A snowmobile including a warming element at a handlebar of the snowmobile. The warming element is configured to generate heat in response to electrical current driven therethrough. A user interface is configured to receive inputs from an operator of the snowmobile. The inputs include a first temperature input setting a first predetermined temperature for the warming element. A control assembly includes a warmer control button configured for setting the warming element at the first predetermined temperature. A control module is included with the control assembly and in receipt of inputs from the user interface and the control assembly. The control module is configured to, when the first predetermined temperature is selected by way of the warmer control button, direct sufficient electrical current to the warming element to generate heat equal to the first predetermined temperature.

A method for recharging an electrical energy storage device of all or some of a plurality connected to the chain. All the vehicles connected to the chain being referred to as the stock. Each vehicle includes an electronic circuit connected to the energy storage device. An electric current flowing between the electronic circuits of at least two consecutive vehicles among the vehicles in the stock recharges the energy storage device or devices.

A method for recharging an electrical energy storage device of all or some of a plurality connected to the chain. All the vehicles connected to the chain being referred to as the stock. Each vehicle includes an electronic circuit connected to the energy storage device. An electric current flowing between the electronic circuits of at least two consecutive vehicles among the vehicles in the stock recharges the energy storage device or devices.

A saddle riding vehicle includes a front fork including a pair of left and right fork tubes and a pair of top and bottom bridges connecting the left and right fork tubes, a headlight, and an electric part accommodating member accommodating electric parts, the electric part accommodating member being disposed on the rear side of the headlight in a space surrounded by the left and right fork tubes and the top and bottom bridges. The electric part accommodating member includes a fastening section fixed to the front fork by a fastening member and a fitting section fitted and fixed to the bridge.

A saddle riding vehicle includes a front fork including a pair of left and right fork tubes and a pair of top and bottom bridges connecting the left and right fork tubes, a headlight, and an electric part accommodating member accommodating electric parts, the electric part accommodating member being disposed on the rear side of the headlight in a space surrounded by the left and right fork tubes and the top and bottom bridges. The electric part accommodating member includes a fastening section fixed to the front fork by a fastening member and a fitting section fitted and fixed to the bridge.

A motorcycle including a motorcycle body having a front part, a tail part and a central part between the front part and the tail part front and rear wheels constrained to the motorcycle body (2,3,4), a traction engine constrained to the motorcycle body (2,3,4) and operatively connected to at least one of the wheels, at least one optical signalling device fixed to the motorcycle body arranged and oriented so as to be visible by a vehicle that is following the motorcycle, an electronic control unit of the optical signalling device operatively connected to the optical signalling device, an obstacle sensor fixed to the motorcycle body (2,3,4) and operatively connected to the electronic control unit, where the electronic control unit is adapted and configured to receive at least one output signal supplied by the obstacle sensor, verifying whether said output signal meets at least one logical activation condition and, in such case, turning on the optical signalling device to signal a risk of collision with the motorcycle to the vehicle which follows the motorcycle, and where the obstacle sensor is arranged and oriented so that the output signal supplied to the electronic control unit carries information correlated to the presence of obstacles placed in front of the motor cycle.

A motorcycle including a motorcycle body having a front part, a tail part and a central part between the front part and the tail part front and rear wheels constrained to the motorcycle body (2,3,4), a traction engine constrained to the motorcycle body (2,3,4) and operatively connected to at least one of the wheels, at least one optical signalling device fixed to the motorcycle body arranged and oriented so as to be visible by a vehicle that is following the motorcycle, an electronic control unit of the optical signalling device operatively connected to the optical signalling device, an obstacle sensor fixed to the motorcycle body (2,3,4) and operatively connected to the electronic control unit, where the electronic control unit is adapted and configured to receive at least one output signal supplied by the obstacle sensor, verifying whether said output signal meets at least one logical activation condition and, in such case, turning on the optical signalling device to signal a risk of collision with the motorcycle to the vehicle which follows the motorcycle, and where the obstacle sensor is arranged and oriented so that the output signal supplied to the electronic control unit carries information correlated to the presence of obstacles placed in front of the motor cycle.

A straddle vehicle includes a vehicle body, a headlamp main body, and a driver circuit. The driver circuit drives the headlamp main body. The headlamp main body includes a housing that accommodates a light emission member. The driver circuit is disposed outside the housing.

A straddle vehicle includes a vehicle body, a headlamp main body, and a driver circuit. The driver circuit drives the headlamp main body. The headlamp main body includes a housing that accommodates a light emission member. The driver circuit is disposed outside the housing.

A human-powered vehicle control device is provided for a human-powered vehicle. The human-powered vehicle control device includes a master electronic controller configured to control a first component and a second component. The first component is configured to be controlled by at least one of the master electronic controller and a first slave electronic controller. The master electronic controller is configured to restrict operation of at least one of the first component and the second component based on a first operation signal transmitted from the first slave electronic controller in a case where the first component is controlled by the first slave electronic controller.