A programmable robot includes a body, a pair of drive wheels rotatably coupled to the body, a pair of electric motors in the body for driving the drive wheels, a receiver unit configured to receive at least one wireless command from a programming device, a sensor configured to sense a surrounding environment of the programmable robot, and a controller operably connected to the receiver unit and the sensor, the controller configured to control operation of the electric motors in response to the at least one wireless command received from the receiver unit and a data signal received from the sensor.

A vehicle platform with positioning and guiding mechanisms and having a single wheel. A frame extends from the vehicle with a receptacle connected to the frame, and a motor drives the vehicle forward and rearward. A head appendage is mounted to the receptacle to yaw left and right, pitch up and down, and roll from side to side to guide the vehicle. Another motor provides for positioning the appendage to roll, with an additional motor for positioning the head to pitch and yaw. A pair of left and right rims is disposed adjacent to the wheel for limiting lean of the vehicle platform, and a control system is incorporated.

The present disclosure provides a collision judgment method and apparatus. The method includes: determining, by a moving device, according to acceleration data collected by an acceleration sensor, that the moving device collides; sending collision information to the corresponding control device, including at least a moving device identifier and a collision time; sending, by the corresponding control device, the collision information to a collision judgment device; detecting, by the collision judgement device, whether at least two collision information sent by the at least two control devices is received within a predetermined time interval; when the at least two collision information is received within the predetermined time interval, and a difference between collision times carried in the at least two collision information is less than a preset threshold, determining that moving devices corresponding to moving device identifiers carried in the at least two collision information collided with one other.

The present disclosure provides a collision judgment method and apparatus. The method includes: determining, by a moving device, according to acceleration data collected by an acceleration sensor, that the moving device collides; sending collision information to the corresponding control device, including at least a moving device identifier and a collision time; sending, by the corresponding control device, the collision information to a collision judgment device; detecting, by the collision judgement device, whether at least two collision information sent by the at least two control devices is received within a predetermined time interval; when the at least two collision information is received within the predetermined time interval, and a difference between collision times carried in the at least two collision information is less than a preset threshold, determining that moving devices corresponding to moving device identifiers carried in the at least two collision information collided with one other.

An unpowered downhill autonomous car kit is provided for a user to build. The kit includes a control circuit board, a servo, and a roadway detection sensor. The control circuit board is programmed by a user to interpret patterns marked on a race course that are detected by the roadway detection sensor, and then the control circuit board instructs the servo to steer the car based on the detected roadway patterns. The challenge is for the user to program the car kit in a manner such that during a race, the car will avoid vertical barriers on the race course by correctly interpreting the patterns viewed by the roadway detection sensor. The roadway patterns are intentionally not consistent as the car moves from one roadway segment to the next, so as to increase the technical challenge.

An unpowered downhill autonomous car kit is provided for a user to build. The kit includes a control circuit board, a servo, and a roadway detection sensor. The control circuit board is programmed by a user to interpret patterns marked on a race course that are detected by the roadway detection sensor, and then the control circuit board instructs the servo to steer the car based on the detected roadway patterns. The challenge is for the user to program the car kit in a manner such that during a race, the car will avoid vertical barriers on the race course by correctly interpreting the patterns viewed by the roadway detection sensor. The roadway patterns are intentionally not consistent as the car moves from one roadway segment to the next, so as to increase the technical challenge.

The present disclosure provides a collision judgment method and apparatus. The method includes: determining, by a moving device, according to acceleration data collected by an acceleration sensor, that the moving device collides; sending collision information to the corresponding control device, including at least a moving device identifier and a collision time; sending, by the corresponding control device, the collision information to a collision judgment device; detecting, by the collision judgement device, whether at least two collision information sent by the at least two control devices is received within a predetermined time interval; when the at least two collision information is received within the predetermined time interval, and a difference between collision times carried in the at least two collision information is less than a preset threshold, determining that moving devices corresponding to moving device identifiers carried in the at least two collision information collided with one other.

The present disclosure provides a collision judgment method and apparatus. The method includes: determining, by a moving device, according to acceleration data collected by an acceleration sensor, that the moving device collides; sending collision information to the corresponding control device, including at least a moving device identifier and a collision time; sending, by the corresponding control device, the collision information to a collision judgment device; detecting, by the collision judgement device, whether at least two collision information sent by the at least two control devices is received within a predetermined time interval; when the at least two collision information is received within the predetermined time interval, and a difference between collision times carried in the at least two collision information is less than a preset threshold, determining that moving devices corresponding to moving device identifiers carried in the at least two collision information collided with one other.

A children's toy includes a base having an upper portion and a lower portion and a driving mechanism operably connected to the lower portion of the base. The driving mechanism is configured to move the base along a plurality of paths. One or more lights operably connected to the base are configured to display a patterned light display as the base moves along one of a plurality of paths. A removable member is also included for placement on the base with a sensor on the base triggered by the removable member which affects the path of the base.

The invention relates to a simulation intelligent electric toy car with intelligent path planning which includes: a positioning module, configured to mark elevator position coordinates and home door position coordinates in the same coordinate system, and drive the toy car to automatically travel from the home door to the elevator and travel from the elevator to the home door according to the elevator position coordinates and the home door position coordinates; a marking module, configured to mark coordinates of a specific location according to an indication of the user; a planning module, configured to plan a specific path according to coordinates of the specific location, and drive the toy car to automatically travel along the specific path; an acquiring module, configured to acquire, by using a camera, an object that which the toy car passes through car during driving; a processing module, configured to analyze the object to obtain a name and related content of the object, and convert the related content into an audio format for playing and provide various functions.