This disclosure relates generally to a robotic gripper to hold a writing and object creation device for writing and object creation. The robotic gripper includes clamping unit, spring loaded slider unit and outer housing unit. The clamping unit include a finger collet with three or more flexible finger positions equispaced within 360 degrees with two areas of contact on each finger in front part for firm gripping. The spring loaded slider unit include a middle housing to transfer a force from the writing and object creation device to a force sensitive resistor (FSR). A micro actuator induces a required force to the writing and object creation device based on feedback from the force sensitive resistor. The middle housing includes a plunger shaft connected with a preload spring. The outer housing unit configured to hold a micro actuator, cotter pins, locator pins to the micro actuator, and a push pull key.

A cutting machine head and a cutting machine are provided in the present invention. The cutting machine head includes a fixing plate, a cutter holder, a cutting component, a machine head lifting mechanism and a machine head rotating mechanism. The cutter holder is mounted on the fixing plate. The machine head lifting mechanism is connected to the cutter holder, and is used to drive the cutter holder to move up and down on the fixing plate. The cutting component includes at least two cutter head assemblies mounted on the cutter holder. The machine head rotating mechanism is connected to the cutter head assemblies for driving the cutter head assemblies to rotate. The rotating angle of each cutter head assembly of the cutting machine head can be controlled. The machine head rotating mechanism controls the cutter head assembly to rotate when the machine head is cutting, and the resulting cutting line has no flaws, which can ensure the integrity of the cutting pattern.

Processes for dividing the arc of an angle and its angle into n number of equal parts. The same processes apply to dividing the arc of a wave of any amplitude into n number of equal lengths. The number of equal divisions to be derived may be either an even number or an odd number. The number of degrees in the arc of a circle or the angle of the circle, or in the arc of a wave or its amplitude, need be known.

The present invention provides for a wall mountable system for automated drawing of an image upon a wall which includes a horizontal mounting track for mounting on a wall, a robot having a y-track rigidly mounted it where the robot and the mounted y-track travel along the horizontal track. An end effector, which includes a pen holding mechanism holding a pen, is in electrical communication with the robot and travels along the y-track of the robot. The present invention provides a system and device that can attach to a wall or vertical surface in a damage-free manner and draw fast any complexity or style image of custom size in both the horizontal (X) and vertical (Y) directions, that is easy to remove and transport and require small floor space to operate.

Aspects of the present disclosure relate to illustration robot movement. In examples, a destination location may specify a location to which the illustration robot should move a writing instrument from its current location. In some examples, the robot may not be parallel to the vector from the location of the writing instrument to the destination location, such that the robot may need to rotate or turn in order to create the illustration. Accordingly, the robot may move along an arc determined to cause the writing instrument to move tangent to the vector. Further, the arc may be periodically recalculated in order to maintain the movement of the writing instrument along the vector, rather than along an arc.

A gaging apparatus and method for automation of a shoemaking process are provided for automating a shoemaking process. According to the method, the gaging apparatus obtains operation data according to the gaging process of drawing a gaging line on a boundary between the upper and the sole for shoe manufacturing, and generates trajectory data for the boundary based on the operation data. Based on the trajectory data, the gaging apparatus generates robot trajectory data for performing a buffing and bonding process after the gaging process and transmits it to a shoemaking robot.

A vertically driving marking robot includes a robot body; at least one magnet constraining the robot to move parallel to a vertical, magnetically responsive surface; a drive configured to displace the robot relative to the surface while the robot is held to the surface; a holder configured to hold a marker; an accelerometer measuring a gravity vector; a computing device in communication with the optical sensors, the accelerometer, and the drive. The computing device includes a processor and computer-readable memory, wherein the computer-readable memory includes non-transitory program code for at least one of the following actions: (a) generating a drift correction to compensate for drive slippage drift in response to and as a function of the gravity vector and (b) commanding the drive to displace the robot along a desired trajectory in response to the drift correction.

Aspects of the present disclosure relate to illustration robot movement. In examples, a destination location may specify a location to which the illustration robot should move a writing instrument from its current location. In some examples, the robot may not be parallel to the vector from the location of the writing instrument to the destination location, such that the robot may need to rotate or turn in order to create the illustration. Accordingly, the robot may move along an arc determined to cause the writing instrument to move tangent to the vector. Further, the arc may be periodically recalculated in order to maintain the movement of the writing instrument along the vector, rather than along an arc.

In a method for interactive marking by a mobile robot on a vertical surface, a mobile robot that includes a sensor and an actuated marker is displaced across a vertical surface. Features on, in or behind the vertical surface are detected with the sensor. Displacement of the mobile robot and actuation of the actuated marker is controlled in response to the detection of these features.

In a method for interactive marking by a mobile robot on a vertical surface, a mobile robot that includes a sensor and an actuated marker is displaced across a vertical surface. Features on, in or behind the vertical surface are detected with the sensor. Displacement of the mobile robot and actuation of the actuated marker is controlled in response to the detection of these features.