In one embodiment, a method for a process facility is disclosed. The method includes identifying a plurality of moving entities and a plurality of movable parts associated with the process facility. The method further includes determining an action event for each of at least some interactions between one or more of the plurality of moving entities and one or more of the plurality of movable parts, where one or more of the at least some interactions include a manipulation of at least one of the plurality of movables parts by at least one of the plurality of moving entities. Moreover, the method includes determining an actual duration for each of at least some of the action events. Additionally, the method includes tracking the actual duration for each of at least some of the action events in relation to an expected duration of each action event.

A numerical control device includes a multicore CPU for outputting a position command value of a servomotor, an ASIC including a servo controller, which outputs a current command value to an amplifier for driving the servomotor, and another processor, and a DSP for reading the position command value and controlling the servomotor such that the servomotor moves to a position indicated by the position command value. The CPU and the ASIC are connected through a plurality of serial interfaces.

An integrated controller for motion control and motor control comprises a first processor, a second processor, a cache and a shared memory. The first processor is configured to run an operating system and at least perform motion control. The second processor is configured to at least perform motor control and normally not run the operating system. The cache is coupled to the first processor and the second processor. The shared memory maps onto the cache. The first processor and the second processor are configured to share the shared memory and accordingly perform data transmission via the cache during the periods of motion control and motor control. The first processor, the second processor and the cache are integrated in a same chip.

A control system includes a control device that repeatedly performs a series of pieces of processing including I/O refresh processing and program execution processing. The control system includes: a first obtainment unit that obtains a first sample value group collected by repeatedly performing the I/O refresh processing in a first control period; a second obtainment unit that obtains a second sample value group collected by repeatedly performing the I/O refresh processing in a second control period longer than the first control period; a determination unit that determines whether a first frequency component in the first sample value group and a second frequency component in the second sample value group are substantially identical to each other; and a change unit that changes the first control period to the second control period under a condition that the first frequency component and the second frequency component are substantially identical to each other.

A microassembler system includes an alignment surface, a two-dimensional array of electrodes adjacent the alignment surface, a sensor network arranged adjacent the array of electrodes, and a control computer electrically connected to the array of electrodes and the sensor network, the control computer to receive signals from the sensor network indicating a position of at least one chiplet and to actuate the electrodes to change the position of the chiplet based upon the signals. A method of assembling chiplets includes receiving, at one of an array of control logic units, a signal from a control computer identifying an assembly location in a block of an assembly template at which a chiplet is to be located, using a sensor to determine a chiplet location of a nearest chiplet, and generating, using electrodes corresponding to the control logic unit, a traveling wave pattern to translate and orient the nearest chiplet to the location.

A microassembler system includes an alignment surface, a two-dimensional array of electrodes adjacent the alignment surface, a sensor network arranged adjacent the array of electrodes, and a control computer electrically connected to the array of electrodes and the sensor network, the control computer to receive signals from the sensor network indicating a position of at least one chiplet and to actuate the electrodes to change the position of the chiplet based upon the signals. A method of assembling chiplets includes receiving, at one of an array of control logic units, a signal from a control computer identifying an assembly location in a block of an assembly template at which a chiplet is to be located, using a sensor to determine a chiplet location of a nearest chiplet, and generating, using electrodes corresponding to the control logic unit, a traveling wave pattern to translate and orient the nearest chiplet to the location.

A numerical control device includes a multicore CPU for outputting a position command value of a servomotor, an ASIC including a servo controller, which outputs a current command value to an amplifier for driving the servomotor, and another processor, and a DSP for reading the position command value and controlling the servomotor such that the servomotor moves to a position indicated by the position command value. The CPU and the ASIC are connected through a plurality of serial interfaces.