Abstract: An interior trim part for a bodywork component has a lighting system with a first component that generates a light signal and a second component that outputs the light signal toward the passenger compartment of the motor vehicle. The bodywork component has a moveable region (200) that can be moved with respect to a non-moveable region (300), from a stationary normal position into an open position displaced with respect to the non-moveable region (300). The first component of the light system generates, in the normal position of the moveable region (200), a light signal that is input into the second component which passes on the light signal in the manner of a lightguide.

Abstract: A head restraint actuation system is provided having a receiver configured for receiving an image signal, a transmission status signal, a head restraint request signal and a seat information signal. A mirror controller is configured for communicating with the receiver for analyzing the received signals and selecting a rearview mirror mode. A user interface is configured for communicating with the mirror controller for displaying the image signal based on the selection of a first mode, and for enabling transmission of a head restraint request to the mirror controller based on the selection of a second mode. A transmitter is configured for communicating with the mirror controller for transmitting the head restraint request to a seat controller based on the selection of the second mode. A head restraint actuator receives the head restraint request and actuates a corresponding head restraint.

Abstract: A main electrode is located in a vehicle seat. A guard electrode is located between a grounded vehicle body and the main electrode. A detection unit selectively applies an alternating voltage signal to the main electrode and the guard electrode, sets the main electrode and the guard electrode to be in an open state or a grounded state, detects an electric current of one of the main electrode and the guard electrode, converts the selected electric current into a voltage value, and detects an overcurrent in the main electrode and the guard electrode. A control unit determines the main electrode and the guard electrode to be an open failure, a power supply short failure, a grounded failure, or a short failure with the guard electrode, according to one or a combination of the voltage value and detection or non-detection of an overcurrent.

Abstract: A device and a method for activating a personal protection device are provided, in which a feature vector with at least two features is formed by an evaluation circuit from at least one signal of an accident sensor system. The evaluation circuit classifies the feature vector in the corresponding dimension using at least one class boundary. The activation circuit generates an activation signal which activates the personal protection device.

Abstract: A collision detecting device includes a chamber member providing a chamber, a pressure sensor connected to the chamber member, and a bumper absorber absorbing an impact generated by collision of an object with the vehicle. The bumper absorber has a region, which has a thickness in a front-rear direction of the vehicle. The thickness of the region is equal to or smaller than a predetermined thickness. The region is in contact with at least a portion of the chamber member. The collision is detected based on the pressure of the chamber detected by the pressure sensor. Hereby, a collision detecting device in which the bumper absorber has sufficient rigidity, and the chamber has sufficient deformability in case of collision can be obtained.

Abstract: Sensors for detecting rapid deceleration/acceleration events are disclosed herein. A sensor configured in accordance with one embodiment of the disclosure includes a magnetically operable device proximate to a magnet. The sensor also includes a biasing member operably coupled to a magnetic shield. The biasing member controls the movement of the magnetic shield between a first position that shields the magnetically operable device from the magnet, and a second position that exposes the magnetically operable device to the magnet. In a deceleration/acceleration event, the magnetic shield overcomes the biasing member and moves from the first position to the second position, thereby causing the magnetically operable device to be exposed to the magnet.

Abstract: A method for predicting potential injury assessment for at least one occupant of a vehicle involved in a crash event and for broadcasting assessment of the occupant to a medical response unit. An occupant seated in each seat of a vehicle is detected. Occupant data is obtained relating to physical characteristics of each occupant seated in the vehicle. A crash event involving the vehicle is detected. Vehicle dynamic data and safety restraint data during the crash event is recorded. The potential injury assessment of each occupant is predicted by an injury assessment processing module based on the vehicle dynamic data and safety restraint data obtained during the crash event and the occupant data of each occupant in the vehicle. The corresponding injury assessment of each occupant of the vehicle is broadcast to a medical response unit.

Abstract: A vehicle is provided which includes a closure member such as a powered window or a moon roof or sunroof that may be controlled in an auto close mode. The closure member may be controlled with anti-pinch control to provide a plurality of thresholds that are selected based on the presence of an occupant in close proximity to the vehicle, such as in the vehicle, so that an unsupervised control of the closure member provides a lower anti-pinch threshold than a supervised control of the closure member.

Abstract: A vehicle safety system includes a motion detecting device, a control module, a positioning module, and a wireless transmitting module. The motion detecting device is configured for sensing the motion of a vehicle and recording corresponding motion data. The control module is configured for analyzing the motion data and judging whether an accident has occurred to the vehicle based upon the analysis. The positioning module is configured for obtaining position coordinates of the vehicle. The wireless transmitting module is configured for automatically making contact with and reporting the position coordinates of the vehicle to a remote service station when an accident has occurred to the vehicle.

Abstract: A method of controlling a restraint device in a vehicle. The method comprises sensing an acceleration of the vehicle, analyzing the acceleration with at least two independent thresholds, and activating the restraint device when the analyzed acceleration exceeds the at least two independent thresholds.

Abstract: The invention is related to capacitive detection systems and methods. In one embodiment, a capacitive detection system comprises a first transmitter electrode and a first receiver electrode disposed in a first seat and configured to form a first capacitor, and a second transmitter electrode disposed in a second seat and configured with the first receiver electrode to form a second capacitor.

Abstract: A method and a device for activating a personal protection arrangement in the event of a rollover are provided, according to which, initially, at least one first driving dynamic variable is ascertained and then, based on this first driving dynamic variable, a second driving dynamic variable is determined, in order to activate the personal protection arrangement as a function of these two driving dynamic variables.

Abstract: The present invention can include an automobile having a multi-stage inflation system. The multi-stage inflation system can include an engine control unit, a multi-stage inflation unit, a curtain airbag, a curtain airbag pressure indicator, and/or a rollover side impact detection unit. The rollover side impact detection unit can detect when a side impact or a rollover occurs to the automobile. When the rollover or the side impact is detected, the engine control unit can instruct the multi-stage inflation unit to deploy and inflate the curtain airbag in multiple stages. The multi-stage inflation unit can include a pyrotechnic inflation unit with multiple compartments. At each of the stages, a different one of the multiple compartments can be activated to substantially inflate the curtain airbag. The multi-stage inflation unit can also optionally include a cold gas inflation unit to supplement the pyrotechnic inflation unit.

Abstract: An on-board emergency reporting apparatus includes a collision detection sensor, an airbag inflator for inflating an airbag in the event of collision detection, an airbag deflator for deflating the inflated airbag, a camera for capturing an image of an occupant seated on a seat provided with the airbag, a controller for transmitting the captured image to an emergency reporting center through a communication device, and a deflation sensor for detecting whether the volume of the inflated airbag is reduced to a predetermined threshold value. The controller causes the camera to start capturing upon detection of a reduction in the volume of the inflated airbag to the predetermined threshold value.

Abstract: An acceleration sensor arrangement comprises, in one package, an acceleration threshold detector for detecting acceleration and for providing an output signal and a processor circuit for receiving the output signal. The acceleration threshold detector provides an output signal having a first value when the acceleration is less than a predetermined threshold and is arranged to switch the output signal from the first value to a second value when the acceleration reaches the predetermined threshold. The processor circuit generates an event signal to trigger an event, such as the closing of a safing transistor switch in an airbag system, in response to the output signal from the acceleration threshold detector switching to the second value.

Abstract: A device for protection of a vehicle occupant (14) in a motor vehicle (10) comprises a means for detecting a maloperation during use of a seat belt system by the vehicle occupant (14). The detection means includes means for characterizing the vehicle occupant (14) and individually checks operation of the seat belt system by taking into account the characterization. A method for protecting a vehicle occupant (14) in a motor vehicle (10) with a seat belt system comprises the following steps: characterization of the vehicle occupant (14), and individual check of operation of the seat belt system for a maloperation by taking into account the characterization.

Abstract: A system and method are provided for deploying a safety system when a vehicle involved in a front crash may be experiencing rotational velocity. The vehicle may include a number of acceleration and rotational sensors. The vehicle may further include a controller that may be configured to determine if the vehicle is involved in a frontal crash using a combination of the acceleration and rotational sensors. The controller may also be configured to determine if the vehicle experiences rotational energy during the frontal crash using a combination of the acceleration and rotational sensors. The controller may also be configured to deploy vehicle safety systems, including at least one side safety system, if it is determined that the vehicle is involved in a frontal crash and the vehicle is experiencing rotational energy.

Abstract: A plurality of lighting units are positioned forwardly of the driver seat in the cabin of a vehicle for applying infrared radiations in respective directions to the vehicle driver seated on the driver seat. The intensities of the emitted infrared radiations are controlled according to respective basic controlled variables depending on the illuminance in the vehicle cabin. The position and orientation of the face of the vehicle driver are recognized from an image captured of the vehicle driver by an imaging device, and the basic controlled variables are corrected according to the recognized position and orientation, thereby adjusting the intensities of the infrared radiations emitted from the lighting units and a balance of the infrared radiations emitted from the lighting units. Thereafter, the illuminance in the vehicle cabin and the recognized position and orientation change, then corrective coefficients for the basic controlled variables are updated depending on the changes.

Abstract: A vehicle according to the present invention includes: a weight sensor disposed in a seat to sense the weight of a passenger sitting in the seat; a weight-keeping-exerted time measurer measuring how long the weight of the passenger sensed by the weight sensor is exerted; a vehicle speed sensor sensing the traveling speed; and a passenger identification unit setting the class of the seat by using the passenger's weight sensed by the weight sensor and the weight-keeping-exerted time measured by the weight-keeping-exerted time measurer and finally fixing the set class, when the traveling speed sensed by the vehicle speed sensor is a fixed reference speed or more.

Abstract: There are provided an abnormality reporting device that can generate vibration which can be easily perceived by a driver even when the driver is in a vibrating vehicle during running, and a control program therefore. The abnormality reporting device is equipped with a detector 2 for detecting the state of a driver 10 or the state of a vehicle 20 as a prescribed state when the vehicle 20 is moving, a judging unit 4 for judging on the basis of the detection result of the detector 2 whether it is under an abnormal state, and a vibrating unit 8 for applying vibration of a predetermined vibration pattern to the driver 10 when the abnormality state is judged, and the vibrating unit 8 can apply the vibration while varying the vibration pattern when the abnormality state is continued.

Abstract: A capacitance-based occupant detection system accurately determines seat occupancy and a failure of an electrode and between electrodes and includes an impedance calculation section, a Re/Im part calculation section, and a determination section. A first impedance Z1 is calculated including a main-body impedance Za between a main electrode and a vehicle body. The Re/Im part calculation section calculates real and imaginary parts of the first impedance Z1 based on the first impedance Z1 calculated by the impedance calculation section. The determination section determines the presence or absence of destruction of the main electrode and a guard electrode based on an imaginary part of the first impedance Z1 calculated by the Re/Im part calculation section.

Abstract: A vehicular pedestrian collision detection sensor detects a collision with a pedestrian which allows high-accuracy recognition of a collision with a pedestrian. A large number of load detection cells are arranged in a lateral direction (width direction) of the front side of a vehicle. The total collision load is calculated with respect to a cell group composed of some of the load detection cells which are adjacent to each other, wherein the cell group has a width generally equal to a pedestrian width. Based on the total collision load, an amount correlated to the mass of a pedestrian is calculated. When the amount correlated to the pedestrian mass is within a preset range, a collision with a pedestrian is recognized or determined.

Abstract: An activation system for a passenger protection device comprises a pair of communication wires, a central unit for detecting currents flowing in the communication wires, and a satellite unit for varying the currents flowing in the communication wires based on output data of an acceleration detection sensor. The central unit calculates a sum of the detected currents and compares the sum with a first predetermined level to detect the output data of the sensor. The central unit also calculates a difference between the detected currents and compares the difference with a second predetermined level, thereby detecting failure in the communication wires and stopping activation of the passenger protection device.

Abstract: A tensioner and a method of controlling tension for a three-point seat belt installed in a vehicle include an adjuster that varies tension of the three-point seat belt, a detector that signals a direction of a turn made by the vehicle, and a controller that is coupled to the adjuster and to the detector. The three-point seat belt is used to restrain both sides of an occupant's lumbar region as well as one of the occupant's right and left shoulders. The controller controls the adjuster so that the tension of the three-point seat belt when the direction of the turn is opposite to the one of the occupant's right and left shoulders that is restrained by the three-point seat belt is set lower than when the direction of the turn corresponds to the one of the occupant's right and left shoulders that is restrained by the three-point seat belt.

Abstract: A motor vehicle, such as a passenger car, having a preventive action protection system is provided, which includes safety devices which are actuated as a function of features which are based on input variables from a safety sensor system in a data evaluation and control device, wherein, when a critical driving state is detected, the data evaluation and control device actuates at least one safety device which is assigned to the driving state. The features are each assigned a specific weighting relating to the criticality of the driving state.

Abstract: An adjustment device for a motor vehicle seat that includes an electric motor, a gear connected to the electric motor, a mechanical adjustment unit connected to the gear and a control circuit, at least one sensor being associated with the control circuit for detecting a critical situation of the motor vehicle and the control circuit providing an operating voltage for the electric motor, characterized in that the control circuit provides as an alternative, in addition to the normal operating voltage, an overvoltage for supplying the electric motor, that the normal operating voltage applies in a normal driving condition of the motor vehicle in which the sensor does not deliver any signal, that the overvoltage applies at the electric motor in a driving condition after the sensor has delivered a signal indicating that the driving condition is no longer normal and that the overvoltage is at least 150% of the value of the normal operating voltage, more specifically at least 200% of the value of the normal operating

Abstract: An airbag deployment controller and a passenger protection device including the same are provided to prevent erroneous (false) operation of an airbag due to noises and quickly deploy the airbag. The passenger protection device determines whether or not to drive an airbag unit, upon determining a detected value of a front acceleration sensor as being over a first collision threshold. Then, when determining to drive the airbag unit, the passenger protection device determines whether or not a detected value of a central acceleration sensor exceeds a second collision threshold. With the detected value being over the second threshold, it generates a driving signal and outputs it to the airbag unit in a final deployment control process. Thereby, the airbag unit operates an inflator to drive an airbag.

Abstract: In a method for actuating a vehicle occupant protection system, a sensor senses driving state data, and a reversible vehicle occupant protection device can be triggered to move into an effective position, prior to an imminent collision. A setpoint braking deceleration, which triggers the vehicle occupant protection device when a threshold value is exceeded, is determined by a predictive surroundings sensing unit in advance of an imminent collision. A check is made to determine whether the setpoint braking deceleration exceeds a threshold value, by referring to a deceleration characteristic curve that is dependent on the vehicle speed.

Abstract: A first processing circuit determines a collision of a vehicle based on an output from a sensor for detecting a collision of the vehicle. A second processing circuit outputs a signal to deploy an airbag based on an output from the first processing circuit. A communication unit controls information communication between the first processing circuit and an electronic control unit outside the airbag system. A first power supply unit generates a first driving voltage for driving the first and second processing circuits based on a voltage of an outside power supply. The first power supply unit includes backup power supply unit that supplies a backup voltage when the voltage of the outside power supply falls. A second power supply unit supplies a second driving voltage to the communication unit based on an output of the first power supply unit.

Abstract: A vehicle occupant protection device comprising a headrest configured to be movable forward with respect to a vehicle, and an actuator configured to implement the forward movement is disclosed. The device is configured to protect a vehicle occupant by operating the actuator to move the headrest forward in a pre-crash stage in the course of an object crashing into the vehicle from backside of the vehicle. The headrest is provided with an electrical capacitance sensor. The device is configured to control an amount of the forward movement of the headrest according to a variation manner of electrical capacitance, which electrical capacitance is detected by the electrical capacitance sensor when the headrest moves forward.

Abstract: Vehicle including a crash sensor system arranged to determine a crash condition involving the vehicle which might cause injury to a vehicular occupant, at least one module each including an occupant protection device actuatable upon determination of a crash condition in order to protect the occupant from injury during the crash, and a vehicle bus to which the crash sensor system and module(s) are connected. The crash sensor system generates a signal upon a determination of a crash condition and directs the signal over the bus. Each module is arranged to actuate its occupant protection device in consideration of the signal. The signal might be directly sent to the module from the crash sensor system or sent to a control module which processes it and in turn generates a signal to be directed via the bus to the module(s).

Abstract: A control unit for personal protection having a polarity reversal protection between an external battery voltage and an internal voltage, to prevent an energy discharge from the control unit. The control unit also has a bidirectional DC/DC converter between an energy reserve and the internal voltage, the DC/DC converter determining its direction of conversion as a function of the internal voltage. The control unit is configured so that the control unit, after a switching-off process, records at least one measured value and generates a signal as a function of this measured value which characterizes an autarchy behavior of the control unit.

Abstract: The invention provides a method for deciding on the triggering of and controlling restraint systems of a motor vehicle, including the method steps of determining the current position of the motor vehicle; determining position-relevant environmental data of the motor vehicle; determining position-relevant reference values of the motor vehicle; determining position-relevant actual values of the motor vehicle; comparing the reference and actual values; and taking this data into account in the decision to trigger, and in the triggering of restraint systems. The invention also provides a device for this purpose.

Abstract: A method for activating additional functions in response to a rollover procedure of a vehicle, using at least one sensor and one control unit, the sensor supplying at least one unidirectional acceleration signal, having the following method steps: analyzing at least one acceleration signal in its characteristics as a function of time; processing analyzed values of the at least one acceleration signal; establishing the plausibility of the processed values using a second signal value; and activating at least one additional function in response to a rollover procedure of the vehicle in the light of the values whose plausibility has been established; as well as a control device using this method.

Abstract: Overlapping section (81) is constructed by positioning an inner side wall portion (78) of an outer impact absorbing section (63) closer to a longitudinal centerline (48) of a vehicle body than an outer side wall (33, 103) of a front side frame (11, 12; 91), so that a collision impact load can be transmitted to the outer side wall portion by way of the overlapping section. Inner impact absorbing section (62) projects forward by a greater length than an outer impact absorbing section (63). Thus, an airbag-deploying acceleration threshold value Gs is set within a range between an acceleration level when the inner impact absorbing section (62) alone is deformed by impact energy and an acceleration level when the inner and outer impact absorbing sections (62, 63) are deformed.

Abstract: A seat folding apparatus is provided with a passive Rf frequency link that requires that a person be within a certain limited distance from the vehicle to operate the seat folding mechanism. A foreign object detection system, such as a plurality of weight sensors, is provided in the seat to detect foreign objects on the seat.

Abstract: A gas generator 10 contains a baffle assembly for cooling of gases. An imperforate housing 46 is contained within the gas generator 10. A perforate housing 30 is contained within the imperforate housing 46. At least one orifice 70/72 is formed within the baffle assembly, where the orifice 70/72 is formed at the juncture 57 of the baffle assembly 12 and the perforate housing 30, at a second end of the perforate housing 30. Upon activation of the gas generator 10, gases produced are shunted through the orifice 70/72 and into the baffle assembly 12 for cooling and filtration thereof.

Abstract: A vehicle crash sensing system and method are provided for sensing a vehicle crash event. The system includes a linear acceleration sensor located on a vehicle for sensing linear acceleration along a first sensing axis and generating a linear acceleration signal. The system has linear crash sensing logic for determining a crash event along the first sensing axis as a function of the sensed linear acceleration. The system also has signal processing circuitry for processing the linear acceleration signal and generating a processed linear acceleration signal. The system has an angular rate sensor located on the vehicle for sensing an angular roll rate of the vehicle about a second sensing axis and generating a roll rate signal. The system further includes rollover crash sensing logic for determining a rollover event of the vehicle about the second sensing axis as a function of the processed linear acceleration signal and the roll rate signal.

Abstract: A capacitance type seat occupant sensor system of a vehicle includes an AC electric power source, a main electrode disposed at a seat of the vehicle to form an electric field between the main electrode and the body of the vehicle, a guard electrode disposed between a seat frame and the main electrode, a switch unit for establishing connection of the guard electrode to have the same potential as the main electrode to provide a seat occupant sensing mode, an impedance calculating unit for calculating an impedance of a sensing circuit based on the AC voltage and an amount of current flowing through the sensing circuit, a real-part-and-imaginary-part calculating unit and judging unit for discriminating an occupant on the seat based on at least the imaginary part of the first impedance.

Abstract: A method for determining a triggering decision for restraint device of a motor vehicle, in response to a preceding skidding maneuver. A yaw rate, a first driving dynamics parameter set and a context parameter set are made available. The triggering decision being determined using the yaw rate, the first vehicle parameter set and the context parameter set.

Abstract: An airbag apparatus for a small vehicle for preventing an airbag from being inflated uselessly even when a rider is moved significantly on the vehicle. A first airbag module includes impact sensors, an electronic control unit for generating an output signal when an impact force is determined to be excessive from detection signals supplied from the impact sensors, an inflator which is activated by the output signal from the electronic control unit and an airbag which is inflated by gas generated from the inflator that is mounted on a small vehicle. A second airbag module includes an inflator and a wearing type airbag which is inflated by gas generated by the inflator that is mounted on a rider. The electronic control unit and the inflator of the second airbag module are connected by couplers that can input the output signal from the electronic control unit to the second airbag module.

Abstract: A wireless system that detects the presence of a child in a safety seat located in the passenger cabin of a vehicle includes a controller responsive to signals generated by sensors monitoring predefined functions of the vehicle, RFID tag device attached to the safety seat and RFID tag reader mounted in the cabin. The system generates control signals which activate an alarm, open the doors of the vehicle and roll down windows if the child is left in the safety seat of an unattended vehicle.

Abstract: A sensor assembly includes a elongate article and a plurality of elongate piezoelectric elements provided to the elongate article. Each of the piezoelectric elements is configured so that when a load is applied in a direction perpendicular to a surface of the piezoelectric element, a short axis direction of the piezoelectric element becomes a sensitivity direction in which a voltage is generated, and a major axis direction becomes a non-sensitivity direction in which a voltage is not generated.

Abstract: An aspect of the present invention provides a passenger protection device that includes, a brake pedal sensor configured to detect the amount by which a brake pedal of a vehicle is operated, a webbing, one end of the webbing fixed to the vehicle, configured to restrain a passenger seated on a seat of the vehicle, a retractor connected to the other end of the webbing, the rector configured to retract the webbing and inhibit of the webbing extraction, and an ECU electrically coupled to the brake pedal sensor, the ECU configured to detect that the brake pedal operation amount detected by the pedal sensor exceeds a first threshold value, the ECU configured to revise the threshold value based on safety related information of the vehicle to control the inhibition of the webbing extraction of the retractor.

Abstract: An energy management system for a motor-assisted user-propelled vehicle comprising a motor capable of assisting in propelling the vehicle and a rechargeable power supply for supplying energy to the motor. The system comprises: a user input for providing a desired value for each of at least one control parameter related to the user; a sensor for each control parameter for obtaining an actual value of the control parameter; a value comparator for receiving the desired value and the actual value of each control parameter and comparing them to generate a comparison signal for each control parameter; a command generator for generating a motor command using at least one comparison signal; and a motor controller for operating the motor, using the motor command, either to assist in propelling the vehicle, or act to recharge the power supply, in a way to bring the actual value closer to the desired value.

Abstract: A device for deploying an element including a detonatable charge formed from at least one primary pyrotechnic compound; at least one initiator equipped with a reinforcing charge to initiate decomposition of the primary pyrotechnic compound(s); a secondary compound having a decomposition rate less than the decomposition rate of the primary pyrotechnic compound(s) such that the primary pyrotechnic compound(s) control(s) decomposition of the secondary compound(s) after initialization of decomposition; and at least one unconfined or weakly confined interaction chamber wherein the primary pyrotechnic compound(s) enable(s) at least one interaction of combustion products of the reducing primary compound(s) and oxidizing secondary compound(s) by oxidoreduction reaction.

Abstract: A roll angular velocity sensor and an occupant sensor are operatively coupled to a processor, which provides for detecting a rollover condition responsive to a measure of roll angular velocity and controlling a safety restraint system responsive thereto, wherein a detection criteria associated with the rollover detection process is responsive to a signal from the occupant sensor. In one embodiment, a closure time is estimated from estimates or measurements of occupant velocity or acceleration, and the estimated closure time is compared with a threshold. If the estimated closure time is less than the threshold, activation of the safety restraint system is either inhibited or advanced relative to that otherwise provided by the rollover detection process alone. Otherwise, the activation may be delayed to provide additional time for the rollover detection.

Abstract: A collision determining apparatus for a vehicle includes: a first acceleration measuring device; a second acceleration measuring device; a movement amount calculating device; a change in movement speed calculating device; a first collision determining threshold value setting device which sets a collision determining threshold value for a correlation between the amount of movement of the occupant and the change in movement speed of the occupant based on the acceleration which is measured by the first acceleration measuring device; a first collision determining device which determines whether or not the correlation exceeds the collision determining threshold value; and a control signal generating device which generates a control signal which controls operations of an occupant protection apparatus, in accordance with a result of a determination by the first collision determining device.

Abstract: An air bag device includes a retainer having an opening, a lid for covering the opening of the retainer, an air bag accommodated in the retainer, at least one hinge member connecting the retainer and the lid, and at least one guide plate having a hook-shaped or J-shaped cross section to define a recess. The hinge member is bent at its mid portion along the recess of the guide plate, and one end portion of the hinge member is fixed to a reverse surface of the lid at one side thereof and the other end portion of the hinge member is fixed to the guide plate and sandwiched between the guide plate and the retainer.

Abstract: A device for impact sensing having at least two pressure sensors is described, where pressure values are communicated from the pressure sensors to a processor, and the processor performs impact sensing on the basis of the pressure value. The processor communicates the pressure values to additional vehicle systems, which use them to fulfill their own functions, or at least to carry out a plausibility check of their own pressure values.