A method of manufacturing a toy finger skateboard may include inserting a flange portion of a toy finger skateboard truck into a flange receiver of a toy finger skateboard deck. The toy finger skateboard truck is moved such that a column portion of the toy finger skateboard truck is received by a through hole of the toy finger skateboard deck, and then, the method involves interacting with a top end of the column portion of the toy finger skateboard truck to affix the toy finger skateboard truck to the toy finger skateboard deck. A portion of the top end of the column portion may be cylindrical. The top end of the column portion of the toy finger skateboard truck may be welded to a seat portion of the toy finger skateboard deck, and the welding may include spin welding.

A method of manufacturing a toy finger skateboard may include inserting a flange portion of a toy finger skateboard truck into a flange receiver of a toy finger skateboard deck. The toy finger skateboard truck is moved such that a column portion of the toy finger skateboard truck is received by a through hole of the toy finger skateboard deck, and then, the method involves interacting with a top end of the column portion of the toy finger skateboard truck to affix the toy finger skateboard truck to the toy finger skateboard deck. A portion of the top end of the column portion may be cylindrical. The top end of the column portion of the toy finger skateboard truck may be welded to a seat portion of the toy finger skateboard deck, and the welding may include spin welding.

A toy finger board kit includes a board and at least one shoe. Each shoe includes a finger hole in an upper of the shoe and at least one bracket on a sole of shoe. The at least one bracket is configured to removably attach the at least one shoe to the board. In some instances, the board is formed by inserting a flange portion of a toy finger skateboard truck into a flange receiver of a toy finger skateboard deck. Then, the toy finger skateboard truck is moved such that a column portion of the toy finger skateboard truck is received by a through hole of the toy finger skateboard deck. Finally, a top end of the column portion of the toy finger skateboard truck is affixed to the toy finger skateboard truck to the toy finger skateboard deck.

A toy finger board kit includes a board and at least one shoe. Each shoe includes a finger hole in an upper of the shoe and at least one bracket on a sole of shoe. The at least one bracket is configured to removably attach the at least one shoe to the board. In some instances, the board is formed by inserting a flange portion of a toy finger skateboard truck into a flange receiver of a toy finger skateboard deck. Then, the toy finger skateboard truck is moved such that a column portion of the toy finger skateboard truck is received by a through hole of the toy finger skateboard deck. Finally, a top end of the column portion of the toy finger skateboard truck is affixed to the toy finger skateboard truck to the toy finger skateboard deck.

A robot system has a follower robot and a leader robot. The follower robot follows the path of the leader robot using infrared (IR) signals. The follower robot follows the physical path and positioning of the leader robot. The leader robot is permitted to travel an arbitrary path or is controlled by a wireless transmitter. Relative robot positioning, being distance or direction can use an infrared system between respective robots.

A programmable robot for educational purposes comprising a body comprising a drive system for causing the robot to move, an information acquisition device configured to acquire information from an external information carrying element, and a first connection element, and a head comprising a control system with a data storage element and a processor element being configured to receive a data signal transmitted from the at least one information acquisition device, the data signal comprising the acquired information from the external information carrying element, to process the data signal to interpret the information and achieve instructions, and to cause the drive system to move the robot in accordance with the instructions, and a second connection element, where the body and the head are adapted to be detachably coupled to one another by connecting the first connection element and the second connection element to one another.

Disclosed herein is a racer, in accordance with some embodiments. Accordingly, the racer may include a figurine. Further, the figurine may include a transportation device. Further, the transportation device may be configured to be secured to be a portion of the figurine using a fastener. Further, the transportation device may include a propulsion assembly and a power source. Further, the propulsion assembly may be configured for propelling the figurine. Further, the propelling set the figurine into a motion. Further, the power source may be configured for powering the propulsion assembly. Further, the propelling of the figurine may be based on the powering. Further, the figurine may be configured to be oriented in an orientation.

Disclosed herein is a racer, in accordance with some embodiments. Accordingly, the racer may include a figurine. Further, the figurine may include a transportation device. Further, the transportation device may be configured to be secured to be a portion of the figurine using a fastener. Further, the transportation device may include a propulsion assembly and a power source. Further, the propulsion assembly may be configured for propelling the figurine. Further, the propelling set the figurine into a motion. Further, the power source may be configured for powering the propulsion assembly. Further, the propelling of the figurine may be based on the powering. Further, the figurine may be configured to be oriented in an orientation.

A bubble generating assembly has a housing shaped as an animal. The housing is made up of an upper housing section and a lower housing section that define an interior space, the upper housing having a front edge and a rear edge, a bubble opening positioned adjacent the front edge, and a bubble inlet positioned adjacent the rear edge. The lower housing section has a front piece with a transparent or open section, such that a bubble solution reservoir is positioned in the interior space adjacent the transparent or open section such that the contents of the bubble solution reservoir are visible from outside the housing. A bubble generator is positioned adjacent the upper housing section and generates bubbles that are emitted through the bubble opening. A plurality of legs is positioned below the lower housing section, and extend outside the width of the housing.

A bubble generating assembly has a housing shaped as an animal. The housing is made up of an upper housing section and a lower housing section that define an interior space, the upper housing having a front edge and a rear edge, a bubble opening positioned adjacent the front edge, and a bubble inlet positioned adjacent the rear edge. The lower housing section has a front piece with a transparent or open section, such that a bubble solution reservoir is positioned in the interior space adjacent the transparent or open section such that the contents of the bubble solution reservoir are visible from outside the housing. A bubble generator is positioned adjacent the upper housing section and generates bubbles that are emitted through the bubble opening. A plurality of legs is positioned below the lower housing section, and extend outside the width of the housing.