A vehicle includes a first voice output section, a second voice output section, a third voice output section, and a control section which are arranged side by side in a width direction of the vehicle. The control section controls volume of the voice output from the first, second and third voice output sections. If sitting on a rider seat and a pillion passenger seat is detected, the control section controls the first, second and third voice output sections to make the volume of the voice output from the first and third voice output sections larger than the volume of the voice output from the second voice output section. The first and third voice output sections are located at both ends in the width direction of the vehicle and the second voice output section is located between the first and third voice output sections.

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 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.

Embodiments of the present disclosure relate to a immersive digital advertising system and method thereof for providing one or more local merchants the ability to expand their advertising outreach to local and nearby consumers via digitally displayed advertisements, the system having an electric pod cargo trailer and an electric tow bicycle coupled to the electric pod cargo trailer for hauling the electric pod cargo trailer along a predetermined Ad pedestrian route.

A running bike includes a front fork, a rear fork, a handlebar, and a frame extending between and connecting the front fork and the rear fork. The frame has a top tube and a seat tube coupled to the top tube. A seat is adjustably coupled to the seat tube. A footrest is connected to and supported by the frame, a drivetrain receiving region is defined as an area below the top tube and above the footplate, a drivetrain assembly is positioned within the drivetrain receiving region, and a battery mount selectively receives a battery. The battery mount faces the front wheel at a position between the top tube and the footrest. A side panel is coupled to the frame to enclose the drivetrain assembly within the drivetrain receiving region, and has in side view, a plurality of edges positioned between the top tube and the footrest.

A running bike includes a front fork, a rear fork, a handlebar, and a frame extending between and connecting the front fork and the rear fork. The frame has a top tube and a seat tube coupled to the top tube. A seat is adjustably coupled to the seat tube. A footrest is connected to and supported by the frame, a drivetrain receiving region is defined as an area below the top tube and above the footplate, a drivetrain assembly is positioned within the drivetrain receiving region, and a battery mount selectively receives a battery. The battery mount faces the front wheel at a position between the top tube and the footrest. A side panel is coupled to the frame to enclose the drivetrain assembly within the drivetrain receiving region, and has in side view, a plurality of edges positioned between the top tube and the footrest.

The present invention provides a horn or vehicle warning system that is operably accessible to the operator of a motorcycle without the need to release the grip when in use.

The present invention provides a horn or vehicle warning system that is operably accessible to the operator of a motorcycle without the need to release the grip when in use.

A component is provided for a human-powered vehicle. The component includes a component body, a strain gauge provided on the component body, a signal processing unit electrically connected to the strain gauge, a signal output that outputs a signal from the signal processing unit, and an electric power input electrically connected to the signal processing unit and supplied with electric power from a power supply provided on at least one of the human-powered vehicle and the component body. The strain gauge includes a substrate and a resistor provided on the substrate. The resistor is formed by a metal layer having a thickness of 0.01 micrometers or greater and 1 micrometer or less.

A component is provided for a human-powered vehicle. The component includes a component body, a strain gauge provided on the component body, a signal processing unit electrically connected to the strain gauge, a signal output that outputs a signal from the signal processing unit, and an electric power input electrically connected to the signal processing unit and supplied with electric power from a power supply provided on at least one of the human-powered vehicle and the component body. The strain gauge includes a substrate and a resistor provided on the substrate. The resistor is formed by a metal layer having a thickness of 0.01 micrometers or greater and 1 micrometer or less.