An active seat belt control apparatus is controlled according to a state of a vehicle. A control method for the active seat belt control apparatus includes: collecting, by a communication unit, state information about the vehicle; determining, by a controller, whether to activate a pulling operation of a seat belt using the collected state information; and activating the pulling operation of the seat belt using a motor.

A vehicle safety system for a vehicle includes an electronic control unit (ECU) and at least one remote crash sensor mounted in the vehicle at a location remote from the ECU and operatively connected to the ECU. The remote crash sensor is configured to sense vehicle crash conditions and to provide data related to the sensed vehicle crash conditions to the ECU. An ECU remote sensor is mounted in the vehicle at a location remote from the ECU and near a vehicle center-of-gravity (COG). The ECU remote sensor includes an inertial measurement unit (IMU), and is configured to sense vehicle roll conditions and to provide data related to the sensed vehicle roll conditions to the ECU. The ECU is operative to receive the data provided by the at least one remote crash sensor and the ECU remote sensor, perform calculations to determine whether the data is indicative of a vehicle crash condition, and to provide a signal for actuating a vehicle occupant protection device.

Methods and systems for preventing serious injury or vehicle damage resulting from collisions between automotive vehicles and people, animals, or other objects are described. In some instances, the system may comprise an object detection system configured to detect a human prior to impact with an automotive vehicle comprising the object detection system, and further configured to send a first activation signal upon detection of the human; a first actuator attached to the automotive vehicle; and a protection plate operatively connected to the first actuator and mounted on a structural component of the automotive vehicle; where upon receipt of the first activation signal by the first actuator, the protection plate is deployed from a non-vertical orientation into a vertical orientation and is vertically-positioned between a level of a front bumper of the automotive vehicle and a surface on which the automotive vehicle is traveling.

A vehicle safety system for a vehicle includes an electronic control unit (ECU) and at least one remote crash sensor mounted in the vehicle at a location remote from the ECU and operatively connected to the ECU. The remote crash sensor is configured to sense vehicle crash conditions and to provide data related to the sensed vehicle crash conditions to the ECU. An ECU remote sensor is mounted in the vehicle at a location remote from the ECU and near a vehicle center-of-gravity (COG). The ECU remote sensor includes an inertial measurement unit (IMU), and is configured to sense vehicle roll conditions and to provide data related to the sensed vehicle roll conditions to the ECU. The ECU is operative to receive the data provided by the at least one remote crash sensor and the ECU remote sensor, perform calculations to determine whether the data is indicative of a vehicle crash condition, and to provide a signal for actuating a vehicle occupant protection device.

A self-balancing enclosed motorcycle includes a platform base, a seat, a first wheel and a second wheel, a rear cabin, a door component and a gyroscope system. The gyroscope system includes a housing, a gyroscope sensor, a calculation device, an electrical coding device, a microprocessor, a servomotor, a vertical corrective rod movably extended from the servomotor, a first balancing assembly and a second balancing assembly. The first balancing assembly is mounted in the housing to engage with the vertical corrective rod. The second balancing assembly mounted in the housing at an opposite side of the first balancing assembly to engage with the vertical corrective rod. The vertical corrective rod is normally retained in a substantially vertical orientation with respect to the platform base.

A rollover mitigation device for a motor vehicle comprises a frame mounted to a roof assembly within which is disposed a transversely mounted deployable rollover protector shaft. The frame comprises a pair of lateral mounting rails mounted to the roof assembly and a tubular cross member extending between the pair of lateral mounting rails. The deployable rollover protector shaft is substantially disposed within the tubular cross member when in the stowed position and is actuated from the stowed position to a locked deployed position by a spring disposed within the tubular cross member. A controller actuates a release lock to release the deployable rollover protector shaft to the deployed position upon a sensor detecting a roll angle of the motor vehicle exceeding a predetermined value. A deployment lock restrains the deployable rollover protector shaft in the deployed position.

A rollover mitigation device for a motor vehicle comprises a frame mounted to a roof assembly within which is disposed a transversely mounted deployable rollover protector shaft. The frame comprises a pair of lateral mounting rails mounted to the roof assembly and a tubular cross member extending between the pair of lateral mounting rails. The deployable rollover protector shaft is substantially disposed within the tubular cross member when in the stowed position and is actuated from the stowed position to a locked deployed position by a spring disposed within the tubular cross member. A controller actuates a release lock to release the deployable rollover protector shaft to the deployed position upon a sensor detecting a roll angle of the motor vehicle exceeding a predetermined value. A deployment lock restrains the deployable rollover protector shaft in the deployed position.

An anti-rollover system and method for mitigating vehicle rollover. The system having a plurality of anti-rollover devices positioned around the vehicle chassis and being operable to calculate the likelihood of a vehicle rollover and determine the attitude of rollover there by actuating the anti-rollover device to counter roll thereby preventing a rollover collision.

A vehicle safety system for helping to protect a vehicle occupant in the event of a frontal collision includes a controller, one or more crash sensors for sensing a frontal collision, and an active sensor for detecting objects in the path of the vehicle. The controller is configured to implement crash discrimination metrics that detect the occurrence of a frontal collision in response to signals received from the crash sensors. The crash discrimination metrics implement thresholds for determining whether the signals received from the crash sensors indicate the occurrence of a frontal collision. The controller is configured to implement an algorithm that uses information obtained from the active sensor to detect an object in the path of the vehicle and to select the thresholds implemented in the crash discrimination metrics in response to detecting the object.

A vehicle safety rollover device utilizing a circular arc level for detecting vehicle rollover is disclosed. Upon detection, the device automatically shuts-off power to an ignition system and notifies for shut-down of the electrical system of the vehicle. The circular arc level is capable of measuring gravitational norm deviation while remaining impervious to the effects of acceleration, deceleration, impact, and centripetal forces.