An action robot according to an embodiment of the present disclosure may include a figure configured to have a plurality of joints, a figure base configured to support the figure from below, a plurality of seesaw levers configured to be embedded in the figure base, the plurality of seesaw levers being configured to be disposed to be long in a radial direction of the figure base, the plurality of seesaw levers being configured to be spaced apart from each other in a circumferential direction of the figure base, a wire configured to be connected to an inner end portion of the seesaw lever to pivot the joint, a plurality of rods configured to be disposed vertically, the plurality of rods being configured to press an outer end portion of the seesaw lever upward, at least one lifter configured to raise the rod, and a revolution mechanism configured to revolve the lifter about a virtual vertical axis passing through a center of the figure base. The number of the lifters may be less than the number of rods.

An action robot according to an embodiment of the present disclosure may include a figure configured to have a plurality of joints, a figure base configured to support the figure from below, a plurality of seesaw levers configured to be embedded in the figure base, the plurality of seesaw levers being configured to be disposed to be long in a radial direction of the figure base, the plurality of seesaw levers being configured to be spaced apart from each other in a circumferential direction of the figure base, a wire configured to be connected to an inner end portion of the seesaw lever to pivot the joint, a plurality of rods configured to be disposed vertically, the plurality of rods being configured to press an outer end portion of the seesaw lever upward, at least one lifter configured to raise the rod, and a revolution mechanism configured to revolve the lifter about a virtual vertical axis passing through a center of the figure base. The number of the lifters may be less than the number of rods.

A radio controlled (RC) vehicle includes a receiver that is coupled to receive an RF signal from a remote control device, the RF signal containing command data in accordance with a first coordinate system, wherein the first coordinate system is from a perspective of the remote control device. A motion sensing module generates motion data based on the motion of the RC vehicle. A processing module transforms the command data into control data in accordance with a second coordinate system, wherein the second coordinate system is from a perspective of the RC vehicle. A plurality of control devices control the motion of the RC vehicle based on the control data.

A radio controlled (RC) vehicle includes a receiver that is coupled to receive an RF signal from a remote control device, the RF signal containing command data in accordance with a first coordinate system, wherein the first coordinate system is from a perspective of the remote control device. A motion sensing module generates motion data based on the motion of the RC vehicle. A processing module transforms the command data into control data in accordance with a second coordinate system, wherein the second coordinate system is from a perspective of the RC vehicle. A plurality of control devices control the motion of the RC vehicle based on the control data.

A radio controlled (RC) vehicle includes a receiver configured to receive a radio frequency (RF) signal from a remote control device. The RF signal indicates command data in accordance with a first coordinate system. The command data includes yaw-velocity command data. The RC vehicle includes motion sensors configured to generate motion data. The RC vehicle includes a processor coupled to the motion sensors and to the receiver. The processor is configured to transform the command data into control data based on the motion data and in accordance with a second coordinate system from a perspective of the RC vehicle. The control data includes yaw-velocity control data. The yaw-velocity control data is related to the yaw-velocity command data. The RC vehicle includes control devices coupled to the processor and configured to control motion of the RC vehicle based on the control data.

A radio controlled (RC) vehicle includes a receiver configured to receive a radio frequency (RF) signal from a remote control device. The RF signal indicates command data in accordance with a first coordinate system. The command data includes yaw-velocity command data. The RC vehicle includes motion sensors configured to generate motion data. The RC vehicle includes a processor coupled to the motion sensors and to the receiver. The processor is configured to transform the command data into control data based on the motion data and in accordance with a second coordinate system from a perspective of the RC vehicle. The control data includes yaw-velocity control data. The yaw-velocity control data is related to the yaw-velocity command data. The RC vehicle includes control devices coupled to the processor and configured to control motion of the RC vehicle based on the control data.

The figure system includes: a plurality of drive units each including an actuator that generates rotative force; and a figure including a plurality of movable mechanisms and a plurality of flexible wires. The movable mechanisms each include a movable body that operates by the rotative force and an operation amount detector that detects an amount of operation of the movable body. The flexible wires include their respective first ends that are coupled to the movable bodies. The rotative force generated by one of the actuators is transmitted to corresponding one of the movable bodies through one of the flexible wires.

The figure system includes: a plurality of drive units each including an actuator that generates rotative force; and a figure including a plurality of movable mechanisms and a plurality of flexible wires. The movable mechanisms each include a movable body that operates by the rotative force and an operation amount detector that detects an amount of operation of the movable body. The flexible wires include their respective first ends that are coupled to the movable bodies. The rotative force generated by one of the actuators is transmitted to corresponding one of the movable bodies through one of the flexible wires.

A puppet having left and right upper and lower limbs, a body and head. Each upper limb includes a finger recess shaped to receive a respective finger of a first one of an operators hands, and the head has at least one finger recess to receive a finger of the first one of the operators hands, and each lower limb includes a finger recess shaped to receive a respective finger of the other, operators hand. At least one of the upper limbs may have a movable finger associated therewith, the finger being movable by a cable drive arrangement operable by a lever mounted upon the body. The head may have a pair of finger recesses associated therewith to receive respective fingers of the first one of the operators hands, wherein the finger recesses associated with the head comprise respective finger receiving components, each of which is pivotally connected to the head such that relative forward-backward movement between the finger receiving components drives the head for angular movement.

A puppet having left and right upper and lower limbs, a body and head. Each upper limb includes a finger recess shaped to receive a respective finger of a first one of an operators hands, and the head has at least one finger recess to receive a finger of the first one of the operators hands, and each lower limb includes a finger recess shaped to receive a respective finger of the other, operators hand. At least one of the upper limbs may have a movable finger associated therewith, the finger being movable by a cable drive arrangement operable by a lever mounted upon the body. The head may have a pair of finger recesses associated therewith to receive respective fingers of the first one of the operators hands, wherein the finger recesses associated with the head comprise respective finger receiving components, each of which is pivotally connected to the head such that relative forward-backward movement between the finger receiving components drives the head for angular movement.