A seat belt wearing encouragement apparatus includes a wearing state detecting unit to detect a wearing state of a seat belt; a wearing determination unit to determine whether the seat belt is worn, based on the wearing state; a vehicle speed detecting unit to detect a vehicle speed of the vehicle; a warning unit to warn the passenger; a warning command unit to issue a command to the warning unit to execute warning if the vehicle speed detecting unit has detected the vehicle speed exceeding a setting speed, and the wearing determination unit has determined that the seat belt is not being worn properly; and a vehicle speed limiting unit to limit the vehicle speed in a case where even after a predetermined time has elapsed since the warning was executed, the wearing determination unit still determines that the seat belt is not being worn properly.

A seatbelt ignition interlock system. The system includes a plurality of sensor devices each including a housing, a latch configured to removably engage the latch receiver of a vehicle seatbelt system, a latch receiver configured to receive and removably engage the latch of the vehicle seatbelt system, a latch sensor, a temperature sensor, and a power source. Each sensor device is in electrical communication with a vehicle ignition interlock circuit, and the vehicle ignition interlock circuit is in electrical communication with an ignition of a vehicle. The vehicle ignition interlock circuit is configured to prevent the vehicle ignition from being started when a combination of temperature sensors and latch sensors determine that occupied seats have unfastened seatbelts.

Devices, systems and processes for the detection of unsafe cabin conditions that provides a safer passenger experience in autonomous vehicles are described. One example method for enhancing passenger safety includes capturing at least a set of images of one or more passengers in the vehicle, determining, based on the set of images, the occurrence of an unsafe activity in an interior of the vehicle, performing, using a neural network, a classification of the unsafe activity, and performing, based on the classification, one or more responsive actions.

Embodiments described herein take the form of a fastener, such as a button, clasp, or the like, that magnetically attracts a button to an enclosure, thereby securely closing the fastener. In one example embodiment, the fastener includes a base and a ring. The ring defines an aperture and the base includes a button. The button can move perpendicularly to a surface of the base that abuts or otherwise engages the ring. The ring includes multiple magnets typically positioned within a body of the ring and, generally, at opposing positions along a circumference or perimeter of the ring. Similarly, a magnet is positioned within the button. As the ring approaches the base, the ring magnets attract the button magnet, drawing it into the ring and closing or securing the fastener. The button moves transversely to the polarization direction of the ring magnets (and button magnet) as the button extends.

A system for detecting usage of a seat belt and initiating a notification signal on detecting non-usage of the seat belt. Further, the system transmits the detected data to a plurality of computing units over a communication network. The system is integrated with the seat belt of a vehicle, wherein the seat belt comprises a female unit and male unit. The system comprises a first sensor unit, circuitry unit, second sensor unit, communication unit, and power unit. The first sensor unit and the circuitry unit are integrated with the female unit to detect an unbuckled position of the seat belt. The second sensor unit is integrated with the male unit to detect a buckled position of the seat belt on completing a circuitry when the male unit is secured into the female unit of the seat belt. The circuitry unit is electrically coupled to the first sensor unit to transmit a plurality of notification signals to computing units. The communication unit transmits the notification signals such as text messages to the computing units. The power unit energizes the first sensor unit, the second sensor unit, the circuitry unit, and the communication unit.

A computer is programmed to identify first and second regions of an image representing a seatbelt, actuate an output device to deliver a first output upon detecting an absence of the seatbelt in the first region and in the second region, and actuate the output device to deliver a second output upon detecting an absence of the seatbelt in the first region and a presence of the seatbelt in the second region.

A seatbelt assembly includes a seatbelt, a conductive sensing conductor and a conductive shield. The seatbelt has a lap band. The conductive sensing conductor is fixed to a first side of the lap band. The conductive shield is fixed to a second side of the lap band and is substantially aligned with and substantially overlaps the sensing conductor. An insulating layer is disposed between the sensing conductor and the conductive shield.

An off-road vehicle includes a control module which limits power source rotational speed beneath a controlled rotational speed value based both on whether a protection device such as a safety belt is engaged or disengaged and on whether the vehicle velocity is greater than or less than a velocity threshold. If the safety belt becomes disengaged while the power source is spinning above the controlled rotational speed value, the control module gradually and safely reduces power source rotational speed. If/when the safety belt becomes reengaged, the control module logic will ensure that the power source rotational speed is released from the controlled first value without immediate change in vehicle response. The invention effectively reduces safety hazards of safety belt disengagement while not creating safety hazards of its own in a wide range of discussed situations.

A computer is programmed to identify first and second regions of an image representing a seatbelt, actuate an output device to deliver a first output upon detecting an absence of the seatbelt in the first region and in the second region, and actuate the output device to deliver a second output upon detecting an absence of the seatbelt in the first region and a presence of the seatbelt in the second region.

A seat belt routing sensing system for a seat belt of a vehicle is provided. The seat belt includes a latch plate. The seat belt routing sensing system includes a seat belt buckle mounting assembly and a sensor. The seat belt buckle mounting assembly includes a first bracket or a first strap. The first bracket or the first strap is configured to connect to a seat belt buckle. The sensor is attached directly or indirectly to the first bracket, the first strap, or the seat belt buckle and is configured to detect changes in a parameter. The changes are indicative of (i) at least one of a bending moment, a force, an angular position, or an angular movement of the first bracket or first strap, and (ii) routing of the seat belt.