It is an object of the present invention to reduce the amount of data used in an apparatus, a system, and a method for performing a substrate processing. In order to achieve this object, a substrate processing apparatus includes one or more processing units each for performing a processing on a substrate and one or more arithmetic processing parts. One or more arithmetic processing parts generate a flow recipe defining a flow of a series of processings for a substrate by combining two or more processing recipes among a plurality of processing recipes each defining a processing condition relating to a processing to be performed on a substrate in the one or more processing units. The plurality of processing recipes include a plurality of liquid processing recipes each defining a condition of a processing to be performed on a substrate by using a processing liquid.

An execution plan segment of an execution plan can be received at a control unit of a computer numerically controlled machine from a general purpose computer. The execution plan segment can define operations for causing movement of a moveable head of the computer numerically controlled machine to deliver electromagnetic energy to effect a change in a material within an interior space of the computer numerically controlled machine. The execution plan segment can include a predefined safe pausing point from which the execution plan can be restarted while minimizing a difference in appearance of a finished work-product relative to if a pause and restart are not necessary. Operations of the computer numerically controlled machine can be commenced only after determining that the execution plan segment has been received up to and including the predefined safe pausing point by the computer numerically controlled machine.

A computer-implemented method for generating a model of a laser-engraved surface, the method comprising: transforming a first set of values for a first set of parameters associated with a laser-engraving process to a second set of values for a second set of parameters associated with a laser pulse model; modifying the laser pulse model based on the second set of values to produce a modified laser pulse model; and executing the modified laser pulse model to direct a plurality of laser pulses towards a computer-simulated surface, wherein the plurality of laser pulses modify the computer-simulated surface.

A harsh environment enclosure for use with sensor systems, such as cameras. The enclosure can include a housing having an end wall, sidewalls, a top wall, and a bottom wall. A door is hinged to the top wall. The enclosure can have a linkage assembly including a door lever having an elongate first end portion connected to the door, a laterally extending second end portion, and an elbow positioned therebetween. A pivot arm having a proximal end is connected to an interior surface of the housing and a distal end of the pivot arm is connected to the elbow. An actuator can be connected between the housing and the laterally extending second end portion. The linear actuator can be positioned with respect to the door lever and pivot arm to move the door to an open position when extended and a closed position when retracted.

A patterned smart card module includes a chip module and a patterned ink layer coated on a conductive surface of the chip module. The IC chip of the chip module stores chip data therein, and the chip data includes holder-related data. The patterned ink layer has a pattern relating to the holder-related data.

A self-configuring computer-controlled fabrication apparatus that utilizes no fewer than four user changeable tools concurrently installed to fabricate a three-dimensional component from digital design data out of a variety of materials using additive and/or subtractive methods. User interchangeable tools perform different tasks including paste extrusion, filament extrusion, inkjet deposition, laser curing, laser etching, milling, cooling, curing, inspection, and component placement, among others. Each tool, that is selected and installed by the user for each job, contains operational information regarding its performance in nonvolatile memory such that the system can read, then adapt, the build process to the set of tools currently installed.

It is an object of the present invention to reduce the amount of data used in an apparatus, a system, and a method for performing a substrate processing. In order to achieve this object, a substrate processing apparatus includes one or more processing units each for performing a processing on a substrate and one or more arithmetic processing parts. One or more arithmetic processing parts generate a flow recipe defining a flow of a series of processings for a substrate by combining two or more processing recipes among a plurality of processing recipes each defining a processing condition relating to a processing to be performed on a substrate in the one or more processing units. The plurality of processing recipes include a plurality of liquid processing recipes each defining a condition of a processing to be performed on a substrate by using a processing liquid.

A method may include generating, by a camera having a view of an interior portion of a computer-numerically-controlled machine, an image comprising a pattern. The image can be transformed into a set of machine instructions for controlling the computer-numerically-controlled machine to effect a change in a material. The change can correspond to at least a portion of the pattern. At least one machine instruction from the set of machine instructions can be executed to control the computer-numerically-controlled machine to effect at least a portion of the change. The execution can include operating, in accordance with the at least one machine instruction, a tool coupled with the computer-numerically-controlled machine. The tool can be configured to effect the change on the material. Related systems and articles of manufacture, including computer program products, are also provided.

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.

A host computer, a plurality of thermal carving machines, and a user terminal are connected to a network. The host computer includes seal image creation means that permits edition of a seal image using the user terminal, site selection means that allows a user to specify one site from a site candidates list, ID issuing means that issues an order ID for identifying the contents of an order, and order information registration means that registers the issued order ID and order information in a database. A control device of the thermal carving machine includes order acceptance means that accepts an order ID input when information on the input order ID is registered in the database, and carving control means that performs seal carving of a stamp based on seal image data associated with the order ID.