The present invention relates to driving assist systems and methods for assisting efforts by operators to operate vehicles in traveling.
There is a need for a driving assist system, which can reliably assist effort by an operator to operate a vehicle, such as, an automobile, in traveling. Currently available automobiles are equipped with a data acquisition system and a controller including a processor. Such data acquisition system can continuously acquire data including information on vehicle state, such as current vehicle velocity, and information on environment in a field around the vehicle. The information on environment includes the presence of obstacles, including a leading vehicle ahead. Ideally, a driving assist system should avoid objection by the operator of the automobile in assisting the operator manual effort to reduce a risk of collision with an obstacle. However, if the vehicle should encounter risky environment involving the presence of an obstacle, the driving assist system should avoid collision with the obstacle. Thus, there is a need for a system, which performs assist so that the operator can continue driving comfortably without any objectionable feel due to such assist.
JP-A 10-211886, published on August 11, discloses a steering control system, which modulates power-assist for avoidance of collision upon recognition of a risk within a field around the vehicle. This steering control system computes the magnitude of risk with respect to each of obstacles within the field around the vehicle. The magnitude of risk reflects the magnitude of impact upon collision with the obstacle. The magnitude of impact depends mainly upon the relative velocity between the vehicle and the obstacle. Accounting for this fact, the known system computes an individual risk R(i) from an angular location α(i) expressed in terms of an azimuth angle of an obstacle i, a distance or separation d(i) between the subject vehicle and the obstacle i, and an odd function of the relative velocity Vref(i) between the subject vehicle and the obstacle i. This odd function involves a term of Vref(i)n (n=a real number grater than or equal to 3). The individual risk R(i) is expressed as,
where,
The individual risks are summed vertorially to produce a resultant risk R, which is expressed as,
The known steering control system is capable of avoiding collision with the obstacle by assisting the operator to operate the vehicle laterally to clear the obstacle. However, this system appears to be insufficient to avoid objectionable feel, which the operator might have. The operator may have such objectionable feel upon occurrence of a power assist, which has magnitude determined by the risk R, because a discrepancy exits between the risk R and a risk that is perceived by the operator. When the vehicle encounters an obstacle, the magnitude of risk R is proportional to the cube of the relative velocity between the vehicle and the obstacle, whereas the magnitude of risk perceived by the operator is proportional to the square of the relative velocity.
It is therefore an object of the present invention to provide a driving assist system for assisting effort by an operator to operate a vehicle in traveling, which can assist the operator without causing the operator to have any objectionable feel.
It is another object of the present invention to provide a simple and economical driving assist system for assisting effort by an operator to operate a vehicle in traveling.
The present invention provides, in one aspect thereof, a driving assist system for assisting effort by an operator to operate a vehicle in traveling, the driving assist system comprising:
The present invention provides, in second aspect thereof, a driving assist system for assisting effort by an operator to operate a vehicle in traveling, the driving assist system comprising:
The present invention provides, in third aspect thereof, a driving assist system for assisting effort by an operator to operate a vehicle in traveling, the driving assist system comprising:
The present invention will be apparent from reading of the following description in conjunction with the accompanying drawings.
Referring to
Vehicle operator 10 perceives the vehicle state through normal senses, represented by feedback line 16, and environment or situation in a field around the vehicle through normal senses, represented by line 18. The operator applies manual effort, represented by line 20, to the accelerator pedal, represented by input device 12 sending a power request command to an engine controller, not shown, of vehicle 14 through line 22. The operator applies manual effort, represented by line 24, to the brake pedal, represented by input device 12, sending a brake request command to a braking system, not shown, of vehicle 14 through line 26. The operator applies manual steering effort, represented by 28, to the steering wheel, represented by input device 12 sending a steering request command to a steering system, not shown, of vehicle 14 through line 30. Input device 12 provides reaction force to the manual effort by the operator.
The reference numeral 40 generally indicates a driving assist system for assisting effort by operator 10 to operate vehicle 14 in travelling. A data acquisition system (DAS) 42 arranged on or off the vehicle, continuously acquires data including information on the state of vehicle 14 and information on environment in a field around the vehicle. The information on the vehicle state includes velocity Vf of vehicle 14. The information on environment includes the presence of obstacles, such as, a leading vehicle in the same lane and other adjacent vehicles in the same or other lanes, in the field around vehicle 14. DAS 42 provides the presence of each obstacle in terms of angular location of the obstacle with respect to the subject vehicle 14 and relative velocity Vr between the obstacle and the subject vehicle 14. DAS 42 may provide velocity of each of the obstacles. The information on environment also includes the presence of lane markings in the field around vehicle 14. DAS 42 may provide the presence of lane markings in terms of lateral displacement of the subject vehicle 14. DAS 42 may provide weather condition in the way of the subject vehicle 14.
Driving assist system 40 receives and uses the acquired data, represented by line 44. A predicting module 46 uses the acquired data 44 to determine or predict future environment in the field around vehicle 14. Using the determined future environment as input 48, a plan making or building module 50 makes or builds an operator-response plan, which prompts vehicle operator 10 to operating vehicle 14 in a desired manner for the predicted future environment. To implement the operator-response plan, command or commands are determined. The determined command or commands are generated and provided to actuator(s) 52 through line 54. In response to the command(s), actuator(s) 52 prompts the vehicle operator 10 to operating the vehicle 14 in the desired manner.
In embodiments, the actuator(s) 52 acts on input device 12 through line 56 to modulate reaction characteristic to manual effort applied to the input device by the vehicle operator 10. In one embodiment, the future environment determined by predicting module 46 involves a risk which each of the determined obstacles would cause the vehicle operator 10 to perceive. Such risks are summed vertorially to produce a resultant risk. In this case, the planning module 50 makes an operator-response plan that prompts operator 10 to operating vehicle in a desired manner to reduce the resultant risk. In another embodiment, the future environment further involves a risk derived from the road condition. Such risk is determined by a lateral deviation of vehicle 14 from a lane and by curvature of the lane. In this embodiment, the planning module 50 makes an operator response plan that prompts operator 10 to operating vehicle in a desired manner to reduce the resultant risk superimposed by the risk derived from the road condition. In the embodiments, the operator-response plan made by planning module 50 includes the amount input to the actuator(s) 52.
Building of the operator response plan must account for type of actuator(s) 52 employed. In one embodiment where the actuator(s) 52 is capable of modulating reaction characteristic to manual steering effort by operator 10, plan making module 50 can make an operator-response plan, which prompts vehicle operator 10 to operating vehicle 14 laterally in such a manner as to reduce the resultant risk. In another embodiment where the actuator(s) 52 is capable of modulating reaction characteristic to manual effort applied to the accelerator pedal along with modulating reaction characteristic to manual steering effort, plan making module 50 can make an operator-response plan, which prompts vehicle operator 10 to operating vehicle 14 longitudinally and laterally in such a manner as to reduce the resultant risk.
While the plan-making module 50 and predicting module 46 can be implemented in hardware or software, it is most likely implemented in software. In a software implementation, the modules 46 and 50 represent software instructions stored in a memory of a computer, and executed in the processor, and the acquired data stored in memory. In hardware implementations, the modules 46 and 50 are implemented in digital logic, preferably in an integrated circuit.
Before describing implementations in detail, it is helpful to begin with consideration of parameters that define relationship between the two adjacent vehicles on the same lane.
The following description provides various implementations of the present invention.
In
Referring to
Front camera 76 is of a CCD type or a CMOS type and mounted to vehicle 70 in the vicinity of the internal rear view mirror to acquire image data of a region in front of the vehicle. The region covered by front camera 76 extends from a camera axis laterally to each side by about 30 degrees.
RRS and RLS cameras 78R and 78L are, each, of a CCD type or a CMOS type. RRS camera 78R is mounted to vehicle 70 in the vicinity of the internal rear right corner to acquire image data of rear scenery including the adjacent lane on the right-hand side. RLS camera 78R is mounted to vehicle 70 in the vicinity of the internal rear left corner to acquire image data of rear scenery including the adjacent lane on the left-hand side.
Source of vehicle speed 80 may obtain a measure of vehicle velocity by processing outputs from wheel speed sensors. The source of vehicle speed 80 may include an engine controller or a transmission controller, which can provide a signal indicative of the vehicle velocity.
Driving assist system 40A includes a microprocessor-based controller 82. Controller 82 receives the acquired data from DAS 72. From source of vehicle speed 80, controller 82 receives information on the vehicle velocity Vf. From laser radar 74, controller 82 receives information on vehicle separation D between the subject vehicle 70 and the adjacent leading vehicle. From the image data provided by front camera 76, controller 82 receives information on vehicle separation D between the subject vehicle 70 and each of vehicles in front. From the image data provided by RRS and RLS cameras 78R and 78L, controller 82 receives information on the presence of vehicles, in the adjacent lanes, approaching from the rear, and it also receives information on extent to which each vehicle is approaching. From the image data provided by front camera 76, controller 82 receives information on the presence of lane markings on a road, information on the lateral position of the vehicle relative to the lane markings, and information on the angular position of the vehicle relative to the lane markings. Using such information, controller 82 determines current environment or situation in a field around vehicle 70. Using the current and past values of environment, controller 82 predicts or determines future environment in the field around vehicle 70 for building of an operator response plan.
According to this implementation, the operator response plan includes using the current and future environments to determine the optimum path for vehicle 70 to take, establishing the optimum steering angle for vehicle 70 to track the determined optimum path, and determining the optimum steering reaction characteristic for prompting the vehicle operator to operating the steering wheel to the optimum steering angle. Controller 82 determines the amount of command in response to the determined optimum steering reaction characteristic. Controller 82 generates the command and applied it to a steering reaction modulation actuator 84.
Steering reaction modulation actuator 84 includes a controller called a steering reaction characteristic modulator 86 and a servo motor 88. Servo motor 88 is incorporated in the steering mechanism to modulate steering reaction characteristic to operator steering effort. Modulator 86 controls output torque of servo motor 88 in response to the command from controller 82 such that the steering reaction characteristic is adjusted to the reaction characteristic determined at controller 82.
The flow diagram in
At input box 102, the processor of controller 82 inputs acquired data by DAS 72. Specifically, the processor inputs vehicle velocity Vf, an angular location of a leading vehicle and a vehicle separation D between the subject vehicle 70 and the leading vehicle, and relative relation between the subject vehicle 70 and each of vehicles that are determined by RRS and RLS cameras 78R and 78L.
At box 104, using the input data at box 102, the processor determines current environment in a field around vehicle 70. Particularly, the processor builds a current hazard map visualizing the possibility of collision of the subject vehicle 70 with each of other vehicles from current and past values of the acquired data at box 102.
The possibility of collision with another vehicle lowers as the vehicle 70 separates from it. This possibility may be expressed as a function of the reciprocal of vehicle separation or the reciprocal of the square of vehicle separation. If the relative velocity between the two vehicles can be neglected, isograms in the hazard map are concentric circles with the location of the vehicle as the center. However, if the relative velocity between the two vehicles is not negligible, the isograms protrude in the direction of a vector of the relative velocity.
Accounting for the vehicle lateral position from the lane marking and the road curvature has proven to be effective for enhanced building of a hazard map. The possibility of collision grows big as the vehicle gets close to the lane marking separating the adjacent lanes or to the edge of a road. Weighting component is the least when the vehicle follows the centerline of a lane, and it gets great as the vehicle is close the lane marking or to the edge of road. With different weighting components, this collision possibility due to the lane marking and the before-mentioned collision possibility due to other vehicles are summed to provide enhanced hazard map. The weighting component applied to the collision possibility due to other vehicles is less than the weighting component applied to the collision possibility due to the lane markings.
At the moment (t=0), vehicle 122 closes a path 126 for vehicle 70 to take to the left adjacent lane. Thus, path 126 is not justified. Apparently, vehicle 124 is about to close space in the right adjacent lane, closing any path for vehicle 70 to take to the right adjacent lane. The vehicle separation between the two vehicles 70 and 120 allows vehicle 70 to stay in the middle lane. In this environment, what the vehicle operator has to do is to continue driving vehicle 70 in the middle lane.
At box 106, after it has determined the current environment, the processor predicts or determines future environments related to different future moments. The different future moments have different time values, respectively. The time values are arranged regularly with the largest time value being a predetermined time value of 5 seconds in this implementation.
At this future moment (t=T), vehicle 122 opens a path 126 for vehicle 70 to take to the left adjacent although the vehicle separation between vehicles 70 and 120 has reduced and vehicle 124 has closed space in the right adjacent lane. In this future environment, the path 126 is justified and may be set as the optimum path at the future moment (t=T).
At box 108, the processor uses the predicted future environments to determine the optimum path at each of the moments. The following provides a description on what has been taken into account in determining the optimum path at each moment. The optimum path has been determined by finding, in a hazard map for each moment, a provisional location, within an area around the location of vehicle 70, where the collision possibility is the local minimum. The processor checks on one after another of the provisional location and the adjacent other locations whether or not lateral acceleration and yaw angular rate due to a change from the current location to the one of the locations falls within an acceptable range. If the provisional location has past the test, it is used as the optimum location. If not, any one of the adjacent other locations that has past the text is used as the optimum location.
At box 110, the processor determines the optimum steering angle δ to accomplish the optimum path, and the optimum steering reaction characteristic to prompt the vehicle operator to operating the steering wheel to the optimum steering angle δ*. The optimum steering angle δ* may be determined by the steering characteristic and the optimum path.
The slope angles KSR and KSL are not fixed and determined by gradient of the collision possibility on one side in the vicinity of the optimum path and gradient on the opposite side in the vicinity thereof. Such gradients can be given from isograms on both sides of the optimum path within the predicted hazard maps (see box 106 in
At output box 112, the processor outputs command indicative of the determined reaction characteristic to steering reaction modulation actuator 84 (see
In
Driving assist system 40B includes an on board data acquisition system (DAS) 72B.
DAS 72B, mounted to the vehicle 70B, includes laser radar 74, a front camera 76, and a source of vehicle speed 80. DAS 72B is substantially the same as DAS 72 except the elimination of RRS and RLS cameras 78R and 78L.
Referring to
In
According to this implementation, the operator response plan includes using the current and future environments to determine the optimum vehicle velocity for vehicle 70B to take, establishing the optimum pedal positions of an accelerator pedal and a brake pedal for vehicle 70B to travel at the determined optimum vehicle velocity, and determining the optimum accelerator and brake reaction characteristics for prompting the vehicle operator to operating the accelerator pedal and brake pedal to the optimum pedal positions. Controller 82B determines the amount of accelerator pedal reaction command in response to the determined optimum accelerator reaction characteristic. Controller 82B also determines the amount of brake pedal reaction command in response to the determined optimum brake reaction characteristic. Controller 82B generates the accelerator reaction command and applies it to an accelerator reaction modulation actuator 140. Controller 82B generates the brake reaction command and applies it to a brake reaction modulation actuator 142.
Accelerator reaction modulation actuator 140 includes a controller called an accelerator pedal reaction characteristic modulator 144 and a servo motor 146. Brake reaction modulation actuator 142 includes a controller called a brake pedal reaction characteristic modulator 148 and a brake booster 150.
Referring also to
Referring back to
The flow diagram in
At input box 162, the processor of controller 82B inputs acquired data by DAS 72B. Using the image data from front camera 76, the processor determines the position of lane markings and the position of each of vehicles in front relative to the lane markings. Based on the relative position of each of the vehicles in front to the lane markings, the processor picks up a leading vehicle on the same lane as a target to be monitored by laser radar 74 for the subsequent control. The processor inputs an angular location of the leading vehicle, and a vehicle separation D between the subject vehicle 70B and the leading vehicle from laser radar 74. The processor receives vehicle velocity Vf from source of vehicle speed 80.
At box 164, using the acquired data received at box 162, the processor determines current environment in a field around vehicle 70B. Particularly, the processor builds a current hazard map visualizing the possibility of collision of the subject vehicle 70B with the following vehicle from current and past values of the acquired data.
The possibility of collision with the leading vehicle lowers as the vehicle 70B separates from it. This possibility may be expressed as a function of the reciprocal of vehicle separation or the reciprocal of the square of vehicle separation. If the relative velocity between the two vehicles can be neglected, isograms in the hazard map are concentric circles with the location of the vehicle as the center. However, if the relative velocity between the two vehicles is not negligible, the isograms protrude in the direction of a vector of the relative velocity.
Vehicle 70B is traveling at a vehicle velocity Vf, while vehicle 120 is traveling at a vehicle velocity Va. As Vf>Va, a vector originating at vehicle 120 indicates the relative velocity between the two vehicles 70B and 120. At the moment (t=0), there is a sufficient vehicle separation.
At box 166, after it has determined the current environment, the processor predicts or determines future environments related to different future moments. The different future moments have different time values, respectively. The time values are arranged regularly with the largest time value being a predetermined time value of 5 seconds in this implementation.
At box 168, the processor uses the predicted future environments to determine the optimum path at each of the moments. The following provides a description on what has been taken into account in determining the optimum path at each moment. The optimum path has been determined by finding, in a hazard map for each moment, a provisional location, within an area around the location of vehicle 70B, where the collision possibility is the local minimum. The processor checks on one after another of the provisional location and the adjacent other locations whether or not longitudinal acceleration due to a change from the current location to the one of the locations falls within an acceptable range. If the provisional location has past the test, it is used as the optimum location. If not, any one of the adjacent other locations that has past the text is used as the optimum location. In the second implementation, the lateral control is out of consideration. Hence, the optimum path is found in the same lane so that it may be taken by vehicle 70B by varying the vehicle velocity.
At box 170, the processor determines the optimum vehicle velocity V* to accomplish the optimum path, the optimum accelerator and brake pedal positions θA* and θB*, and accelerator and brake pedal reaction characteristics.
According to the second implementation, modulating accelerator and brake pedal reaction characteristic has accomplished the desired coordinated variations of the optimum accelerator and brake pedal positions θA* and θB*.
The slope angles KAF and KAB are not fixed and determined by gradient of the collision possibility if deviated longitudinally from the optimum position. Such gradients can be given from isograms around the optimum position within the predicted hazard maps (see box 166 in
The slope angles KBF and KBB are not fixed and determined by gradient of the collision possibility if deviated longitudinally from the optimum position. Such gradients can be given from isograms around the optimum position within the predicted hazard maps (see box 166 in
At output box 172, the processor outputs first command indicative of the determined accelerator pedal reaction characteristic and second command indicative of the determined brake pedal reaction characteristic. The first command is applied to the modulator 144 of the actuator 140. Under the control of the modulator 144, servo motor 146 operates to provide the determined accelerator pedal reaction characteristic to the manual effort applied to the accelerator pedal by the vehicle operator. The second command is applied to the modulator 148 of the actuator 142. Under the control of the modulator 148, brake booster 150 operates to provide the determined brake pedal reaction characteristic to the manual effort applied to the brake pedal by the vehicle operator.
In
Driving assist system 40C includes an on board data acquisition system (DAS) 72C. DAS 72C, mounted to the vehicle 70C, includes laser radar 74 and a source of vehicle speed 80. The laser radar 74 and source of vehicle speed 80 are mounted to vehicle 70C in the same manner as the second implementation (see
In
Controller 82C determines, by calculation for example, a first extent to which vehicle 70C has approached a leading vehicle from vehicle separation D between the two vehicles and relative velocity Vr between them. Controller 82C determines current environment in a field around vehicle 70C from the first extent. Further, controller 82c predicts how the current environment will progress in future and uses the result of such prediction to output command to a controller called an accelerator pedal reaction characteristic modulator 144 of an accelerator reaction modulation actuator 140. Modulation actuator 140 includes a servo motor 146 and a stroke sensor 178.
Referring also to
Controller 82C receives information on vehicle separation D between vehicle 70C and a leading vehicle, information on relative velocity Vr between the vehicles, and information on vehicle velocity Vf of vehicle 70C from the acquired data by DAS 72C. Using the received information, controller 82C determines, by calculation for example, the first extent (=a first risk category) to which vehicle 70C has approached the leading vehicle, and a second extent (=a second risk category) to which vehicle 70C might be influenced due to a predictable change in movement of the leading vehicle. Controller 82C uses the first and second extents to predict future environment expressed in terms of risk perceived (RP), determines an accelerator pedal reaction command ΔF based on the RP. Command AF is applied to modulator 144. Modulator 144 controls servo motor 146 in response to command ΔF, thus modulating reaction force versus stroke characteristic of accelerator pedal 152.
In
The flow diagram in
At input box 182, the processor of controller 82C inputs acquired data by DAS 72C. What are read at box 182 include velocity Vf of vehicle 70C, vehicle separation D between vehicle 70C and a leading vehicle, relative velocity Vr between the vehicles, and velocity Va of the leading vehicle.
At box 184, the processor calculates time to contact (TTC) and time headway (THW).
We introduced the notion of TTC to quantify a first extent to which the subject vehicle 70C has approached a leading vehicle in the traffic scene illustrated in
TTC is expressed as,
TTC=D/Vr Eq. 3
where,
In the traffic scene of
The presence of such discrepancy may be confirmed by considering a traffic scene where the relative velocity Vr between the leading and following vehicles is zero. In this case, TTC is infinite irrespective of how short the vehicle separation D is. Apparently, the risk perceived by the operator of the following vehicle varies with different distances of vehicle separation D. The shorter the vehicle separation D, the bigger the risk perceived by the operator is. This is because the vehicle operator accounts for the magnitude of influence on TTC due to unpredictable drop in velocity Va of the leading vehicle.
With reference to
To overcome this difficulty, according to the third implementation, we introduced the notion of time headway (THW). THW is a physical quantity quantifying a second extent to which TTC might be influenced if a change in velocity Va of a leading vehicle should occur. The second extent is introduced to represent how much a change in relative velocity Vr, if any in immediate future, might influence TTC. THW is expressed as,
THW=D/Va Eq. 4
or
THW=D/Vf Eq. 5
THW is a measure of a timer that is set to count when the leading vehicle reaches a point on a road and will be reset subsequently when the following vehicle will reach the same point. The longer THW, the smaller the second extent is. That is, when THW is long, the first extent is not greatly influenced due to a change in Va, if any, of the leading vehicle, so that a change in TTC is sufficiently small.
Using THW is to quantify the influence caused due to a future change in Va. In his respect, the use of THW determined by Va is recommendable rather than the other THW determined by Vf. Besides, the former represents the risk that is perceived by the operator with better accuracy than the latter does. However, if a value of Va that is given by a measure of Vf and a measure of Vr is less reliable than a value of Vf, the use of THW determined by Vf is recommendable. In the traffic scene where Va=Vf, the equations 4 and 5 are equally recommendable.
With continuing reference to the flow diagram in
RP=a(1/THW)+b(1/TTC) Eq. 6,
where b and a (b>a) are parameters weighting the first extent (1/TTC) and the second extent (1/THW), respectively, such that the second extent (1/THW) is less weighted than the first extent (1/TTC) is. The values of b and a are optimized after accounting for a statistics of values of THW and TTC collected in the traffic scene including leading and trailing vehicles. In this implementation, b=8 and a=1.
The equation 3 clearly reveals that time to contact TTC is a first risk category or component indicating how long it takes for a following vehicle to contact with a leading vehicle if it is assumed that the relative velocity Vr between the vehicles is constant. The equations 4 and 5 reveal that time headway THW is a second risk category or component indicating how long it takes for the following vehicle to arrive at the point, which the leading vehicle has arrived at, from the instance of arrival of the leading vehicle if it is assumed that the relative velocity Vr will be subject to a drop. Using the first and second risk categories TTC and THW, defined by current values of D, Vf, Va and Vr, in the equation 6 yields risk perceived RP, which represents a predicted future environment in the field around the vehicle. This operation is nothing but predicting a future environment in a field around the vehicle using current values of D, Vf, Va and Vr.
The RP can provide quantitative expression as to how much a following vehicle has approached a leading vehicle continuously over a range from its separating from the leading vehicle to its approaching same. The more it increases, the more strongly an operator perceives risk of excessively approaching the leading vehicle in immediate future.
The RP map in
The operating point approaching the leading vehicle moves through an upper section of the isograms of RP in a direction increasing RP, while the separating point separating the leading vehicle moves through a lower or the remaining section of the isograms RP in a direction reducing RP. The upper and lower sections are interconnected at the horizontal axis. In the upper section, lines of the isograms extend from vertically spaced generally equidistant start points on the right edge of the RP map to differently spaced intermediate points on the horizontal axis, respectively. The intermediate points are arranged such that a distance between the adjacent two points of them becomes narrower and narrower as the THW becomes shorter and shorter. The lines of the isograms curve downwardly from the start points to the intermediate points to define a range of the highest or higher values of the RP. Such range is reached at a value of the reciprocal of TTC(1/TTC), which becomes smaller as the value of THW becomes smaller. Further, with the same value of THW, the higher the reciprocal of TTC(1/TTC), the higher the RP is. Besides, with the same value of the reciprocal of TTC(1/TTC), the shorter the THW, the higher the RP is. In the lower section, lines of the isograms extend from vertically spaced generally equidistant start points on a vertical line, not illustrated, near the left edge of the RP map to the differently spaced intermediate points on the horizontal axis and a point on the right edge of the map, respectively. The lines of the isograms curve upwardly from the start points to the intermediate points to define a range of the lowest or zero value of the RP.
With continuing reference to the flow diagram of
At box 188, the processor uses the RP to determine an accelerator pedal reaction command ΔF, which is expressed as,
ΔF=K·RP Eq. 7
where,
As readily seen from the RP map in
At the next box 190, the processor outputs the command AF and applies it to the accelerator pedal reaction characteristic modulator 144 (see
The preceding description on the equation 6 and the RP map in
The second embodiment of the third implementation is substantially the same as the first embodiment thereof except the manner of producing the RP. In the first embodiment, the RP was expressed as the equation 6. In this second embodiment, RP is expressed as,
RP=max{a/THW, b/TTC} Eq. 8
where, b and a (b>a) are parameters weighting the first extent (1/TTC) and the second extent (1/THW), respectively, such that the second extent (1/THW) is less weighted than the first extent (1/TTC) is. The values of b and a are optimized after accounting for a statistics of values of THW and TTC collected in the traffic scene including leading and trailing vehicles. In this implementation, b=8 and a=1.
According to the equation, the larger one of a/THW and b/TTC is selected and used as RP.
The RP map in
Prior to a further description on the RP map in
According to the equation 8 and the RP map in
According to the third implementation, the RP is indicative of the magnitude of risk actually felt or perceived by an operator of a vehicle when, for example, involved in a traffic scene including a leading vehicle ahead. In the first embodiment, the RP is expressed by the equation 6 and illustrated in
It will be appreciated, as an advantage, that the operator normally perceives the risk when the accelerator pedal reaction force is increased to prompt the operator to operating the vehicle in such a direction as to eliminate or at least reduce the risk. Accordingly, the operator is prompted to operating the vehicle in the direction with little objection to such driving assist.
Expressing in concrete terms, upon recognition of an increase in the RP by an increase in accelerator pedal reaction force, the operator is inspired to allow the accelerator pedal 152 to move toward the released position. The increase in accelerator pedal reaction force causes the operator foot to move automatically to release the accelerator pedal 152, prompting the operator to operating the vehicle in the direction to eliminate or at least reduce the risk. Besides, the increase in accelerator pedal reaction force discourages the operator from further depressing the accelerator pedal 152 to reduce the vehicle separation.
In the first embodiment of the third implementation, the equation 6 is used to produce RP. As is readily seem from the RP map in
In the second embodiment of the third implementation, the equation 8 is used to produce RP. As illustrated in
In the embodiments according to the third implementation, time to contact TTC and time headway THW are provided by calculation of simple equations involving easily measurable or obtainable physical quantities like velocity Vf of trailing vehicle, velocity Va of leading vehicle, and vehicle separation D. This works in suppressing an increase, if any, in number of component parts of a driving assist system.
As has been described in connection with the equations 6 and 8, the parameter b is greater than the parameter a (b>a) such that the second extent (1/THW) is less weighted than the first extent (1/TTC) is. In the embodiments of the third implementation, the first extent (1/TTC) is heavily weighted than the second extent (1/THW) in producing the RP.
In
Driving assist system 40D includes a microprocessor based controller 82D. Controller 82D receives information on vehicle separation D between vehicle 70D and a leading vehicle, information on relative velocity Vr between the vehicles, and information on velocity Vf of vehicle 70D from the acquired data by laser radar 74 and source of vehicle speed 80 of DAS 72D. Controller 82D also receives information on the leading vehicle after processing the image data captured by front camera 70. The processing of the image data includes filtering and image pattern recognition. Such processing may be carried out within or outside of controller 82D. Controller 82D receives current and future information ahead of vehicle 70D from communication tool 208. Such information captured by communication tool 208 via antenna 210 will be later described.
Using the received information, controller 82D determines, by calculation for example, the first extent 1/TTC to which vehicle 70D has approached the leading vehicle. Controller 82D determines a period of time τp in response to the current value of the first extent 1/TTC, and predicts a future value of the first extent the determined period of time after as a future environment in a field around vehicle 70D.
In this implementation, a risk perceived RP by operator expresses the future environment. Based on the RP, controller 82D determines an accelerator pedal reaction commandΔF. CommandΔF is applied to an accelerator pedal reaction characteristic modulator 144. Modulator 144 controls a servo motor 146 in response to commandΔF, thus modulating reaction force versus stroke characteristic of an accelerator pedal 152.
The flow diagram in
At input box 222, the processor of controller 82D inputs acquired data by DAS 72D. What are read at box 222 include velocity Vf of the vehicle 70D, vehicle separation D between vehicle 70D and a leading vehicle, relative vehicle velocity Vr between the vehicles, and velocity Va of the leading vehicle.
At box 224, the processor calculates time to contact (TTC) that is expressed by the equation 3. As mentioned before in the third implementation, time to contact TTC is introduced to quantify a first extent to which the subject vehicle 70D has approached a leading vehicle in the traffic scene illustrated in
At box 226, the processor determines a period of time τp, which indicates how many seconds to come prior to a future environment to be predicted, in response to the time to contact TTC. The period of time τp is expressed as,
τp=f(1/TTC) Eq. 9
This function involves, as a variable, the reciprocal of TTC. The fully drawn curve in
The period of time τp corresponds to the magnitude of risk that is felt or perceived by the vehicle operator. In the case where time to contact TTC is negative or long so that the first extent (1/TTC) is small, the subject vehicle 70D separates sufficiently from the leading vehicle. The current environment in the field around vehicle 70D does not require urgent attention by the operator. In such environment, the operator can afford to predict future environment long time to come to account for all available potential risk. Thus, the period of time τp is long. In the case where time to contact TTC is short so that the first extent (1/TTC) is large, the subject vehicle 70D has approached the leading vehicle. The current environment in the field around vehicle 70D indicates the presence of risk in immediate future. In such environment, the operator will pay attention to the leading vehicle and cannot afford to predict future environment long time to come to account for all available potential risk. Thus, the period of time τp is short.
With continuing reference to the flow diagram in
The use of intervehicle communication is limited to the case where the leading vehicle has intervehicle communication tool.
At the next box 230, the processor inputs the acquired image data at front camera 76.
The image data covering the front view of vehicle 70D is subject to image and pattern recognition for the processor to determine the presence of a leading vehicle and whether its rear brake lamps are turned “on” or “off”. The information as to the state of the brake lamps is used later for predicting the magnitude of deceleration of the leading vehicle.
At box 260, the processor predicts deceleration XGa of the leading vehicle. If the leading vehicle is capable of performing intervehicle communication, the processor inputs the information on deceleration XGa of the leading vehicle out of the acquired data through the intervehicle communication. If the leading vehicle is not capable of performing the intervehicle communication, the processor predicts the deceleration XGa in the following manner.
First, the processor determines, out of the acquired image data from the front camera 76, whether or not the brake lamps of the leading vehicle is turned “on”. If this is the case, the processor measures, using a timer, for example, the elapse of time when the brake lamps are turned “on”. Using the measure of the elapse of time and the variation of velocity Va of the leading vehicle, the processor predicts the deceleration XGa. For example, if the measure of the elapse of time is less than 0.5 seconds, the processor sets a predetermined value as a virtual deceleration value of the leading vehicle. If the measure of the elapse of time is not less than 0.5 seconds, the processor determines a predicted value by calculation out of the rate of variation of past values of velocity Va of the leading vehicle.
The predicted deceleration XGa of the leading vehicle is corrected accounting for the homogeneous degree of traffic flow. The homogeneous degree of traffic flow is predicted based on the traffic congestion of the road, which may be obtained, at box 228, out of the acquired data from the communication tool 208. The logic is such that the homogeneous degree of traffic flow is high when the traffic is congested and the variation of vehicle velocity Va is small. The processor corrects the predicted deceleration XGa in response to the predicted homogeneous degree of traffic flow. For example, the processor corrects the predicted deceleration XGa such that the predicted deceleration XGa decreases as the predicted homogeneous degree of traffic flow increases. This is because a vehicle will not be accelerated or decelerated greatly when the road is congested and the homogeneous degree of traffic flow is high.
At the next block 234, the processor predicts future value of the first extent (TTC) that would occur τp after, using the current value of the first extent (TTC) obtained at box 224, the period of time τp determined at box 226, and the deceleration XGa predicted at box 232. First, the processor calculates velocity of the subject vehicle 70D, velocity of the leading vehicle, and the vehicle separation between the vehicles. The processor calculates deceleration XGf of the subject vehicle 70D based on the current velocity Vf. When it is assumed that deceleration XGf and XGa remains unaltered during the period of timeτp, future values of Vf, Va and D are expressed as,
Vf(t0+τp)=Vf(t0)+XGf×τp Eq. 10
Va(t0+τp)=Va(t0)+XGa×τp Eq. 11
D(t0+τp)=D(t0)−Vr×τp+(½)×(XGa−XGf)×τp2 Eq. 12
Using the results given by calculations of the above equations 10-12, the processor predicts the future TTC, which is expressed as,
TTC(t0+τp)=D(t0+τp)/{Vf(t0+τp)−Va(t0+τp)} Eq. 13
where, t0 is the current moment.
At box 236, the processor predicts future environment by calculating RP, which is expressed as,
RP=b/TTC(t0+τp) Eq. 14
At box 238, the processor uses the RP to determine an accelerator pedal reaction command ΔF, which is expressed by the equation 7.
At the next box 240, the processor outputs the command ΔF and applies it to the accelerator pedal reaction characteristic modulator 144 (see
According to the fourth implementation, the period of time τp is determined as a function of time to contact TTC. Time to contact TTC is determined based on Vf, Va, Vr and D. Using the information from the acquired data by front camera 76 and communication tool 208, the deceleration of a leading vehicle XGa is predicted. Using this deceleration XGa, a future value of TTC that would occur τp after is predicted. Risk perceived PR is determined as a function of the reciprocal of this future value of TTC. Finally, the RP is used to determine accelerator pedal reaction command ΔF.
According to the fourth implementation, a future value of extent to which vehicle 70D might approach a leading vehicle is predicted from a current value of the extent. This future value of the extent corresponds to the real risk perceived or felt by the operator. In this implementation, RP (risk perceived) is indicative of this future value. The RP is predicted as a quantity indicative of future environment in a field around vehicle 70D. Accounting for the predicted RP, the accelerator pedal reaction control is performed.
The period of time τp is used for prediction of a future value of RP. The period of time τp is variable with the extent to which vehicle 70D has approached the leading vehicle. The faster the vehicle approaches the leading vehicle, the more immediate future is selected for the prediction. This has provided an accelerator pedal reaction control that corresponds to the magnitude of risk actually perceived or felt by operator. Like the previously described third implementation, the operator is continuously kept informed of how fast the vehicle is approaching the leading vehicle through the magnitude of reaction force felt during manipulation of accelerator pedal.
As different from the third implementation, the deceleration XGa of the leading vehicle, which is determined on the acquired data at front camera 76 and/or communication tool 208, is used. The use of deceleration XGa has enhanced prediction of future environment in a manner more closely corresponding to the magnitude of risk actually perceived by operator.
In the fourth implementation, a current value and a future value of time to contact TTC are provided by calculation of equations involving, as variables, such physical quantities as vehicle speed and vehicle separation. This has lead to the minimal number of new components needed for installing a driving assist system in a vehicle. Using communication tool 208 to receive information on deceleration XGa for use in the predication enhances the accuracy of a future value of TTC.
In the fourth implementation, both front camera 76 and communication tool 208 are used to determine deceleration XGa. The present invention is not limited to this example. Another example is the use of front camera 76 or communication tool 208. Further example is the use of information provided by laser radar 74 or source of vehicle speed 80. A future value of TTC as determined using such deceleration XGa as predicted is satisfactorily reliable.
In the fourth implementation, laser radar 74 is used. Such laser radar may be replaced by millimeter radar or radar of other type.
The fifth implementation is substantially the same as the third implementation except the provision of producing a selected one of different alert categories to be informed of via an appropriate alarm. Thus, the same technique as in the third and fifth implementations is used in determining TTC and THW.
The flow diagram of
The control routine 250 is substantially the same as the control routine 180 illustrated in
In
Setting alert category in response to the RP as described above will keep operator informed of the magnitude of risk when vehicle has approached a leading vehicle and/or when influence due to a predicted future change in environment is great.
In this embodiment, the RP expressed by the equation 6 has been used. Alternatively, RP expressed by the equation 8 or 14 may be used. An example using the equation 14 will be explained below.
The flow diagram of
The control routine 270 is substantially the same as the control routine 220 illustrated in
In
Setting alert category in response to the RP as described above will keep operator informed of the magnitude of risk when vehicle has approached a leading vehicle and/or when influence due to a predicted future change in environment is great.
In the embodiments of the fifth implementation, the repetition rate of alarm has been varied for different alert categories. The invention is not limited to the repetition rate of alarm. Another example is to vary the volume and/or tone of alarm for different alert categories. Other example is to use various kinds of voice for different alert categories.
The sixth implementation is substantially the same as the third, fourth and fifth implementations in the use of equation 6 in determining the RP. However, according to the sixth implementation, the use of equation 6 is limited to provide a new RP, which does not keep operator from operating an automobile 70C (see
The fully drawn curve in
During the first half, paying much attention mainly to THW, the operator manipulates an accelerator pedal. During this first half, the RP expressed by the equation 6 and felt by the operator through the accelerator pedal grows in response to the reciprocal of THW, which the operator pays attention to. The risk actually perceived by the operator does not grow in response to the reciprocal of THW, however. Specifically, during the first half, the RP expressed by the equation 6 grows at the rate less than the rate at which the risk actually perceived by operator grows. In
According to the sixth implementation, a new risk perceived RP1 is used to compensate for an insufficiency provided by the RP expressed by the equation 6. To avoid confusion, the RP expressed by the equation 6 is represented by a current risk perceived RP0.
Thus, the RP0 and RP1 are expressed as,
RP0=RP=a(1/THW)+b(1/TTC) Eq. 15
where b and a (b>a) are parameters weighting the first extent (1/TTC) and the second extent (1/THW), respectively, such that the second extent (1/THW) is less weighted than the first extent (1/TTC) is. The values of b and a are optimized after accounting for a statistics of values of THW and TTC collected in the traffic scene including leading and trailing vehicles. In this implementation, b=8 and a=1.
RP1=(c−THW)+(b/TTC) Eq. 16
where b and c are parameters. In this implementation, b=8 and c=2.5.
In this implementation, the threshold of THW is 0.5 seconds (THW=0.5). When THW>0.5, the RP1 is used. When THW≦0.5, the RP0 is used. The graph in
The seventh implementation is substantially the same as the sixth implementation. In this seventh implementation, another RP2 is used. The RP2 is expressed as,
RP2=d(c−THW)+(a/THW)+(b/TTC) Eq. 17
where a, b, c and d are parameters. In this implementation, b=8, and c=2.5.
d and a are determined as follows:
Referring to
In
In
Controller 82E recognizes the state of obstacles within environment in a field around vehicle 70E by determining velocity Vf of vehicle 70E, relative position and relative velocity between vehicle 70E and each of other vehicles within the environment, and relative position between the adjacent lane marking and each of obstacles within the environment. Based on the recognized obstacle state, controller 82E determines risk which each of the recognized obstacles would cause the operator to perceive. Controller 82E divides each of the risks into a longitudinal risk component and a lateral risk component, and sums all of the longitudinal risk components to give a total longitudinal risk and all of the lateral risk components to give a total lateral risk. Based on the total longitudinal and lateral risks, controller 82E determines longitudinal commands and a lateral command.
Controller 82E outputs the longitudinal commands for application to an accelerator pedal reaction characteristic modulator 144 and a brake pedal reaction characteristic modulator 148, respectively. In response to the applied longitudinal commands, the accelerator pedal reaction characteristic modulator 144 and the brake pedal reaction characteristic modulator 148 control servo motor 146 and brake booster 150, thereby modulating the accelerator pedal and brake pedal reaction force characteristics. Modulating the accelerator pedal and brake pedal reaction characteristics prompt the vehicle operator to manipulating an accelerator pedal 152 and a brake pedal 154 to appropriate positions, respectively.
Controller 82E outputs the lateral command for application to a steering reaction characteristic modulator 86. In response to the applied lateral command, the steering reaction characteristic modulator 86 controls servo motor 88. Modulating the steering reaction characteristic prompts the vehicle operator to manipulating a steering wheel to an appropriate angular position.
The flow diagram in
At input box 312, the processor of controller 82E inputs acquired data by DAS 72. Specifically, the processor inputs vehicle velocity Vf, an angular location of a leading vehicle and a vehicle separation D between the subject vehicle 70E and the leading vehicle. The processor also inputs relative position of the vehicle 70E to the adjacent lane marking out of the image data from the front camera 76. The relative position of the vehicle 70E to the adjacent lane marking includes a lateral position and an angular position of the vehicle 70E with respect to the lane marking. Out of the image data from the front camera 76, the processor further inputs the shape of the lane marking. Out of the image data from the front camera 76, the processor still further inputs an angular location of the leading vehicle and a vehicle separation D between the vehicle 70E and the leading vehicle. Out of the image data from RRS and RLS cameras 78R and 78L, the processor inputs an angular location of each of vehicles existing in the adjacent lane(s) and a vehicle separation between the vehicle 70E and each of the vehicles. The processor also input velocity of the vehicle 70E from the source of vehicle speed 80. Besides, the processor recognizes the presence of and kinds of obstacles around the vehicle 70E out of the image data from the front camera 76 and the image data from RRS and RLS cameras 78R and 78L. Recognizing the kinds of obstacles includes pattern recognition to identify them whether they are a four wheel vehicle or a two wheel vehicle or a pedestrian.
At box 314, the processor determines current environment in the field around the vehicle 70E in terms of position of each of the obstacles/vehicles relative to the vehicle 70E, direction of movement of each of the obstacles relative to the vehicle 70E, and speed at which each of the obstacles relative to the vehicle 70E.
Specifically, the processor determines current values of position, direction and speed of each of the obstacles/vehicles from the past stored values thereof that were determined in the previous cycles and the input data at box 312.
At box 316, using the data on current environment determined at box 314, the processor calculates time to collision TTC between the vehicle 70E and each of the obstacles. TTCk indicates TTC between the vehicle 70E and an obstacle k. TTCk is expressed as,
where
The following several paragraphs provide a description on the variances σ(Dk) and σ(Vrk).
An error in data might grow should if a sensor or a camera be subject to uncertainty or unforeseeable event. Accounting for how much such an error might be, variance of separation σ(Dk) and variance of relative velocity σ(Vrk) are determined depending upon what an obstacle k is and which sensor or camera is used to recognize the obstacle k.
For example, the laser radar 74 is superior to a CCD camera, which is used as the front camera 76 and RRS and RLS cameras 78R and 78L, in its capability of providing accurate measure in separation or distance between two vehicles irrespective of how far they are separated. The curves in
The curves in
Using pattern recognition technique, image data from front camera 76 and RRS and RLS cameras 78R and 78L are analyzed by the processor to determine what an obstacle k is. A family of curves in
When the CCD camera is used to measure the separation Dk, the bigger the obstacle k, the higher the accuracy of measurement is. Accordingly, as shown in
When the CCD camera is used to measure the relative velocity Vrk, the variance σ(Vrk) is determined depending on the magnitude of relative velocity which may be assumed for the kinds of obstacle k, respectively. As shown in
In
With reference again to the flow diagram in
where,
Lane markings are distributed within a range of angular locations ahead of the vehicle 70E. Risk with regard to lane markings is determined by integrating RPk over the whole range of angular locations. Risk perceived RPlane is expressed as,
where
With continuing reference to
where,
At the next block 322, the processor sums lateral components of individual risk perceived RPk including risk with regard to lane markings RPlane to provide a total lateral risk RPLateral. The total lateral risk RPLateral is expressed as,
At box 324, the processor determines longitudinal commands by referring to the relationship shown in
The fully drawn line in
The fully drawn line in
With reference to
In
As shown in
With continuing reference to
With reference again to
The preceding description on the flow diagram in
In the eighth implementation, the controller 84E determines the magnitudes of accelerator pedal reaction command FA, brake pedal reaction command FB, and steering reaction command FS based on the total longitudinal risk RPLongitudinal and total lateral risk RPLateral. In this implementation, the magnitudes of such commands are determined using the relationships illustrated in
With reference to FIGS. 38 to 47, the eighth implementation of the present invention has been described. This implementation provides features as follows.
In this implementation, the controller 82E uses the equation 19 to determine RPk as a physical quantity quantifying the extent how quickly the vehicle 70E has approached an obstacle k. The invention is not limited to the use of equation 19 to quantify the extent how quickly the vehicle 70E has approached an obstacle k. Any appropriate physical quantity may be used in quantifying the extent how quickly the vehicle 70E has approached an obstacle k.
The ninth implementation is substantially the same as the eighth embodiment illustrated in FIGS. 38 to 47.
Turning back to
In the ninth implementation, a microprocessor-based controller 82E recognizes the state of obstacles within environment in a field around vehicle 70E by determining velocity Vf of vehicle 70E, relative position and relative velocity between vehicle 70E and each of other vehicles within the environment, and relative position between the adjacent lane marking and each of obstacles within the environment. Based on the recognized obstacle state, controller 82E determines risk which each of the recognized obstacles would cause the operator to perceive. Controller 82E predicts a change in risk RPk in response to a change in operator input. Controller 82E calculates a change in total longitudinal risk in response to a change in operator input for longitudinal operation of the vehicle 70E and a change in total lateral risk in response to a change in operator input for lateral operation of the vehicle 70E. Based on the calculated changes in total longitudinal and lateral risks, controller 82E determines longitudinal and lateral commands.
Controller 82E inputs the information on the current operator input for longitudinal operation of the vehicle by detecting positions of an accelerator pedal 152 and a brake pedal 154 (see
Controller 82 inputs the information on the current operator input for lateral operation of the vehicle by detecting manipulated angle of the steering wheel.
Controller 82E outputs the longitudinal commands for application to an accelerator pedal reaction characteristic modulator 144 and a brake pedal reaction characteristic modulator 148, respectively. In response to the applied longitudinal commands, the accelerator pedal reaction characteristic modulator 144 and the brake pedal reaction characteristic modulator 148 control servo motor 146 and brake booster 150, thereby modulating the accelerator pedal and brake pedal reaction force characteristics. Modulating the accelerator pedal and brake pedal reaction characteristics prompt the vehicle operator to manipulating the accelerator pedal 152 and the brake pedal 154 to appropriate positions, respectively.
Controller 82E outputs the lateral command for application to a steering reaction characteristic modulator 86. In response to the applied lateral command, the steering reaction characteristic modulator 86 controls servo motor 88. Modulating the steering reaction characteristic prompts the vehicle operator to manipulating the steering wheel to an appropriate angular position.
The flow diagram in
The control routine 340 is substantially the same as the control routine 310 in
In
At input box 350, the processor inputs information on current operator input through the depressed angle θAB of accelerator pedal 152 and/or brake pedal 154 and through the manipulated angle of steering wheel. When the operator manipulates the accelerator pedal 152, the processor uses the depressed angle of the accelerator pedal 152 as the depressed angle θAB. When the operator manipulates the brake pedal 154, the processor uses the depressed angle of the brake pedal 154 as the depressed angle θAB.
At the next box 352, the processor predicts a change in RPk in response to a change in operator input. Specifically, based on the current RPk determined at box 348 and the current operator input received at box 350, the processor predicts two new values of RPk when there is a unit change from the current operator input in both directions.
With reference to
For ease of description, it is hereby assumed that the accelerator/brake pedal depressed angle θAB increases when the accelerator pedal 152 or brake pedal 154 is manipulated in a direction to cause an increase in RPk. For example, it is considered that there is an increase in accelerator/brake pedalθAB when there is an increase from the current value of depressed angle of the accelerator pedal 152 or there is a decrease from the current value of depressed angle of the brake pedal 154.
With continuing reference to
The magnitudes of the variations ΔAB and ΔS are determined taking into account changes in pedal depressed angle and in steering angle per each processing time, which changes would normally occur during normal operation of the vehicle. In this implementation, the one processing time is, for example, from 0.1 to 0.2 seconds. The processing time differs depending on the kind of vehicle and on the type of processing to be completed. If the processing time ranges 0.1 to 0.2 seconds, ΔAB and ΔS are 10 mm and 0.5 degrees, respectively. The variances are not limited to such fixed values. By using learning technique, the average of depressed angles of accelerator/brake pedal and the average of manipulated steering angles over one driving cycle may be set as the variances ΔAB and ΔS for the next driving cycle.
With reference again to the flow diagram in
Using the equation 21, the processor determines the new value of total longitudinal risk RPLongitudinal(+) for θAB+ΔAB, and the other new value of total longitudinal risk RPLongitrudinal(−) for θAB−ΔAB.
At the next box 356, the processor calculates a change in RPLateral. Based on RPk determined at box 348 and its predicted new values determined at box 352, the processor determines the current total lateral risk RPLateral(0), a new value of total lateral risk RPLateral(+) for θS+ΔS, and the other new value of total lateral risk RPLateral(−) for θS−ΔS. The current total lateral risk RPLateral(0) is expressed as,
Using the equation 22, the processor determines the new value of total lateral risk RPLateral(+) for θS+ΔS, and the other new value of total lateral risk RPLateral(−) for θS−ΔS.
At box 358, the processor determines longitudinal commands including a set of accelerator pedal reaction commands FA(0), FA(−) and FA(+), and a set of brake pedal reaction commands FB(0), FB(−) and FB(+). The processor determines accelerator pedal reaction commands FA(0), FA(−) and FA(+) by referring to the relationship illustrated in
At box 360, the processor determines a set of lateral commands FS(0), FS(−) and FS(+) by referring to the illustrated relationship in
At output box 362, the processor outputs longitudinal and lateral commands determined at boxes 358 and 360. These commands include a set of accelerator pedal reaction commands FA(0), FA(−) and FA(+) for application to an accelerator pedal reaction characteristic modulator 144 (see
With reference to
In response to the commands FB(0), FB(−) and FB(+), the brake pedal reaction characteristic modulator 148 controls a brake booster 150 to modulate or alter the brake pedal reaction characteristic as shown in
In response to commands FS(0), FS(−) and FS(+), the steering reaction characteristic modulator 86 controls a servo motor 88 to modulate or alter the steering reaction characteristic as shown in
From the preceding description, it will now be understood that the eighth and ninth implementations provide the same features. However, the ninth implementation provides a feature which the eighth implementation does not. According to the ninth implementation, gradient of reaction force is created across the current position of operator input so as to prompt the operator to selecting a desired change from the current position of the operator input to reduce the risk.
The tenth implementation is substantially the same as the eighth embodiment illustrated in FIGS. 38 to 47.
Turning back to
In the tenth implementation, a microprocessor-based controller 82E recognizes the state of obstacles within environment in a field around vehicle 70E by determining velocity Vf of vehicle 70E, relative position and relative velocity between vehicle 70E and each of other vehicles within the environment, and relative position between the adjacent lane marking and each of obstacles within the environment. Based on the recognized obstacle state, controller 82E determines individual risk which each of the recognized obstacles would cause the operator to perceive. Controller 82E sums all of the individual risks to give a total risk. Controller 82E determines an angular location in which the total risk originates. In response to the determined angular position, controller 82E determines gains to be applied to a total longitudinal risk and to a total lateral risk. Based on the gains and the total longitudinal and lateral risks, controller 82E determines longitudinal and lateral commands.
Controller 82E outputs the longitudinal commands for application to an accelerator pedal reaction characteristic modulator 144 and a brake pedal reaction characteristic modulator 148, respectively. In response to the applied longitudinal commands, the accelerator pedal reaction characteristic modulator 144 and the brake pedal reaction characteristic modulator 148 control servo motor 146 and brake booster 150, thereby modulating the accelerator pedal and brake pedal reaction force characteristics. Modulating the accelerator pedal and brake pedal reaction characteristics prompt the vehicle operator to manipulating the accelerator pedal 152 and the brake pedal 154 to appropriate positions, respectively.
Controller 82E outputs the lateral command for application to a steering reaction characteristic modulator 86. In response to the applied lateral command, the steering reaction characteristic modulator 86 controls servo motor 88. Modulating the steering reaction characteristic prompts the vehicle operator to manipulating the steering wheel to an appropriate angular position.
The flow diagram in
The control routine 370 is substantially the same as the control routine 310 in
In
When the combined risk originates in an angular location ahead the vehicle, φALL=0 degree. When it originates in an angular location behind the vehicle, φALL=180 degrees. When it originates in an angular location on the right hand or left hand side of the vehicle, |φALL|=90 degrees.
At the next box 386, the processor determines gains GLongitudinal and GLateral by referring to the illustrated curves in
With continuing reference to
At box 388, the processor determines an accelerator pedal reaction command FA and a brake pedal reaction FB in the same manner as the processor did at box 324 in
At box 390, the processor determines a steering reaction command FS in the same manner as the processor did at box 326 in
At box 392, the processor outputs the commands determined at boxes 388 and 390 for application to modulators 144, 148 and 86 (see
In the tenth implementation, gains GLongitudinal and GLateral are determined for longitudinal commands and for lateral command. These gains are set in accordance with curves illustrated in
While the present invention has been particularly described, in conjunction with various implementations of the present invention, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the foregoing description. It is therefore contemplated that the appended claims will embrace any such alternatives, modifications and variations as falling within the true scope and spirit of the present invention.
This application claims the priorities of Japanese Patent Applications No. P2001-252422, filed Aug. 23, 2001, No. P2001-389314, filed Dec. 21, 2001, No. P2002-138266, filed May 14, 2002, and No. P2002-177029, Filed Jun. 18, 2002, the disclosure of each of which is hereby incorporated by reference in its entirety.
Number | Date | Country | Kind |
---|---|---|---|
2001-252422 | Aug 2001 | JP | national |
2001-389314 | Dec 2001 | JP | national |
2002-138266 | May 2002 | JP | national |
2002-177029 | Jun 2002 | JP | national |
Number | Date | Country | |
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Parent | 10226232 | Aug 2002 | US |
Child | 11099583 | Apr 2005 | US |