The present invention relates in general to a method for estimating the propensity of a vehicle to rollover, and more specifically, to a method for detecting an approach to a rollover event of a vehicle and providing a corrective action to reduce the likelihood of an actual rollover.
Dynamic stability control systems have been implemented in vehicles to deter a vehicle from actually rolling over. Vehicle rollovers have become a growing concern for vehicles with a high center of gravity and especially those used for multiple purposes in different geographical locations. A vehicle may have the potential to rollover due to forces exerted on the vehicle under different types of operating conditions. Methods have been used to anticipate when the vehicle has the propensity to rollover and to make adjustments to counteract vehicles having that propensity from rolling over.
A rollover event, as used in this application, is defined as a moment when current vehicle operating conditions (e.g., speed, steering angle, lateral acceleration, etc.) approach a threshold where the rollover could actually occur. Typically, stability control systems detect or estimate the propensity for a rollover event to occur by measuring a roll angle or a roll rate. This requires a dedicated sensor for determining the roll angle at each instance the vehicle is in travel. Sensors are costly and require dedicated wiring and packaging locations. Vehicle manufacturers are consistently looking for reliable methods which can obtain the same results yet cost less and minimize the number of components on the vehicle.
It is also known to use differential braking to induce understeer and limit lateral acceleration. Such methods include electronic stability control and active roll management. These systems typically detect critical lateral acceleration, wheel lift detection, vehicle roll rate (roll angle), and roll energy. Suspension based systems use active roll control and active damper controls. Steering based systems typically use active front steer (steering angle overlay) and four wheel steering (active rear steer) to control tire lift from occurring. Each of these methods typically use vehicle inertial based sensors.
Another method for detecting a rollover event of a vehicle and providing a corrective action to reduce the likelihood of an actual rollover is described in pending U.S. patent application Ser. No. 10/719,968 filed Nov. 21, 2003 (hereinafter referred to as the '968 application), the disclosures of which are incorporated herein by reference. The invention disclosed provides a method for detecting a rollover event of a vehicle and providing a corrective action to counteract an actual rollover by using lateral kinetic energy and lateral acceleration of the vehicle to detect the rollover propensity. In one aspect of the invention, a method is provided for detecting a rollover propensity of a vehicle. A lateral kinetic energy of the vehicle is determined in response to vehicle longitudinal velocity and vehicle side slip angle. A lateral acceleration of the vehicle is then measured. A rollover potentiality index is determined in response to the lateral kinetic energy and the lateral acceleration. A rollover index is determined by weighting the rollover potentiality index by a factor of the lateral acceleration. A comparison is made to determine if the rollover index is above a predetermined threshold.
Various objects and advantages of this invention will become apparent to those skilled in the art from the following detailed description of the preferred embodiment, when read in-light of the accompanying drawings.
The present invention provides a method for detecting a rollover event of a vehicle and providing a corrective action to counteract an actual rollover based on lateral kinetic energy and lateral acceleration of the vehicle.
In one aspect of the invention, a method is provided for detecting a rollover event of a vehicle. A lateral kinetic energy of the vehicle is determined in response to vehicle longitudinal velocity and vehicle side slip angle. A lateral acceleration of the vehicle is measured. A rollover potentiality index is determined in response to the lateral kinetic energy and the lateral acceleration. A rollover index is determined by weighting the rollover potentiality index by a factor of the lateral acceleration and by a factor of tire normal forces. A comparison is made to determine if the rollover index is above a predetermined threshold.
Various objects and advantages of this invention will become apparent to those skilled in the art from the following detailed description of the preferred embodiment, when read in light of the accompanying drawings.
The method for estimating a propensity of a vehicle to rollover, according to the '968 application, includes the steps of determining a lateral kinetic energy of the vehicle in response to vehicle longitudinal velocity and vehicle side slip angle, measuring a lateral acceleration of the vehicle, and determining a rollover potentiality index in response to the lateral kinetic energy and the lateral acceleration.
The method according to the present invention adds an additional factor that allows for better estimation of the potential for a wheel lift event thereby allowing for actuation of a control adjustment to be made earlier. Utilizing sensed tire information in conjunction with determining the lateral kinetic energy of the vehicle enables a more robust control algorithm to be designed. Also, using tire information provides a better response in a vehicle that is lightly damped (or has significantly worn dampers) as inertial sensors might not correctly identify wheel lift and could actuate the vehicle brakes in a manner that causes the vehicle to roll over. For example, the vehicle body of a lightly damped vehicle could be out of phase with the suspension (and thus the sensor information) thereby creating a response in the control system that can contradict actual behavior of the vehicle. Implementation of the rollover mitigation strategy according to the present invention can include a standard vehicle stability control system using vehicle roll rate and lateral acceleration, enhanced electronic steering control using additional sensor information, and enhanced roll mitigation functionality utilizing additional sensor information. It is anticipated that a calculated vehicle roll index and electronic steering control will have a more precise response when using the additional sensor information according to the present invention.
Referring now to the drawings and particularly to
After the vehicle operating parameter data is retrieved from the plurality of sensors, the controller determines a lateral kinetic energy 24 of the vehicle 10. The kinetic energy 24 and the lateral acceleration (aym) 38 are used to determine a rollover potentiality index (Φ0) 26. A rollover index (Φ) 28 is thereafter determined by weighting the rollover potentiality index (φ0) 26. If the controller 12 determines rollover index (Φ) 28 to be at a critical stage where an actual rollover may occur if the current vehicle operating parameters are maintained, then the controller 12 detects a rollover event and provides a control signal for taking a corrective action to counteract an actual rollover. The controller 12 provides a signal to a specific device or secondary controller for providing at least one control action to counteract the actual rollover. Control actions may comprise an engine torque reduction such as a change in the engine output 25 or an actuation of the brakes 27, a steering wheel angle adjustment 29, or a suspension adjustment 31. In a preferred embodiment, a tire load sensing mechanism 100 is included as one of the sensors included for determining a factor added to a rollover index (Φ) 28. The tire load sensing mechanism 100 and the implementation thereof will be described in greater detail below.
g cos(φ)
where g is a gravitational constant and φ is a roll angle of the vehicle sprung mass C.G. 12 relating to the lateral acceleration (aym) 38 and/or if present the super elevation angle of the road surface. The vehicle 10 while driving on a flat surface having a 0° roll angle would have a gravitational force 30 equal to the gravitational constant (g) since the cos 0°=1. A nominal height (h) is measured from the road to the vehicle sprung mass C.G. 12 while the half track width (d) represents the width from a tire outside edge to the vehicle sprung mass C.G 12. Nominal height (b) and half track width (d) are stored in memory as part of the vehicle specific dynamic model 22.
g cos(φ)/cos(θ)
A set of reconfigured coordinate axes are shown relating to the tilted vehicle 10. A z′-axis 26 is parallel to the net gravitational force acting on the vehicle sprung mass C.G. 12 while a y′-axis 35 of the lateral acceleration (aym) 38 is always equal to zero.
A minimum amount of potential energy required for an actual roll over is the net gravitational force times the differential in height between the nominal height in a static condition and the ultimate height of the vehicle sprung mass C.G. 32 at the verge of rollover defined by the formula:
(g cos φ/cos θ)*Δh
If (h) is defined as the nominal height of the vehicle sprung mass C.G. 12 while all wheels are in contact with the road surface (as shown in
d sin (θ)+h cos (θ),
and the ultimate height of vehicle sprung mass C.G. 12 when the vehicle 10 is at the verge of the actual roll over is defined by the formula:
√{square root over (d2+h2)}
Therefore, the height change (Δh) of the vehicle sprung mass C.G. 12 required for roll over is defined by the formula:
Δh=√{square root over (d2+h2)}−(d sin θ+h cos θ)
which leads to
Since the lateral kinetic energy of the vehicle 10 can be converted to potential energy very quickly through a rolling motion, the vehicle 10 has a potential to roll over at any time if the lateral kinetic energy is greater than or equal to the minimum amount of potential energy required for actual rollover. The lateral kinetic energy is defined by the formula:
where Vy is the vehicle's lateral velocity, therefore
which leads to
which leads to
The lateral velocity (Vy) can be calculated from longitudinal velocity (Vx) and vehicle side slip angle (β) as:
Vy=Vxβ
The longitudinal velocity (Vx) is the velocity of the vehicle 10 traveling along the road and is measured by wheel speed sensors. The vehicle side slip angle (β) is determined by the controller monitoring the yaw rate, the lateral acceleration (aym) 38, the steering wheel angle, and a specific vehicle dynamic model of the vehicle 10.
A rollover potentiality index (Φ0) 26 is determined from the difference between the vehicle lateral kinetic energy and the minimum potential energy required for rollover. The rollover potentiality index (Φ0) 26 is defined by the following formula:
In determining the rollover potentiality index (Φ0) 26 from the above inequality condition, cos φ is neglected. The objective of the rollover algorithm applied by the controller is to detect the rollover event. The rollover event is defined as a condition where corrective action is taken to counteract an actual rollover. This requires that the rollover event is identified prior to the rollover angle becoming excessive resulting in the actual rollover. In determining whether omitting the roll angle from the inequality equation results in a significant error, a roll angle φ of 25 degrees is factored into the above inequality equation where cos (25°) is equal to 0.9. The effect of neglecting cos φ on the rollover potentiality index (Φ0) 26 using φ equal to 25 degrees is less than 0.4% of the rollover potentiality index (φ0) 26. The error of 0.4% is less than the uncertainties of the vehicle parameters and the estimated vehicle side slip angle, and therefore, the roll angle φ may be neglected when determining the rollover potentiality index (Φ0) 26.
When the rollover potentiality index (Φ0) 26 is positive, the vehicle 10 has a potential to rollover. The potential to rollover increases with an increasing rollover potentiality index (Φ0) 26. However, a large rollover potentiality index (Φ0) 26 alone does not necessarily indicate that the vehicle 10 will rollover. The large kinetic energy needs to be converted to potential energy. This typically occurs when the vehicle 10 hits a high mu surface or a bump after a large side slip typically on a low mu surface. When the vehicle 10 hits a high mu surface, the lateral acceleration (aym) 38 of the vehicle 10 increases very rapidly. In the preferred embodiment, the measured lateral acceleration (aym) 38 needs to be more than 80% of statically critical lateral acceleration for roll over to occur. However, in other preferred embodiments, the measured lateral acceleration (aym) 38 may be any variable less than 100% of the statically critical lateral acceleration for roll over to occur for a respective vehicle. A statically critical lateral acceleration is defined as an acceleration required to make the vehicle 10 rollover on a flat surface which is represented by the formula:
(d/h)*g
In determining a rollover index (Φ) 28 from the measured lateral acceleration (aym) 38 and the statically critical lateral acceleration, the rollover index (Φ) 28 is defined by the following formula:
The rollover index (Φ) 28 is the rollover potentiality index (Φ0) 26 weighted by the measured acceleration less the statically critical lateral acceleration. When the absolute value of the measured lateral acceleration (aym) 38 is less then 80% of the critical acceleration, the index is zero and the potential for an actual rollover is not present. When the rollover index (Φ) 28 yields a positive number, the rollover index (Φ) 28 will be compared against a predetermined threshold. If the rollover index (Φ) 28 is above the predetermined threshold, then the controller 12 will provide a signal to take a control action to counteract the vehicle 10 from rolling over.
In the '968 application, there are illustrated several graphs depicting tire normal forces, a calculated rollover index, and vehicle states during a slowly increasing steering wheel angle maneuver (See
In the preferred embodiment, tire force sensor information is factored into the rollover index (Φ) 28 equation. There is illustrated in
The use of tire load being added to the rollover index (Φ) 28 described above is to increase the performance and response of the rollover mitigation strategy in several areas. Particularly, there can be an increased detection of shifts to the vehicle center of gravity that can be due to loading variations in the vehicle. Additionally, an efficiency can be achieved by utilizing a similar control program for various vehicle types, since the tire load factor will automatically tailor the vehicle response to the particular loading characteristics of the vehicles in which the tire load sensing mechanism 100 is installed. A tire load sensing mechanism 100 also provides the advantages of constantly monitoring, measuring, and adjusting to road surface conditions. Similarly, the tire load sensing mechanism 100 can adjust the overall system response due to the tire size and tire type that is installed on the vehicle. Another advantage gained by using a tire load sensing mechanism 100 to determine the rollover index (Φ) 28 is that each tire 102 would be affected by actuation and brake load variation during operation of the vehicle. Thus, a rollover index (Φ) 28 that includes tire load sensing can adjust for those continuously changing factors on each of the tires while detecting a rollover event.
As implemented, the tire load sensing mechanism 100 preferably determines the measured tire normal load. It can be appreciated that the tire load could also be implicitly estimated from a tire based measurement. A function of the sensed tire load is added to the rollover index (Φ) 28. The additional factor of the sensed tire load provides a further control lead for identifying a wheel lift condition. That is, the tire load factor information allows the controller to determine more quickly, and more in advance of, a wheel lift condition. The force implementation function is adapted so that the measured force values are processed so that the overall rollover index (Φ) 28 causes a control action with a larger command and greater phase lead. This allows the control actuation to occur at a more precise time.
In
The applied brake pressure on a left front tire and a right front tire of the vehicle 10 are also represented in
There is illustrated in
The principle and mode of operation of this invention has been explained and illustrated in its preferred embodiment. However, it must be understood that this invention may be practiced otherwise than as specifically explained and illustrated without departing from its spirit or scope.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2005/010014 | 3/23/2005 | WO | 00 | 7/9/2008 |
Number | Date | Country | |
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60555480 | Mar 2004 | US |