A training game has a cylindrical conduit having exterior walls and interior walls forming an aperture therethrough that is adapted and sized to accept at least one aerial projectile therethrough. A means for sensing and measuring aerial projectile movement in electronic communication with at least one of said conduit or said projectile is provided. A central processing unit is provided and adapted to calculate and communicate game information with at least player in electronic communication with the means for sensing and measuring aerial projectile movement.

A toy vehicle launcher has a housing, a handle, a slidable plate, a retention member, and biasing elements. The handle is moveably attached to the housing. The slidable plate is operatively coupled to the handle and movable with respect to the housing. The slidable plate includes sequential notches. The first biasing element couples the slidable plate to the housing. The first biasing element biases the slidable plate in a first direction with respect to the housing. Movement of the handle moves the slidable plate in a second direction against the bias of the first biasing element. The retention member is disposed proximate the slidable plate and configured to engage and disengage with notches. The second biasing element attaches the retention member to the launcher housing. The second biasing element biases the retention member into contact with the slidable plate.

A circuit arrangement for a model car racing track, having at least two tracks for model cars, wherein a positive busbar and a negative busbar are in each case assigned to each track, and a first driving speed controller is connected between a positive supply terminal and the positive busbar of the first track and a second driving speed controller is connected between a negative supply terminal and the minus busbar of the second track.

A user input device is provided that includes a button-based control mechanism. The button-based control mechanism includes a button, the button including a user-depressible button top and a button stem, and a button depression guide disposed within an internal cavity of the user input device that engages with the button stem to cause the button to move from a default position and along a substantially arc-shaped path when pressure is applied to the button top. The substantially arc-shaped path may be around an axis of rotation that is external to the user input device. The button-based control mechanism further includes a button biasing mechanism disposed within the internal cavity that returns the button to the default position when the pressure is removed from the button top and at least one sensor that detects actuation of the button responsive to the movement of the button away from the default position.

A marble run apparatus kit includes a plurality of physically interconnectable marble run modules, each module configured to retain a marble and guide the travel of the marble through the module. The plurality of marble run modules includes at least a first controllable module. The first controllable module includes a baffle, an actuator, and a wireless receiver. The baffle is disposed in the module, and has a first position and a second position. The baffle is configured to direct the marble within the module in different directions based on whether the baffle is in the first position or the second position. The actuator is supported on the module, and receives a first control signal. The actuator changes the position of the baffle responsive to receiving the first control signal. The wireless receiver provides the first control signal to the actuator upon receiving a first wireless control signal.

A marble run apparatus kit includes a plurality of physically interconnectable marble run modules, each module configured to retain a marble and guide the travel of the marble through the module. The plurality of marble run modules includes at least a first controllable module. The first controllable module includes a baffle, an actuator, and a wireless receiver. The baffle is disposed in the module, and has a first position and a second position. The baffle is configured to direct the marble within the module in different directions based on whether the baffle is in the first position or the second position. The actuator is supported on the module, and receives a first control signal. The actuator changes the position of the baffle responsive to receiving the first control signal. The wireless receiver provides the first control signal to the actuator upon receiving a first wireless control signal.

A first grounded portion is at least one of portions of an apparatus that are grounded, and vibrates in accordance with a vibration of at least a first vibration unit. A second grounded portion is at least one of the portions of the apparatus that are grounded, and vibrates in accordance with a vibration of at least a second vibration unit. Then, a first control signal for controlling the vibration of the first vibration unit and a second control signal for controlling the vibration of the second vibration unit are generated, whereby, in a state where the apparatus is on a certain surface, the apparatus moves on the certain surface by a vibration of the first grounded portion grounded on the certain surface and/or a vibration of the second grounded portion grounded on the certain surface.

Example implementations may relate to an RC vehicle with a receiver and an inertial measurement unit. In particular, the RC vehicle may include vehicle controller circuitry that works together with the inertial measurement unit to instruct the receiver to enter a bind mode when the RC vehicle is rotated, oriented, or positioned in a certain way. In an example embodiment, the RC vehicle may instruct the receiver to enter a bind mode when the RC vehicle is first powered on and is rotated 180 degrees in a certain direction, such as from upright to upside-down.

Example implementations may relate to an RC vehicle with a receiver and an inertial measurement unit. In particular, the RC vehicle may include vehicle controller circuitry that works together with the inertial measurement unit to instruct the receiver to enter a bind mode when the RC vehicle is rotated, oriented, or positioned in a certain way. In an example embodiment, the RC vehicle may instruct the receiver to enter a bind mode when the RC vehicle is first powered on and is rotated 180 degrees in a certain direction, such as from upright to upside-down.

Example implementations may relate to an RC vehicle with a receiver and an inertial measurement unit. In particular, the RC vehicle may include vehicle controller circuitry that works together with the inertial measurement unit to instruct the receiver to enter a bind mode when the RC vehicle is rotated, oriented, or positioned in a certain way. In an example embodiment, the RC vehicle may instruct the receiver to enter a bind mode when the RC vehicle is first powered on and is rotated 180 degrees in a certain direction, such as from upright to upside-down.