimation observer.
In the figure, A, B, and C are state transition matrices based on the wheel equation of motion, u (k) is the braking force, and y (k) is the wheel speed. x (k) is a filter state quantity. L represents the observer gain, and the error convergence condition is determined by the eigenvalue of A-LC. Z ⁻¹ indicates a delay of one sample.

  In configuring the filters (1) and (2), for example, parameters relating to inertia in the state transition matrix can be adjusted. Further, it may be adjusted according to the value of the observer gain L, or these may be used in combination.

In addition, the state transition matrix based on the equation of motion of the wheels A, B, and C is, for example, the following equation.

  In addition to this, the configuration of the filters (1) and (2) may be implemented by a general low-pass filter, for example, as shown in FIG. 7, or by a moving average line having a different sampling number. Also good.

  FIG. 8 shows an example of the characteristics of the filters (1) and (2). The high speed filter (1) may be adjusted so that the gain in the high frequency region is higher than that of the filter (2).

  In the embodiment, the slip estimation means 14 is provided with a plurality of filters (1) and (2). However, the anti-lock control means is provided with a single delay compensator (filter) provided in the slip estimation means 14. 15A compares the plurality of estimation results by either the difference between the slip estimation result via the delay compensator and the estimation result not via the delay compensator, or the integrated value of the difference. You may make it do. In this case, a delay compensator having the same configuration as that of the filter (1) can be used.

  In this embodiment, the case where the brake device 1B is a friction brake has been described. However, the brake device 1B may be a device that performs regenerative control by an electric motor (not shown) for driving the vehicle. . In that case, the brake control device 8A, which is a kind of drive control means, is a motor control device that controls the motor, and performs regenerative braking by giving a negative torque command. When this regenerative braking is performed, the control by the anti-lock control means 15A is performed in the same manner as in the case of the friction brake. In addition, the motor which comprises the motor drive device which can drive each wheel independently like an in-wheel motor drive device may be sufficient as the said motor.

FIG. 10 shows an embodiment in which the slip suppression control device 12 according to the embodiment of FIG. 1 is applied to a skid prevention control device 12B that is a kind of the vehicle drive device 1, and shows a skid prevention control system for a vehicle such as an automobile. . The steered device 1B is a kind of the vehicle drive device, and for example, a steer-by-wire steered device that detects the steering angle of the steering wheel 9B and controls the steered angle with an electric motor in accordance with the detected steering angle. it can.
The normative yaw rate generating means 21B is a kind of the normative behavior generating means 21. For example, a function for generating a normative yaw rate by a vehicle motion model calculation or the like from the steering angle of the steering wheel 9B, the vehicle speed, and other accelerations. And have. The reference yaw rate generation means 21B may have a function of calculating the reference side slip angle from the above, or may use both the yaw rate and the side slip angle.
The yaw rate estimation means 13B is a kind of the vehicle motion estimation means 13, and estimates the yaw rate from the acceleration, position, speed, etc. of the vehicle.
The slip estimation means 14 has a function of estimating the skid state of the vehicle by comparing the reference yaw rate with the estimated yaw rate, for example.
The skid prevention control calculation means 15B is a kind of the slip suppression control means 15 and the steering angle and the brake device for each wheel so that the slip estimation means 14 corrects oversteer or understeer due to the side slip state of the vehicle. It can be set as the function which gives a command to either one or both of 1B.

  In the case of this configuration, when performing the skid prevention control, it is possible to quickly and accurately determine whether or not the vehicle requires a control intervention for the slip by the vehicle control device 8, and the safety is improved.

In each of the above embodiments, the slip suppression control means 15, 15 A, 15 B is output from the slip estimation means 14 before the determination by comparing the plurality of estimation results output from the slip estimation means 14. Even when the output for which delay compensation is not performed is equal to or greater than the threshold value, a command to reduce the braking force may be given.
As a result, when there is an obvious slip tendency, slip suppression control can be performed more quickly without the delay compensation calculation time.

  As mentioned above, although the form for implementing this invention based on embodiment was demonstrated, embodiment disclosed this time is an illustration and restrictive at no points. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

DESCRIPTION OF SYMBOLS 1 ... Vehicle drive device 1A ... Brake device (vehicle drive device)
1B ... Steering device (vehicle drive device)
2 ... wheel 3 ... brake rotor 4 ... friction material 5 ... friction material drive mechanism 8 ... vehicle control device 8A ... brake control device (vehicle control device)
12 ... Slip suppression control device 12A ... Anti-lock brake control device (slip suppression control device)
13 ... Wheel motion estimation means 13B ... Yaw rate estimation means (wheel motion estimation means)
14 ... slip estimation means 15 ... slip suppression control means 15A ... anti-lock control means (slip suppression control means 15B ... skid prevention control means (slip suppression control means)
16 ... slip estimation units 17a and 17b ... filter (lag compensator)
21 ... normative behavior generating means 21B ... normative yaw rate generating means

Claims (6)

A slip suppression control device for controlling a vehicle drive device capable of generating at least one of a longitudinal force and a turning force of a vehicle,
Vehicle motion estimation means for estimating the motion state of the vehicle or wheel based on at least one of the position, speed, and acceleration of the vehicle or wheel;
Slip estimation means for estimating a slip state of the vehicle in a predetermined direction with respect to a road surface in contact with the vehicle, based on an estimation result of the vehicle motion estimation means;
A slip suppression control means for giving a command to the vehicle drive device in accordance with the slip state estimated by the slip estimation means,
The slip estimation means has one or more delay compensators that perform delay compensation for the estimation result of the vehicle motion estimation means, and outputs a plurality of different estimation results for delay compensation as the estimation result of the slip condition of the vehicle. And
The slip suppression control means gives a command to correct the slip state to the vehicle drive device according to a result of a predetermined determination including a comparison of the plurality of estimation results output from the slip estimation means. Suppression control device.   The slip suppression control device according to claim 1, wherein the slip estimation unit includes two or more delay compensators having different frequency characteristics as the delay compensator, and the slip suppression control unit includes the plurality of slip suppression control units. A slip suppression control device that compares estimation results by either a difference between estimation results via the different delay compensators or an integrated value of the differences.   2. The slip suppression control device according to claim 1, wherein the slip suppression control unit compares the plurality of estimation results by comparing the slip estimation result via the delay compensator and the estimation not via the delay compensator. 3. The slip suppression control apparatus performed by either the difference with a result, or the integrated value of this difference.   4. The slip suppression control device according to claim 1, wherein the delay compensator includes an error correction feedback element between an estimated output via an equation of motion and an output from the delay compensator. 5. A slip suppression control device that is a state estimator.   The slip suppression control apparatus according to any one of claims 1 to 4, wherein the delay compensator is a low-pass filter that attenuates a frequency exceeding a predetermined frequency. 5. The slip suppression control device according to claim 1, wherein the vehicle drive device applies a rotational torque independently to each wheel of the vehicle, and steers the wheel. One or both of the devices providing the corners,
The vehicle motion estimation means is means for estimating at least one of a yaw rate of the vehicle or a value corresponding to a yaw rate and a value corresponding to a side slip angle or a side slip angle of the vehicle;
The slip estimation means, as an estimation result of the slip state of the vehicle, an estimation result of the vehicle motion estimation means, a value corresponding to a yaw rate obtained by a predetermined calculation irrespective of the vehicle motion estimation means, and a side slip of the vehicle Output an estimation result based on comparison with at least one of the values corresponding to the angle or sideslip angle,
The slip suppression control device, wherein the slip suppression control device is a skid prevention control device that gives a command to the vehicle drive device so that a comparison result of the slip estimation device is small.