A control system of an electric bicycle includes is provided, including: a driving motor, a database and a control module. The driving motor includes a transmission module and at least one first sensor configured to sense at least one dynamic parameter of the transmission module. The database stores a plurality of riding mode information which respectively include a plurality of simulation parameters. The control module includes a setting unit, a computing unit and a control unit. The setting unit is configured to input at least one setting parameter, and the computing unit calculates a simulated moment of inertia and a calculation result data related to the simulated moment of inertia. The computing unit outputs at least one control signal according to the calculation result data, and the control unit receives the at least one control signal and controls a driving state of the driving motor accordingly.

A control system of an electric bicycle includes is provided, including: a driving motor, a database and a control module. The driving motor includes a transmission module and at least one first sensor configured to sense at least one dynamic parameter of the transmission module. The database stores a plurality of riding mode information which respectively include a plurality of simulation parameters. The control module includes a setting unit, a computing unit and a control unit. The setting unit is configured to input at least one setting parameter, and the computing unit calculates a simulated moment of inertia and a calculation result data related to the simulated moment of inertia. The computing unit outputs at least one control signal according to the calculation result data, and the control unit receives the at least one control signal and controls a driving state of the driving motor accordingly.

A saddle sensor assembly is provided to a saddle or seatpost. The saddle sensor assembly includes a first part, a second part, a third part and a sensor. The first part is configured to receive a load from a rider, and moves due to the load applied by the rider. The second part is provided closer to a seatpost than the first part. The first part is movable relative to the second part between a first position and a second position. The third part supports the first part and the second part. The third part is attached to at least one of the saddle and the seatpost. The sensor is provided to one of the first part and the second part. The sensor is configured to detect relative movement of at least one of the first part and the second part between the first position and the second position.

Various systems and methods associated with protecting a rider of an electric bicycle from hazards while riding their bicycle are described. In some embodiments, the systems and methods enhance the safety of the rider in response current detected conditions surrounding the rider, such as conditions associated with the route or path traveled by the rider, other vehicles within the route or path traveled by the rider, potential hazards within the route or path traveled by the rider, environmental conditions through which the rider is traveling, and so on.

A bicycle image capturing device is provided that reduces annoying operations for changing an operation state. The bicycle image capturing device includes a controller. The controller includes a reception unit and an electronic control unit. The reception unit is configured to obtain information related to a component of a bicycle. The bicycle component is operable in at least a first state and a second state that differs from the first state. The electronic control unit is configured to control a first image capturing unit based on the information obtained by the reception unit.

A method for controlling an electric vehicle and the electric vehicle are provided. The method includes: under a condition in which the electric vehicle is in unlocked and motor control shielded states, first predetermined information is detected, wherein the first predetermined information is used for indicating that a rider is located on the electric vehicle; the electric vehicle is controlled to switch from the motor control shielded state to a motor control unshielded state; a predetermined control signal is received in the motor control unshielded state; and a motor of the electric vehicle is controlled to rotate according to a rotational speed corresponding to the predetermined control signal. With the disclosure, the problems of complex operation and poor user experience of a manner for controlling the electric vehicle in the related art are solved.

A connected component platform (CCP) is disclosed. The CCP receives information about at least one connected component on a vehicle and sensor derived performance information for the vehicle. The CCP develops a suspension setup recommendation for the vehicle based on the information about the at least one connected component and the sensor derived performance information. The suspension setup recommendation for the vehicle is presented on a display.

A connected component platform (CCP) is disclosed. The CCP receives information about at least one connected component on a vehicle and sensor derived performance information for the vehicle. The CCP develops a suspension setup recommendation for the vehicle based on the information about the at least one connected component and the sensor derived performance information. The suspension setup recommendation for the vehicle is presented on a display.

A vehicle operation and riding data collection device includes a housing defining an internal cavity, a power source supported by the housing in the internal cavity, a communications element supported by the housing in the internal cavity, a global positioning element supported by the housing in the internal cavity, at least one sensor supported by the housing in the internal cavity, and a processor configured to manage the power source, the communications element, the global positioning element, and the at least one sensor, to perform functional features corresponding to providing vehicle operation and riding data to, and receiving input from, a user.

A control system includes a detection device and an electronic controller. The detection device is configured to detect passenger information related to at least one passenger of a human-powered vehicle driven by a driver of the human-powered vehicle in which the at least one passenger is different from the driver. The electronic controller is configured to control at least one component of the human-powered vehicle in accordance with the passenger information.