A machine tool includes a machining chamber, an illuminator in the machining chamber, and an NC unit. The NC unit includes a manual execution unit for executing the machining operation via a pulse signal generated in response to operation of a manually operated part, and has a one-block stop mode in which the NC program is executed for one block and then stopped. A notification unit issues a notification of completion of the execution of one block of the NC program while the machining operation is executed manually using the manual execution unit in the one-block stop mode, and the notification unit includes the illuminator. A change in the illumination state of the illuminator enables an operator to observe the interior of the machining chamber continuously while being notified of the completion of the execution of the one block of the NC program.

Disclosed herein is a method of programming a monitor to process data from a new sensor having a selected location on a vehicle, where in the new sensor transmits a verification code and an identification code as well as said data. The subject monitor programming method basically comprises initiating a programming mode, entering the location of the new sensor, entering a subset of the new sensor's identification code; storing the location and subset, exiting the programming mode, initiating a verification mode, receiving the new sensor's verification code and identification code, recognizing the verification code, storing the identification code, exiting the verification mode, initiating a normal operation and display mode, comparing the new sensor's transmitted identification code with the stored identification code, and processing the data from the new sensor when the transmitted identification code matches the stored identification code.

A machine tool includes a machining chamber, an illuminator in the machining chamber, and an NC unit. The NC unit includes a manual execution unit for executing the machining operation via a pulse signal generated in response to operation of a manually operated part, and has a one-block stop mode in which the NC program is executed for one block and then stopped. A notification unit issues a notification of completion of the execution of one block of the NC program while the machining operation is executed manually using the manual execution unit in the one-block stop mode, and the notification unit includes the illuminator. A change in the illumination state of the illuminator enables an operator to observe the interior of the machining chamber continuously while being notified of the completion of the execution of the one block of the NC program.

Disclosed herein is a method of programming a monitor to process data from a new sensor having a selected location on a vehicle, where in the new sensor transmits a verification code and an identification code as well as said data. The subject monitor programming method basically comprises initiating a programming mode, entering the location of the new sensor, entering a subset of the new sensor's identification code; storing the location and subset, exiting the programming mode, initiating a verification mode, receiving the new sensor's verification code and identification code, recognizing the verification code, storing the identification code, exitng the verification mode, initiating a normal operation and display mode, comparing the new sensor's transmitted identification code with the stored identification code, and processing the data from the new sensor when the transmitted identification code matches the stored identification code.

A device for multi-energy field induced atomic-scale CNC machining in an environmental atmosphere comprises an electromagnetic shielding chamber and a control mechanism, wherein an environmental chamber is arranged in the electromagnetic shielding chamber, a workpiece platform is arranged at the bottom of the environmental chamber, and a nanotool driven by a nanotool actuator is arranged at the top of the environmental chamber, and a gas inlet and a gas outlet which are connected to the environmental chamber are formed in the electromagnetic shielding chamber; and the control mechanism is used for controlling the workpiece platform and the nanotool actuator and applying energy fields including a force field, a temperature field, an electric field, an optical field and a magnetic field. The device has the advantages of atomic precision, high efficiency, low cost and good universality.

According to the present embodiment, a control device comprises a first processor, a switching manager, and a second processor. The first processor is configured to execute control of a next control period on basis of control information having been changed during a current control period. The switching manager is configured to transmit to the first processor a switching notification for instructing switching to the first processor. The second processor is configured to use second software different from first software to be capable of executing control of a device by repeating a predetermined control period. The second processor uses at least the changed control information before a switching completion time as a time point where a currently processing control period ends to start control of the device in a next control period when control of the device in the next control period is executable.

A device for multi-energy field induced atomic-scale CNC machining in an environmental atmosphere comprises an electromagnetic shielding chamber and a control mechanism, wherein an environmental chamber is arranged in the electromagnetic shielding chamber, a workpiece platform is arranged at the bottom of the environmental chamber, and a nanotool driven by a nanotool actuator is arranged at the top of the environmental chamber, and a gas inlet and a gas outlet which are connected to the environmental chamber are formed in the electromagnetic shielding chamber; and the control mechanism is used for controlling the workpiece platform and the nanotool actuator and applying energy fields including a force field, a temperature field, an electric field, an optical field and a magnetic field. The device has the advantages of atomic precision, high efficiency, low cost and good universality.