A system for detecting improper usage of a seatbelt of a vehicle includes a vehicle seat having a seat cushion and a seat back. A shoulder belt and a lap belt are intended to restrain an occupant sitting on the vehicle seat. The system includes a sensor module associated with the shoulder belt and the lap belt. The sensor module generates signals indicative of at least one parameter associated with the vehicle seat, the shoulder belt, and the lap belt when the occupant is sitting on the vehicle seat. The system also includes a controller that receives the signals indicative of the at least one parameter associated with the seat back, the shoulder belt, and the lap belt. The controller analyzes the received one or more signals, and determines whether the seatbelt is being used improperly by the occupant, based on the analysis.

A passenger detection apparatus may include: an SBR (Seat Belt Reminder) sensor unit having a plurality of SBR sensors installed in respective seats of a vehicle, and connected in parallel to one another; and a control unit configured to detect a combined resistance value of the SBR sensor unit, compare the detected combined resistance value to resistance values of a combined resistance table which is preset and stored in an internal memory, and determine that a passenger corresponding to each boarding zone of the combined resistance table is on board, when the detected combined resistance value is not included in a grey zone.

A seatbelt system for automatically detecting damage to a seatbelt webbing includes a strip of seatbelt webbing, a sensor, and processing circuitry. The strip of seatbelt webbing includes an embedded conductive material that extends through the strip of seatbelt webbing. The sensor is connected to the seatbelt webbing and is configured to measure electrical flow through the embedded conductive material. The processing circuitry is configured to receive the measurement of electrical flow from the sensor and to generate an alert based on the measurement.

Aspects of the disclosure relate to reducing the likelihood of injury to a passenger in a collision. In one example, a system for reducing the likelihood of a passenger submarining, may include a restraining device for restraining the passenger. A second restraining device for further restraining the passenger may also be included in the system. A locking mechanism may be configured to prevent a seat back from reclining when the second restraining device is not activated.

The invention relates to an exhaust gas aftertreatment system for a spark ignition internal combustion engine based on the Otto principle. The internal combustion engine is connected on the outlet side to an exhaust gas system, wherein an electrically heatable three-way catalytic converter, a four-way catalytic converter downstream from the electrically heatable three-way catalytic converter, and a further three-way catalytic converter downstream from the four-way catalytic converter are situated in the exhaust gas system in the flow direction of an exhaust gas through the exhaust gas system. Before the internal combustion engine is started, the electrically heatable three-way catalytic converter and preferably also the four-way catalytic converter are heated to allow efficient exhaust gas aftertreatment of the untreated emissions of the internal combustion engine upon starting the internal combustion engine. The exhaust gas aftertreatment system is also configured to allow efficient conversion of the pollutants also during a regeneration of the four-way catalytic converter, and thus, to ensure particularly low emissions in all operating states of the motor vehicle.

The present specification relates to a method for controlling vehicle interior devices. More specifically, the method comprises the steps of: acquiring image data of a vehicle passenger located within a predetermined distance from a vehicle through an object detection device provided in the exterior of the vehicle; extracting body structure information about the body structure of the vehicle passenger from the image data by using a skeletonization-related deep learning algorithm; and when opening of a specific door of the vehicle is detected, controlling passenger seat-related interior devices corresponding to the specific door on the basis of the extracted body structure information.

A vehicle includes a body holding device configured to hold the body of a seated driver; a travel control unit configured to drive the vehicle body so that it travels; and a maximum vehicle speed setting unit configured to set a set maximum vehicle speed. The travel control unit controls an output from the driving unit based on the operation amount of an accelerator device if the vehicle speed is lower than the set maximum vehicle speed, and restricts the output from the driving unit irrespective of the operation amount of the accelerator device if the vehicle speed is equal to or higher than the set maximum vehicle speed. The maximum vehicle speed setting unit sets, if it is detected that the body holding device is worn, a first vehicle speed as the set maximum vehicle speed, and sets, if it is detected that the body holding device is not worn, a second vehicle speed lower than the first vehicle speed as the set maximum vehicle speed.

A system includes: a first camera configured to capture first images of a driver on a driver's seat within a passenger cabin of the vehicle; a second camera configured to capture second images in front of the vehicle; a driver module configured to determine a driver and a present rank of the driver; a module configured to detect a condition based on at least one of (a) a first image, (b) a second image, and (c) a parameter measured by a sensor; a reinforcement module configured to: display the present rank within the passenger cabin; generate an output within the passenger cabin in response to the detection of the condition; when no conditions are detected, increment a rank period of the driver; selectively increase the present rank of the driver; and generate an alert within the passenger cabin in response to the increasing of the present rank.

A computer implemented method for detecting whether a seat belt is used in a vehicle comprises the following steps carried out by computer hardware components: acquiring an image of an interior of the vehicle; determining a plurality of sub-images based on the image; detecting, for at least one of the sub-images, whether a portion of the seat belt is present in the respective sub-image; and determining whether the seat belt is used based on the detecting.

Various implementations include a child restraint anchoring system. The system includes one or more anchors configured for coupling to a support frame of a vehicle seat. The one or more anchors are automatically movable from a retracted position to an extended position. The one or more anchors are closer to the support frame in the retracted position than in the extended position.