The present invention relates to a phone holder that lets users to use it as phone stand on a flat platform or use as a phone mount on a laptop screen. The phone holder is provided with multiple stoppers for accommodating smartphones, phablets, and tablets. In an embodiment of the present invention, the base of the phone holder has flat surface of one side and curved surface on another to aid in proper clamping of the phone holder on thin screens and thick screens. In various embodiments, the phone mounting mechanism is slidably disposed beneath the laptop screen and laptop screen cover such that poles of phone holder can be pulled and slided out by the user when required. The phone holder is also provided with a miniature ball kicker to kick balls to goal between the phone holders vertical poles, thus helping in relaxation and recreation of user.

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 transformable robot comprises an arm structure, a leg structure and a head of the robot which are fixed to a ribcage structure. The arm structure includes a left arm and a right arm; the leg structure includes a left leg and a right leg; the ribcage structure includes a first steering gear fixed on an upper part of a second fixing frame; a rotating output shaft of the first steering gear successively passes through a top wall of the second fixing frame and a first backing plate to fixedly connected to a first steering wheel fixed on a first rotating frame; the first steering wheel is provided with an arc-shaped limited opening; a limited column on the first backing plate is movably passed through the limited opening; the rotating output shaft of the first steering gear rotates to drive the first rotating frame to rotate.

Bend members making up a variable shape structure each have a central coupling point, a one-end coupling point, and an other-end coupling point that are arranged so as to form a V shape with a fixed bend angle. A central coupling point of the first bend member and a central coupling point of the second bend member are pivotally coupled together. A central coupling point of the third bend member and a central coupling point of the fourth bend member are pivotally coupled together. A one-end coupling point of the first bend member and a one-end coupling point of the third bend member are pivotally coupled together. A one-end coupling point of the second bend member and a one-end coupling point of the fourth bend member are pivotally coupled together. The first, the second, the third, and the fourth bend members are of the same shape and the same size.

An action robot may include a main body, at least one joint, and at least one limb configured to be rotatably connected to the main body via the joint. The joint may be configured to provide elastic force in a direction in which the limb is unfolded or pulled away from the main body and a wire connected to the limb to pull the limb in a direction in which the limb is folded or pulled toward the main body. The wire may be connected to an elevation rod provided inside the main body. A drive assembly may be provided outside the main body and be configured to lift the elevation rod. A rod spring may be provided and configured to provide a downward elastic force to the elevation rod. A wire support provided within the main body may be configured to support the wire.

An action robot may include a main body, at least one joint, and at least one limb configured to be rotatably connected to the main body via the joint. The joint may be configured to provide elastic force in a direction in which the limb is unfolded or pulled away from the main body and a wire connected to the limb to pull the limb in a direction in which the limb is folded or pulled toward the main body. The wire may be connected to an elevation rod provided inside the main body. A drive assembly may be provided outside the main body and be configured to lift the elevation rod. A rod spring may be provided and configured to provide a downward elastic force to the elevation rod. A wire support provided within the main body may be configured to support the wire.

A robot includes a body contactable with a placement surface, a head, at least one actuator, and at least one processor. The head is contactable with the placement surface, and is coupled to a front end of the body so as to be rotatable about a first rotational axis extending in a front-rear direction of the body and rotatable about a second rotational axis extending in a width direction of the body. The at least one actuator turns the head by causing the head to make a turn about the first rotational axis and a turn about the second rotational axis independently of each other. The at least one processor repeats a first turn control scheme and a second turn control scheme in sequence.

This describes a treatment method for autism/ASD intended to induce greater intrinsic motivation to make eye contact in affected children. The treatment method incorporates an artificial demonstration of the phenomenon of eye contact, and that method is described herein along with the principles of action of the treatment and the necessary procedure to perform it. Also described are two embodiments of a therapy tool that can be used to effect the demonstration: first, an item in the form of a cuboid with animatronic eyes affixed to one side, and second, another in the form of a stuffed dog.

A driving mechanism includes a driving member, a transmission member, and a swinging member. The driving member has an output end. The transmission member is connected to the output end of the driving member. The transmission member has a driving slot, and the driving slot extends along a circumferential direction of the transmission member. The swinging member is configured to be movably connected to a body of a robot. A part of the swinging member is movably connected in the driving slot, and configured to move along the driving slot under drive of the transmission member to drive the swinging member to swing.

A toy includes a magnetically responsive member, a fulcrum member, a printed circuit board (PCB), a lid covering the PCB, an activation switch, a touch sensor, a motion sensor, an audio transducer, a signal generator and a controller. The flexible PCB includes an electromagnetic coil, and a plurality of light emitting diodes (LEDs). Opening of the lid actuates the activation switch, and in response, the controller controls the signal generator to generate a coil control signal for the electromagnetic coil to produce a magnetic field that interacts with the magnetically responsive member, to induce oscillatory flapping of the PCB. In response to detecting a touch signal from the controller, or a motion signal from the motion sensor, the controller also generates a LED control signal to control illumination of the LEDs while the PCB is flapping, and an audio control signal to control the audio transducer to output sound.