Abstract: A computer determines a gap distance behind a front seat. In response to detecting an impact of the vehicle, the computer selectively controls deployment of an airbag based at least in part on a gap distance behind the front seat. The computer may determine the gap distance based on seat position data, image data, weight data, triangulation data, and proximity data. The computer may be incorporated into an airbag deployment control system for deploying the airbag behind the front seat.

Abstract: A vehicle seat restraint system includes a control system and a second-row restraint system. The control system receives a first-row seat value and a second-row seat value from seat sensors. The control system generates relative position data for a first-row seat and a second-row seat based upon the first-row seat value and the second-row seat value. The control system selects a load limiter setting value using a multidimensional load limiter model based upon body impact values as a function of load limiter setting values and the relative position data, a selected load limiter setting value outside a value avoidance zone for the body impact values. The second-row restraint system is configured by the control system with the selected load limiter setting value. The control system may also determine an occupant weight value and select the load limiter setting value using the occupant weight value.

Abstract: The invention relates to a luggage compartment separator (1) that changes the luggage compartment width in the vehicles with the component parts of two telescopic roof rails (2) that are positioned parallel to one another; four roof brackets (3) that enable said roof rails (2) to be mounted to the roof of the vehicle and are arranged at a quantity of two per roof rail (2); the top mat (4) that is positioned to separate the top-seat compartment of the vehicle and hangs down from said roof rail (2); the bottom mat (5) that is positioned adjacent to said top mat (4); at least one lock mechanism 1 (6) on said top mat (4) for enabling the top mat (4) to be secured to the side surface of the vehicle; the lock mechanism 2 (7) on the bottom mat (5) for connecting the bottom mat (5) and the top mat (4) with each other in both open and closed positions and for enabling the same to remain stationary; and the fixing mechanism (8) that enables the bottom mat (5) to be secured to the vehicle floor when in open position.

Abstract: A component for a vehicle interior configured to deform under a load is disclosed. An armrest for a vehicle interior configured to deform under a load is disclosed. A method for forming the armrest is disclosed. The armrest may comprise a substrate and base formed on the substrate. The base may comprise a core and a surface (or skin). The core may comprise a material configured to deform under a load (e.g. impact). The method for forming the armrest may comprise the steps of: (a) placing the substrate in a mold and (b) forming the base on the substrate. A coating may be provided in the mold. The substrate may be formed from a plastic material such as a thermoplastic material to provide a structure. The base of the armrest may be formed from a plastic material such as a polyurethane foam material to form the core with integral surface/skin.

Abstract: A curtain airbag device that allows easy recognition and correction of twisting of an airbag during attaching. The curtain airbag device can be stored in a compact manner during transportation. The curtain airbag device including an airbag that is disposed along a roof side rail of a vehicle interior, and that can deploy so as to cover a window portion on a side face of the vehicle interior, the curtain airbag device further including a cover that covers the airbag, at least, in a part of the folded or rolled airbag in the longitudinal direction. The cover is formed of a pliable fabric material of polymer fibers, and maintains the shape of the rolled-up airbag through mutual fusion of at least a part of the polymer fibers. A high stiffness portion harder than other portions and formed during the fusion of the cover is provided in the cover extending in the longitudinal direction of the cover.

Abstract: Driver airbag cushion assemblies comprising dampening means. In some embodiments, the assembly may comprise a driver airbag module, a steering wheel armature, and an intermediate plate positioned between the driver airbag module and the steering wheel armature. The assembly may further comprise one or more horn actuators, such as horn springs coupled to the airbag module, and one or more dampening members. The one or more dampening members may be used to couple two or more of the armature, plate, and airbag module together. In some embodiments, the dampening member(s) may be functionally and/or physically decoupled from the one or more horn actuators.

Abstract: Airbag assemblies are disclosed that can reduce rotational velocity of an occupant's head during a collision event and thereby mitigate traumatic brain injury/head injury to an occupant. An airbag includes a pair of lobes or protrusions to deploy and extend from the rear face of the airbag on either side of the occupant's head to limit rotation of the head. A pair of vertical tethers within an interior of the airbag configure the lobes and contour the rear face to form one or more low fabric tension zones or bubbles. The lobes maintain high fabric tension, similar to a pressurization of a main inflatable chamber of the airbag.

Abstract: A button bridge system can include a curtain side airbag and a button bridge attached to the curtain side airbag. The button bridge can be attached to the curtain side airbag at various portions of the curtain side airbag such that a lower portion of curtain side airbag can be folded to a predetermined fold length. The lower portion of curtain side airbag and a corresponding portion of the button bridge can be stored in a storage position such that the button bridge is pulled taut when the curtain side airbag is deployed.

Abstract: An airbag assembly includes a base, an airbag supported by the base and defining an inflation chamber, an external tether, and an internal tether. The airbag includes a panel and an extension extending transverse to the panel. The panel includes an internal surface facing the inflation chamber and an external surface facing away from the inflation chamber. The external tether extends from the extension to the external surface of the panel. The internal tether extends from the base to the internal surface of the panel. During a vehicle impact, the momentum of the occupant may move the occupant towards the extension. The extension may absorb energy from the occupant and reduce or prevent the head of the occupant from sliding across the panel and/or rotating.

Abstract: A wireless communication system includes an in-vehicle device mounted on a vehicle; and a portable device that can be carried by a user. The in-vehicle device includes a first sending unit configured to intermittently and wirelessly send an identification code of the vehicle or the in-vehicle device; and a detection unit configured to detect a presence of the portable device by receiving a response signal wirelessly sent from the portable device. The portable device includes a receiving antenna configured to receive the identification code; a first verification unit configured to verify the identification code, received by the receiving antenna, with a code registered in the portable device; and a sending control unit configured to wirelessly send the response signal if the verification by the first verification unit is successful and not to send the response signal if the verification by the first verification unit is not successful.

Abstract: This electronic key system 1 includes: an electronic key which is enabled to engage in radio communication with a vehicle on condition that a vibration is detected by a vibration detection part; and the vehicle which has an on-board control part for starting an engine on condition that the radio communication with the electronic key is established, and a push switch installed in the vehicle is operated. The on-board control part causes the vehicle to be vibrated by the engine on condition that the push switch is operated.

Abstract: A windshield wiper assembly for a dual sweep angle and indexable wiper system is provided. The system includes a wiper motor and a wiper arm for sweeping a surface of a windshield coupled to a first eccentric, the first eccentric comprising a primary eccentric and an indexable eccentric plate, wherein the indexable eccentric plate determines an eccentric offset of the wiper arm coupled to the first eccentric. The system further includes an output wiper shaft coupled to the wiper arm, a second eccentric coupled to a cam shaft, and a link coupled to the first eccentric and the second eccentric, the link having a first effective link arm length between the first eccentric and the second eccentric for driving the first eccentric to operate the wiper arm when operated in a first direction.

Abstract: A vehicle window wiper system includes a wiper arm having a sliding joint operated by a linear actuator which selectively extends and retract the sliding joint. A controller is configured to cause the linear actuator to selectively extend and retract the sliding joint. A wiper arm rotational position provided to the controller determines whether the wiper arm should be in an extended or a retracted position.

Abstract: The invention relates to a connection module 10 for a wiper device 1 of an outer surface 20 of a window 2 of a motor vehicle intended to be arranged between a windscreen wiper 30 and a driving arm 60, the connection module 10 comprising a hydraulic connector 12 and an electrical connector 14, one of the hydraulic 12 and electrical 14 connectors, called first connector, comprising at least one longitudinal electrical or hydraulic routing channel 120, the other of the hydraulic 12 and electrical 14 connectors, called second connector, comprising two longitudinal electrical or hydraulic routing channels 120, the connection module 10 being characterized in that the first connector is at least partially arranged laterally between the two longitudinal routing channels of the second connector.

Abstract: The invention relates to a vehicle jack 12 integrated into a chassis of a vehicle 10 and comprises two jack assemblies 12.1, 12.2 arranged in end-to-end fashion along each side of the vehicle. Each jack assembly includes an elongate drive screw 20 and a pair of legs 9, one of which is pivotally connected to a screw follower 22. In addition, the jack 12 Includes a drive mechanism 14 comprising a bevel gear arrangement which is drivingly connected to the respective drive screws 20. Upon actuation of the drive mechanism 14, the pairs of legs 9 are simultaneously, pivotally displaced relative to the chassis between a retracted position, in which the legs 9 are substantially aligned and disposed at least partially within or around the chassis, thereby not to adversely affect the ground clearance, and an extended position.

Abstract: A brake pedal apparatus for a vehicle has a pedal member manufactured by bending one steel plate. A pedal arm is forcibly rotated forwards by the pedal member being deformed in the event of crash or rear-end collision.

Abstract: A low cost brake control system adapted to provide roll stability control on a trailer. The system comprises a brake control unit having a load, exhaust and backup valve. This control unit is adapted to control pneumatically and electrically first and second ABS relay valves, each of the ABS relay valves being assigned to a single brake channel adapted to control the braking pressure on the trailer. This enables accurate control of the brakes during a roll stability event.

Abstract: Disclosed herein are a brake fluid pressure sensor validity determination device and a determination method thereof. According to an embodiment of the present disclosure, the brake fluid pressure sensor validity determination device and the determination method thereof includes an inputter configured to receive a brake fluid pressure sensor value sensed by a brake fluid pressure sensor and receive a motor position sensor value sensed by a motor position sensor, an estimator configured to estimate a brake fluid pressure value on the basis of the motor position sensor value when the motor position sensor has not failed; and a determiner configured to determine whether the brake fluid pressure sensor has failed, determine whether the motor position sensor has failed when the brake fluid pressure sensor has not failed, and determine a validity of the brake fluid pressure sensor by comparing the estimated brake fluid pressure value with a brake fluid pressure sensor value.

Abstract: Disclosed is an electric brake system.

Abstract: Disclosed is an electric brake system.

Abstract: A brake retarder valve for a tractor-trailer combination includes a valve housing and a valve assembly. The valve assembly includes a poppet valve biased by a spring and a gravity spool. The valve assembly is selectively operable between the operative closed configuration and an open configuration in response to a resultant of the fluid pressure between a trailer axle brake and a tractor axle brake. The tractor axle brake is actuated with a time delay from actuation of the trailer axle brake. This delay is actuation of the tractor axle brake prevents jack knifing of the trailer onto the tractor in a tractor-trailer combination, thereby ensuring safety during operation of a tractor-trailer combination.

Abstract: A remote startup control device and method in consideration of an operational state of a parking brake is disclosed. The remote startup control device includes an air processing device for supplying compressed air to a parking brake chamber, a relay valve for controlling an air line connecting the air processing device to the parking brake chamber, and a control unit for determining whether to permit remote startup based on whether an input switch and an output switch of the relay valve are in an activated state.

Abstract: A vehicle rear cargo reminder system having a front door sensor, a rear door sensor, an alerting device and a controller. The front door sensor being configured to detect opening movement and closing movement of a front door. The rear door sensor configured to detect opening movement and closing movement of a rear door. The alerting device is configured to provide an alarm signal. The controller detects a sequence of events via the front door sensor and the rear door sensor. The controller determines whether or not an object might be located beside or on the rear seat of the passenger compartment, and operates the alerting device to provide the alarm signal to the vehicle operator in the absence of detection of conditions of an ignition switch of the vehicle.

Abstract: A method for controlling a state of charge (SOC) of a battery for a cruise travel of a hybrid vehicle includes predicting, by a controller, the SOC of the battery including a change slope of the SOC of the battery for the cruise travel based on a measured value of the SOC. The method includes determining, by the controller, whether the predicted SOC of the battery is equal to or greater than a maximum value of a normal range of the battery when the change slope of the SOC is greater than zero. The method includes driving, by the controller, only a driving motor of the hybrid vehicle whereby the driving motor uses electric power of the battery when the predicted SOC of the battery reaches the maximum value of the normal range of the battery. The normal range of the battery is a region required for the cruise travel of the hybrid vehicle.

Abstract: A battery management system for an electrified powertrain of a hybrid vehicle includes one or more sensors configured to measure voltage, current, and temperature for a battery system of the hybrid vehicle and a controller. The controller is configured to obtain an equivalent circuit model for the battery system, determine a set of states for the battery system to be estimated, determine a set of parameters for the battery system to be estimated, receive, from the sensor(s), the measured voltage, current, and temperature for the battery system, using the equivalent circuit model and the measured voltage, current, and temperature of the battery system, estimate the sets of states and parameters for the battery system using a mixed sigma-point Kalman filtering (SPKF) and recursive least squares (RLS) technique, and using the sets of estimated states/parameters for the battery system, control an electric motor of the electrified vehicle.

Abstract: A control method of a hybrid vehicle includes determining, by a controller, whether a target maintaining SOC has been set to a maximum level in a battery maintaining driving mode, determining, by the controller, whether a vehicle speed is equal to or higher than a predetermined speed, when the target maintaining SOC determined is a maximum level, calculating, by the controller, an estimated recovery energy which can be recovered by regenerative braking of the vehicle when a current vehicle speed is equal to or higher than the predetermined speed, and updating, by the controller, the target maintaining SOC by subtracting a subtraction SOC equivalent to the estimated recovery energy calculated from the target maintaining SOC.

Abstract: A vehicle includes an electric power storage device, an electric motor, and an electronic control unit. The electronic control unit is configured to control charging and discharging of the electric power storage device such that a state of charge becomes a target state of charge, to determine whether or not a degree of deterioration of the electric power storage device due to unevenness in salt concentration is equal to or larger than a predetermined degree, when the degree of deterioration is equal to or larger than the predetermined degree and the state of charge is equal to or less than a predetermined requested state of charge, to set the target state of charge such that the target state of charge increases monotonically, and to set an increase amount or an increase rate of the monotonic increase to be larger as the degree of deterioration is larger.

Abstract: A control apparatus of a plug-in hybrid electric vehicle that is provided with a fuel tank, an engine, a battery, and an electric motor. The battery is chargeable by an external power source. The control apparatus includes a fuel deterioration determiner and a regeneration amount limiter. The fuel deterioration determiner determines whether a fuel stored in the fuel tank is deteriorated. The regeneration amount limiter reduces, when the fuel is determined by the fuel deterioration determiner as being deteriorated, a regeneration amount to be less than the regeneration amount of a case where the fuel is determined by the fuel deterioration determiner as not being deteriorated. The regeneration amount is an amount of regeneration of electric power generated by the electric motor upon deceleration of the plug-in hybrid electric vehicle.

Abstract: A method, system, and/or computer program product mitigate sympathetic resonance in a structure that is physically proximate to a machine. One or more processors, based on readings from a sound sensor associated with a machine, detect a sound generated by a machine component of the machine. One or more processors, based on readings from a resonance sensor, detect vibration caused by sympathetic resonance in a structure that is physically proximate to the machine, where the sympathetic resonance is caused by the sound generated by the machine component. One or more processors then direct a machine component controller to adjust the machine component in order to mitigate the sympathetic resonance in the structure that is physically proximate to the machine.

Abstract: Provided is a control device for a hybrid vehicle including a controller that performs a control of the hybrid vehicle including an engine and an electric motor that serve as driving sources, a transmission, and first and second clutches. The first clutch is provided between the engine and the transmission. The second clutch is provided between the transmission and driving wheels. The controller includes first and second control units. The first control unit performs a control, in a motor traveling mode, to bring the first clutch to a disengaged state. The motor traveling mode includes traveling solely with the electric motor being driven. The second control unit performs a control, in the motor traveling mode, to bring the second clutch to a mildly engaged state in which input, from the driving-wheel side, of torque larger than driving torque causes the second clutch to slide.

Abstract: A device for controlling an engine clutch in an environmentally-friendly vehicle, wherein the engine clutch is disposed between an engine and a driving motor and is configured to selectively connect the engine to the driving motor, includes: a transmission configured to receive a driving force that is transmitted from at least one of the engine and the driving motor by release or engagement of the engine clutch; and a controller configured to control the engine clutch based on a gear of the transmission when the failure of the engine clutch is detected and configured to charge a battery using the engine.

Abstract: A method and system of detecting an impending tip over of a vehicle with the following steps and apparatus. Acquiring first measurement data, the first measurement data having strain data and at least one of attitude data and acceleration data. Acquiring second measurement data, the second measurement data having strain data and at least one of attitude data and acceleration data. Determining, based on the first measurement data and based on the second measurement data, if the second measurement data is indicative of an impending tip over of the vehicle. Only if it is determined that the second measurement data is indicative of an impending tip over of the vehicle, triggering an alarm signal, overriding a control command or overwriting a control command.

Abstract: A vehicle stability control device has: a front active stabilizer installed on a front wheel side; a rear active stabilizer installed on a rear wheel side; a turning device for turning the front and rear wheels; and a control device configured to perform load distribution control in conjunction with turning control that actuates the turning device, when a difference in braking force between left and right sides of the vehicle exceeds a threshold value during braking. A first side is one of the left and right sides with a greater braking force, and a second side is the other of the left and right sides. In the load distribution control, the control device actuates the rear active stabilizer in a direction to lift up the first side and actuates the front active stabilizer in a direction to lift up the second side.

Abstract: Disclosed are a system and a method for controlling automatic parking of a vehicle. When a difference between a target speed and a movement speed of the vehicle exists in a process of setting a parking space based on information acquired through a sensor of the vehicle and controlling automatic parking, the system and the method may determine whether there is an obstacle equal to or smaller than a predetermined height in a process of identifying and re-identifying the obstacle by controlling engine driving torque, and a location of the existing obstacle, reset an initially set parking space or a parking termination condition according to the location of the obstacle, and perform the automatic parking control, thereby detecting the obstacle even though the obstacle is equal to or smaller than the predetermined height and is not detected by a sensor, within the parking space or on a movement path to the parking space and completing the automatic parking control.

Abstract: The present disclosure provides a parking assist system including: a rear object recognizer that recognizes a rear object existing behind a vehicle through rear sensors; a reversing controller that controls the vehicle to reverse until an entry rate to the parking space becomes a first reference value or more, and ends reversing control when a distance between the vehicle and the rear object becomes less than a second reference value; a rear object position storage that stores position information of the rear object and increases a count when the reversing control is ended on the basis of the distance between the vehicle and the rear object; and a system terminator that ends parking control when the position information of the rear object before and after the count is increased is substantially the same.

Abstract: A parking assist system is configured to perform an automated parking maneuver of a motor vehicle into a transverse parking space transversely with respect to a roadway with automated longitudinal and transverse guidance along a parking trajectory. The system is configured to define an end-of-parking position for the motor vehicle corresponding to an assumed end of the parking maneuver, and to detect, while the parking maneuver is being performed, that a signal which is characteristic of a drive torque of a drive engine fulfills a first criterion, the fulfillment of which indicates impacting of one or more wheels against an obstacle. The system may also be configured to detect that a vehicle position reached when the one or more wheels impact against the obstacle fulfills, in comparison with the end-of-parking position, a second criterion, the fulfillment of which indicates that the obstacle is a delimiting ground obstacle which delimits the transverse parking space toward a rear.

Abstract: A first phantom vehicle is projected into one of a branch and a circle lane of a roundabout in association with a first autonomous vehicle. The first autonomous vehicle is caused to enter the circle lane upon predicting no collision with oncoming vehicles. The first autonomous vehicle is caused to exit from the roundabout.

Abstract: In one embodiment, in response to a request for changing lane, one or more objects surrounding an autonomous vehicle are perceived. For each of the perceived objects, a virtual spring is assigned to connect the object and the autonomous vehicle. Each virtual spring is associated with a specific spring model to generate a force based on relative positions of an associated object and the autonomous vehicle. One or more forces generated from one or more virtual springs corresponding to the one or more surrounding objects are aggregated to generate an aggregated force. One or more lane-changing parameters for the autonomous vehicle are determined based on the aggregated force and a direction of the aggregated force.

Abstract: The present disclosure provides a lane estimating apparatus and method. The apparatus includes: a lane determiner, an obstacle position calculator, a vehicle position corrector, and a lane estimator. The lane determiner compares a first lane detected by a first sensor with a lane on an actual road or a second lane on a local map to determine reliability of the first lane. The obstacle position calculator detects, when the reliability of the detected first lane is less than a preset reference, a first obstacle in the vicinity of a vehicle and a second obstacle on the local map, and calculates a difference between slopes and positions of straight lines extracted from the first obstacle and the second obstacle. The vehicle position corrector corrects a heading direction and a position of the vehicle based on the difference between the slopes and positions of the straight lines. In addition, the lane estimator estimates a driving lane on the local map.

Abstract: A lane departure preventing device includes at least one electronic control unit. The at least one electronic control unit is configured to: when there is a likelihood that a vehicle will depart from a traveling lane, calculate a prevention yaw moment, and control a brake actuator such that the prevention yaw moment is applied to the vehicle; acquire a lateral acceleration; determine whether the lateral acceleration is greater than an ideal value by a predetermined value; control the brake actuator such that the braking force matches a target braking force required to apply the prevention yaw moment to the vehicle, when the lateral acceleration is not greater than the ideal value by the predetermined value; and control the brake actuator such that the braking force is less than the target braking force, when the lateral acceleration is greater than the ideal value by the predetermined value.

Abstract: Provided is a travel control device by which it is possible to further improve fuel economy in a vehicle. A travel control device has the following: a weather information acquisition unit that acquires weather information indicating a weather state of a road on which a vehicle travels; an estimation value switching unit that sets in a modifiable manner an estimation value for travel resistance on the vehicle traveling on the road, according to the acquired weather information; a coasting travel estimation unit that estimates a change in speed of the vehicle on the road on the basis of the estimation value for the set travel resistance; and an automatic travel control unit that generates a travel schedule for the vehicle including driving travel and coasting travel on the basis of the estimated change in the vehicular speed, and causes the vehicle to travel according to the generated travel schedule.

Abstract: A speed control system includes features which allow for control of a target speed through use of an acceleration pedal and a brake pedal. The control system includes a drivetrain, a braking system, and a plurality of traction devices configured to accelerate and decelerate the vehicle based on input from the drivetrain and braking system. The control system further includes the acceleration pedal and brake pedal configured to be operated by a driver. The control system also includes a controller and one or more sensors. The controller is electronically connected to the drivetrain, the braking system, the acceleration pedal, the brake pedal, and the one or more sensors. The controller is configured to store a target speed and adjust the target speed based on input from the acceleration pedal, the brake pedal, and the one or more sensors.

Abstract: The invention relates to a control method for establishing in a motor vehicle, on the basis of environment data obtained by one or more environment sensors present on the motor vehicle, that, white an ACC system is active in one's own motor vehicle, another motor vehicle, which is moving relative to one's own motor vehicle in a neighboring lane, has a tendency to change to the lane of one's own motor vehicle. The environment sensor are designed to provide environment data representing the area laterally ahead of, laterally next to and/or laterally behind one's own vehicle.

Abstract: A travel control apparatus is provided with: a speed controller that controls speed of a vehicle having an internal combustion engine; and a determination part that determines an emission deterioration state of the internal combustion engine. The speed controller is configured to execute burn-and-coast control that repeatedly executes burn control in which the vehicle is accelerated by driving force of the internal combustion engine, and coasting control in which the vehicle is driven by inertia, by stopping the generation of the driving force or rotation of the internal combustion engine. The speed controller is configured to execute emission suppression control that suppresses emissions by adjusting the burn-and-coast control when the emission deterioration state of the internal combustion engine is determined by the determination part.

Abstract: In various example embodiments, a system and method for determining a gross combined weight of a vehicle and its load is disclosed. A method includes: providing predetermined calibration settings relating force to engine speed for a specific vehicle travelling at various speeds, altering accelerometer data based on filtered vehicle pitch and roll data, determining that one or more vehicle performance parameters fall within a threshold range, storing a plurality of data pairs that include longitudinal acceleration and drive force, and determining a slope of a line that linearly approximates the plurality of data pairs, the slope indicating a total weight, the total weight comprising a weight of the vehicle and a weight being hauled by the vehicle; and transmitting the total weight to a remote system for display.

Abstract: A control strategy for a vehicle powered by an internal combustion engine has a repeating cycle of accelerating the vehicle during a more fuel efficient acceleration phase of the cycle followed by a deceleration phase of the cycle which uses little or no fuel.

Abstract: A system for assisting a vehicle in reversing a trailer includes a vehicle steering system, a vehicle sensor outputting a vehicle velocity and a trailer sensor outputting a trailer yaw rate. The system further includes a controller controlling the vehicle steering system in reversing the trailer to cause a control parameter based on the trailer yaw rate and the vehicle velocity to converge toward a predetermined value.

Abstract: A vehicle includes a transmission mechanical park system, an electronic park brake, and at least one controller. The at least one controller is programmed to in response to (i) a speed difference of a measured speed and an expected speed of a downstream component of the vehicle that transmits torque downstream of the transmission mechanical park system exceeding a calibratable threshold and (ii) an ignition state of OFF, apply the electronic park brake to restrain movement of the vehicle.

Abstract: Route profile data for a vehicle is processed by acquiring a first set of the route profile data for a predetermined route section of a route of the vehicle depending on data provided by a sensor of the vehicle or another vehicle, where the first set of the route profile data is representative of at least a first local physical road characteristic of the predetermined route section. A second set of the route profile data, which is at least partly related to the predetermined route section, is read, where the second set of the route profile data is representative of at least a second local physical road characteristic. A degree of similarity between the first set of the route profile data and the second set of the route profile data is determined. The second set of the route profile data is assigned, based on the determined degree of similarity, to at least one of conditions immediately surrounding the vehicle and a time-dependent mapping function of influences that the route has on the vehicle.

Abstract: An integrated analysis system includes a data collector configured to acquire an image of an accelerator pedal and an image of a brake pedal for vehicle control and collect on-board diagnostic (OBD) data, distance measurement values obtained by measuring an extent to which the accelerator pedal and the brake pedal are applied, and a decibel value of an inside of a vehicle resulting from a sudden acceleration; a data integrator configured to perform an integration process by overlaying the measured data on the image collected by the data collector; a sudden acceleration determiner configured to determine the sudden acceleration of the vehicle by using image data integrated information integrated by the data integrator; and an image display configured to provide a driver with sudden acceleration determination information obtained from the sudden acceleration determiner, the image data integrated information, vehicle driving information using the OBD data, and emergency relief information.