Abstract: A method for controlling restraint devices of a motor vehicle includes measuring a movement variable of the motor vehicle, triggering a first restraint device on the basis of a first predefined threshold value for the measured movement variable being exceeded, triggering a second restraint device on the basis of a second predefined threshold value for the measured movement variable being exceeded, and activating a first device influencing the restraining force of the first restraint device and a second device influencing the restraining force of the second restraint device on the basis of the first predefined threshold value and/or the second predefined threshold value being exceeded.

Abstract: In a method for emulating an environmental sensor in a motor vehicle in a specified collision situation at a first predetermined speed of the motor vehicle, raw data are recorded in a collision situation at a second speed, which is lower than the first speed, with the environmental sensor to be emulated using the motor vehicle and/or a structurally substantially identical motor vehicle and stored. The stored raw data and/or raw data extrapolated therefrom are used downsampled for emulating the environmental sensor at the first speed.

Abstract: A motor vehicle includes a safety device which is changeable between an idle position and an operative position, and an indicator which is rendered operational in at least one of two ways, a first way in which a first acoustic signal is triggered when the safety device departs the idle position, and a second acoustic signal, which differs from the first acoustic signal, is triggered when the safety device has assumed the operative position, a second way in which a first image is optically visualized in a display when the safety device departs the idle position, and a second image is optically visualized in the display when the safety device has assumed the operative position.

Abstract: A method for controlling restraint devices of a motor vehicle includes measuring a movement variable of the motor vehicle, triggering a first restraint device on the basis of a first predefined threshold value for the measured movement variable being exceeded, triggering a second restraint device on the basis of a second predefined threshold value for the measured movement variable being exceeded, and activating a first device influencing the restraining force of the first restraint device and a second device influencing the restraining force of the second restraint device on the basis of the first predefined threshold value and/or the second predefined threshold value being exceeded

Abstract: A motor vehicle includes a safety device which is changeable between an idle position and an operative position, and an indicator which is rendered operational in at least one of two ways, a first way in which a first acoustic signal is triggered when the safety device departs the idle position, and a second acoustic signal, which differs from the first acoustic signal, is triggered when the safety device has assumed the operative position, a second way in which a first image is optically visualized in a display when the safety device departs the idle position, and a second image is optically visualized in the display when the safety device has assumed the operative position.

Abstract: In a method for emulating an environmental sensor in a motor vehicle in a specified collision situation at a first predetermined speed of the motor vehicle, raw data are recorded in a collision situation at a second speed, which is lower than the first speed, with the environmental sensor to be emulated using the motor vehicle and/or a structurally substantially identical motor vehicle and stored. The stored raw data and/or raw data extrapolated therefrom are used downsampled for emulating the environmental sensor at the first speed.

Abstract: A motor vehicle includes a restraint system controlled by a control device, a storage device storing control information for controlling the restraint system, and a computing device. The computing device determines before a collision of the vehicle with a collision object first collision information relating to an impending collision, and determines during an actual collision of the vehicle second collision information relating to the actual collision. The motor vehicle further includes a comparison device producing a comparison result by comparing the first collision information with the second collision information. The control information stored in the storage device is selected when the comparison result indicates that the first collision information is validated in relation to the second collision information, and standard control information is selected in the absence of validation.

Abstract: Method for the triggering of a safety device in a motor vehicle in a rollover process, wherein the rotation rate signals ? generated by a rotation rate sensor are evaluated for the recognition of the rollover process of the motor vehicle about one of its axes. In that regard, predominantly roll bars, side airbags, and belt tensioners come into consideration as safety devices. The object of the invention consists in presenting a method for the triggering of a safety device, without, however, simultaneously suffering an impairment of the safe and reliable recognizing of a tip-over. According to the invention, low-pass filtered rotation rate signals are compared with an adjustable threshold value, whereby this threshold value is generated dependent on the integrated rotation rate signal. In that regard, the low-pass filtering occurs with a limit frequency, with which the signal components of the rotation rate signal characteristic for a rollover process remain unfiltered.

Abstract: The environment outside of a moving vehicle is optically monitored to acquire image information including a number of image points representing image objects or features of the outside environment. The time variation of the respective positions of the image points is analyzed to determine an inclination angle of the vehicle relative to a level horizontal plane. The optical information can be acquired by an optical camera or detector with which the vehicle has already been equipped for obstacle recognition or spacing distance control. The optically determined inclination angle is used to verify the plausibility of a rotation angle signal provided by a gyroscopic rotation rate sensor. An occupant protection device is triggered only if the two separately determined values of the inclination angle are at least approximately equal to each other and exceed a prescribed threshold.