A master communication apparatus comprises a master wired communicator, a master wireless communicator, and a master controller. The master wired communicator is configured to communicate with a slave wired communicator of a slave communication apparatus in the human-powered vehicle via a wired communication channel. The master wireless communicator is configured to communicate with a slave wireless communicator of the slave communication apparatus via a wireless communication channel. The master controller is configured to transmit, via one of the master wired communicator and the master wireless communicator, a control signal to control a component of the human-powered vehicle. The master controller is configured to control the master wired communicator and the master wireless communicator in accordance with a priority order. The master controller is configured to set the priority order in accordance with information relating to the master communication apparatus and the slave communication apparatus.

An apparatus for a bicycle includes an intermediate power connector configured for transmitting power between a bicycle component and a power source positioned remote from the bicycle component. The intermediate power connector has a coupling portion configured for removable attachment to a connecting portion of the bicycle component. The bicycle component can also include a battery having a battery coupling portion configured for removable attachment to the connecting portion of the bicycle component. The battery and the intermediate power connector can be selectively attachable to the bicycle component to provide power thereto.

This control apparatus includes (A) a first connecting part, which is connected with a driving control apparatus for controlling driving of a power unit for assisting a human power or with the power unit, and through which a current relating to charging and discharging of an electrical power storage device flows, (B) a second connecting part, which is provided separately from the first connecting part, and through which a current relating to charging to the electrical power storage device flows via an electrical connection, and (C) a controller to control charging and discharging of the electrical power storage device, which are performed by using a current, which flows in the first connecting part and/or the second connecting part.

System, methods, and other embodiments described herein relate to adjusting a trip fare according to in-vehicle charging provided by a passenger. In one embodiment, a method includes, in response to initiating a trip in the vehicle for a passenger, accumulating the trip fare as a function of traveling a route to fulfill the trip. The method includes metering one or more charging devices to identify a metered charge produced by the passenger operating the one or more charging devices during the trip. The method includes computing a fare offset according to at least the metered charge to identify an amount by which the trip fare is to be discounted. The method includes adjusting the trip fare according to the fare offset to account for an electric charge provided to the vehicle during the trip.

The present invention relates to a bicycle-type game simulation device comprising: a crank pedal unit; a swing footrest horizontally rotatably installed in the crank pedal unit; a swing detection means which detects a left-and-right rotation of the swing footrest and transmits a signal thereof; and a forward-and-backward rotation detection means which detects a forward/reverse rotation of a crank shaft and transmits a signal thereof, wherein a user can easily operate a behavioral motion of a player in a game with his/her foot, using the mechanism of a crank pedal of a bicycle, so that the user can perceive a good sense of reality.

An object is to provide a moving object structure capable of reducing power loss caused when power is supplied from a power feeding device to a moving object by wireless communication. Another object is to provide a moving object structure capable of reducing the intensity of radio waves radiated to the surroundings. A moving object having a plurality of antennas receives radio waves transmitted from a power feeding device. At least one of the plurality of antennas is installed apart from the other antenna(s) of the moving object. Then, the radio waves transmitted from the power feeding device are received by all the plurality of antennas and converted into electric energy. Alternatively, the radio waves transmitted from the power feeding device are received by one or more selected from the plurality of antennas and converted into electric energy.

A support device is provided that can attach to or be integrated with a baby stroller, that combines a mirror, a charging apparatus, an electronic device support and a remote control system in a manner that allows simultaneous charging of the electronic device, accessing of electronic device content and two way interaction between the user and the baby seated in the forward facing stroller.

A smart phone charging system includes a bicycle that has a frame, handlebars and a rear tire. An electronic device is provided. A charging unit is coupled to the frame. The charging unit engages the rear tire such that the rear tire rotates the charging unit. Thus, the charging unit produces an electrical current. The charging unit is electrically coupled to the electronic device such that the charging unit charges the electronic device. A gripping unit is coupled to the handlebars. The gripping unit engages the electronic device such that the electronic device is accessible to a rider.

An object is to provide a moving object structure capable of reducing power loss caused when power is supplied from a power feeding device to a moving object by wireless communication. Another object is to provide a moving object structure capable of reducing the intensity of radio waves radiated to the surroundings. A moving object having a plurality of antennas receives radio waves transmitted from a power feeding device. At least one of the plurality of antennas is installed apart from the other antenna(s) of the moving object. Then, the radio waves transmitted from the power feeding device are received by all the plurality of antennas and converted into electric energy. Alternatively, the radio waves transmitted from the power feeding device are received by one or more selected from the plurality of antennas and converted into electric energy.

A dynamo that is connectable to a wheel of a bicycle may include an electric machine capable of alternatively operating as a generator and as a motor and one or more batteries connected to the electric machine in order to be capable of exchanging energy with this latter. The dynamo may also include a control unit configured for commanding the electric machine according to a first mode, wherein the electric machine acts as a generator and is capable of converting rotational mechanical energy of the wheel into electric energy to be stored in the one or more batteries, and according to a second mode, wherein the electric machine acts as a motor and is capable of delivering additional power to the bicycle wheel by withdrawing energy from the one or more batteries. The dynamo may further include one or more command members connected to the control unit.