An electromagnetic immunity test system includes a data acquisition and control device, a linear module, an electromagnetic disturbance simulator, and an upper computer. The data acquisition and control device is in a data connection to the linear module, the electromagnetic disturbance simulator, and the upper computer. The linear module includes a grating ruler; and the linear module is disposed on the numerical control machine tool to measure location data of the sliding table of the numerical control machine tool and transmit the location data to the data acquisition and control device. The electromagnetic disturbance simulator is configured to generate and transmit an electromagnetic signal to the numerical control system. The data acquisition and control device is configured to read the location data in real time and transfer the real-time location data to the upper computer.

One embodiment includes a monitor module for a first device, wherein the first device is configured to obtain measurement data from a second device, to compare the measurement data to a reference value, and to send a signal when the measurement data in comparison to the reference indicates an error condition. Machine learning can be used, where a head-end is capable of modifying the second device when the reference value so indicates. This enables various embodiments to fix the second device without human intervention

A robot is controlled by a control unit. The robot includes: a first sensor; a second sensor; a third sensor; a fourth sensor; a first circuit capable of transmitting and receiving signals to and from the first sensor and the second sensor; and a second circuit capable of transmitting and receiving signals to and from the third sensor and the fourth sensor. The control unit and the first circuit are connected through a first serial wire, and the first circuit and the second circuit are connected through a second serial wire.

The present disclosure provides a method for accelerating remote control of a measurement application device, the method comprising receiving a control command for the measurement application device, the control command being received in a text-based format that uses a predetermined character encoding for encoding the command text, mapping the received control command to a command identifier, and transmitting the command identifier to the measurement application device.

A thickness measurement system includes a composite carrier assembly and a thickness sensor system. The composite carrier assembly includes a sample carrier and a gauge standard carrier. The sample carrier and gauge standard carrier are configured to simultaneously support a sample and a gauge standard, respectively. The thickness sensor system is configured to generate a signal representative of a thickness of the sample and to be calibrated with the gauge standard while the sample and the gauge standard are simultaneously supported by the sample carrier and the gauge standard carrier, respectively.

A robot is controlled by a control unit. The robot includes: a first sensor; a second sensor; a third sensor; a fourth sensor; a first circuit capable of transmitting and receiving signals to and from the first sensor and the second sensor; and a second circuit capable of transmitting and receiving signals to and from the third sensor and the fourth sensor. The control unit and the first circuit are connected through a first serial wire, and the first circuit and the second circuit are connected through a second serial wire.

One embodiment includes a monitor module for a first device, wherein the first device is configured to obtain measurement data from a second device, to compare the measurement data to a reference value, and to send a signal when the measurement data in comparison to the reference indicates an error condition. Machine learning can be used, where a head-end is capable of modifying the second device when the reference value so indicates. This enables various embodiments to fix the second device without human intervention.

An electromagnetic immunity test system includes a data acquisition and control device, a linear module, an electromagnetic disturbance simulator, and an upper computer. The data acquisition and control device is in a data connection to the linear module, the electromagnetic disturbance simulator, and the upper computer. The linear module includes a grating ruler; and the linear module is disposed on the numerical control machine tool to measure location data of the sliding table of the numerical control machine tool and transmit the location data to the data acquisition and control device. The electromagnetic disturbance simulator is configured to generate and transmit an electromagnetic signal to the numerical control system. The data acquisition and control device is configured to read the location data in real time and transfer the real-time location data to the upper computer.

Processing system for standardization and abstraction of registers measured by measuring devices (1), which comprise processing means of measured registers (5) received for generating processed registers (5a) storable in a storage database (6) of processed registers, characteristics schemes (7a) of separate models of measuring device (1), which comprise at least one module (9) and at least one submodule (10) assigned to the said module (9) on the basis of its functioning mode (17a), each module (9) being allotted to at least one memory position of a measuring device model (1), associated with a single measuring point and assigned to at least one category map (8a) in which a submodule (10) is related to a category variable, with assignment tables (16) of category variables, mapping means (11) with assignment means (12) and transformation means (13) provided for transforming values of each measured register (1a) into values of processed registers (5a), expressed in the pre-established equivalent unit of measurement assigned to the corresponding submodule (10). The assignment means (12) are designed for assigning to each measured register (1a) read in the memory position (18a) corresponding to a submodule (10), the category variable with which the submodule is related in the assignment table (16).

The present disclosure provides a method for accelerating remote control of a measurement application device, the method comprising receiving a control command for the measurement application device, the control command being received in a text-based format that uses a predetermined character encoding for encoding the command text, mapping the received control command to a command identifier, and transmitting the command identifier to the measurement application device.