The present invention provides a control system and a control method capable of appropriately supporting driving of a motorcycle by a rider. The control system includes an execution unit that causes the motorcycle to execute an automatic decelerating operation in a case where an obstacle is located in a predetermined range where a collision avoiding operation of the motorcycle is required, a lane position information acquiring unit that acquires relative position information of a lane boundary with respect to the motorcycle during traveling, and a detection angle range setting unit that set a detection angle range of a forward environment detecting device to be wide in a case where a determination reference is satisfied, in which the determination reference includes a condition that the lane position information acquired by the lane position information acquiring unit satisfies a prescribed condition.

The present invention obtains a controller and a control method capable of appropriately assisting with driving of a motorcycle by a rider.

A controller that controls operation of the motorcycle, to which a surrounding environment detector is mounted, includes: an acquisition section that acquires information on the surrounding environment of the motorcycle on the basis of output of the surrounding environment detector during travel of the motorcycle; and an adaptive cruise operation performing section that makes the motorcycle perform adaptive cruise operation on the basis of the surrounding environment information acquired by the acquisition section. The acquisition section acquires other vehicle travel state information that is information on a travel state of other vehicle acquired by a different vehicle from the motorcycle via wireless communication. The controller further includes a safety operation performing section that makes the motorcycle currently performing the adaptive cruise operation perform safety operation on the basis of the other vehicle travel state information acquired by the acquisition section.

A drive assistance device (24) for a saddle type vehicle (1) includes a ride sensor (37) configured to detect a ride attitude of a rider (J), a vehicle body behavior generating part (25) configured to generate a behavior on a vehicle body by a prescribed output, and a controller (27) configured to control driving of the vehicle body behavior generating part (25), and wherein, when the vehicle body behavior generating part (25) is actuated regardless of the operation of the rider (J), the controller (27) firstly controls the vehicle body behavior generating part (25) such that a low output that is lower than a predetermined original target output is generated as a predictive action, and sets an output value after that according to a change of detection information of the ride sensor (37) generated by the low output.

A stabilization control system for a saddled vehicle including: a vehicle roll angle data unit including a predetermined roll angle of the vehicle; a comparator unit that is configured to receive inputs from the vehicle roll angle data unit and a feedback roll angle data unit and is configured to determine a difference roll angle data between the inputs from the vehicle roll angle data unit and the feedback roll angle data unit; a stabilization control unit that is configured to receive the difference roll angle data from the comparator unit and is configured to enable an actuator driver based upon the difference roll angle data received; and one or more vehicle sensors that are configured to provide inputs to the stabilization control unit.

An augmented traction system for a two-wheeled vehicle comprising a CMG (control moment gyroscope) system including a plurality of CMGs to provide a first torque vector to decrease a roll angle of a turn of the vehicle and to increase force on one or more of the tires of the vehicle on a road surface, a steering system for the vehicle, the steering system to determine a steering control for the turn of the vehicle at a particular vehicle speed and roll angle, based on sensor data, and an aerodynamic control system to actuate one or more aerodynamic elements of the vehicle, the one or more aerodynamic elements to provide a second torque vector to decrease the roll angle of the vehicle.

An anticipating module for a device for controlling, in real time, the path of a motor vehicle includes a sub-module for computing a turning command for compensating for the curvature of a bend in the lane of the vehicle and a variable-gain device that is connected to an output of the computing sub-module. The gain of the variable-gain device is connected to a controller to adjust the gain so as to decrease the lateral offset between the centre of gravity of the vehicle and the centre of the lane of the vehicle depending on the result of the comparison of components of a vector of current measurements of state variables of the device to one another and to a detection threshold, the output of the variable-gain device being the steering command for compensating for the curvature of the bend.

The present invention obtains a controller capable of improving assistance performance of a rider. The present invention also obtains a rider-assistance system including such a controller. The present invention further obtains a control method for such a rider-assistance system. In the case where travel posture information of a lean vehicle (100) is acquired and the travel posture information is information indicating that leaning of the lean vehicle (100) exceeds a reference, initiation of first rider-assistance operation for assisting with driving by a rider by using information on a first target (T1) located on a side of a travel line (DL) of the lean vehicle (100) is prohibited, and initiation of second rider-assistance operation for assisting with driving by the rider using information on a second target (T2) located on the travel line (DL) of the lean vehicle (100) is permitted.

Systems and methods for estimating lane geometry are disclosed herein. One embodiment receives sensor data from one or more sensors; detects a road agent based on the sensor data; detects, based on the sensor data, that the road agent has performed a lane shift from a first lane of a roadway to a second lane of the roadway; and estimates a boundary line between the first lane of the roadway and the second lane of the roadway based, at least in part, on the detected lane shift.

A drive assistance device for a saddle riding-type vehicle includes an outside detecting part that detects a situation around the vehicle, a brake device that brakes a host vehicle, a driving device that drives the host vehicle, and a controller that controls operation of the brake device and the driving device, and the controller performs following-travel-control that causes the host vehicle to travel with a first vehicular gap while following a preceding vehicle by actuating at least one of the brake device and the driving device, adjusts actuation of at least one of the brake device and the driving device when the outside detecting part detects a corner in a direction in which the host vehicle advances while the following-travel-control is performed, and performs control of setting a vehicular gap with respect to the preceding vehicle as a second vehicular gap that is greater than the first vehicular gap.

A terminal device and a personal mobility communicating with terminal device are disclosed. The personal mobility receives gesture information about a leader gesture recognized by a terminal when in a leader state while performing a group riding mode. Additionally, the personal mobility identifies intention information corresponding to the received gesture information and transmits the identified intention information to another personal mobility in the follower state. At least one of a illuminator or sound output are operated based on the identified intention information and the transmitted intention information from the personal mobility in the leader state is displayed through display while performing the group riding mode.