Systems and methods for detecting and accommodating for loss of a torque signal of a gas turbine engine are described herein. An engine deterioration offset may be determined while the torque signal of the engine is available. Then, in the event that the torque signal is lost, a predicted operating offset may be determined. A synthesized torque signal may be generated when the torque signal is lost at least in part from the engine deterioration offset and the predicted operating offset.

A control device includes a processor wherein the processor is configured to: receive designation of one or more frequency components, generate one or more second control signals obtained by reducing at least one of the frequency components from a first control signal, generate one or more third control signals obtained using two control signals among the first control signal and the one or more second control signals, output one control signal among the first control signal, the one or more second control signals, and the one or more third control signals, and generate and output a driving signal to drive a robot based on the one control signal.

One embodiment of the present invention can be characterized as a method for controlling a multi-axis machine tool that includes obtaining a preliminary rotary actuator command (wherein the rotary actuator command has frequency content exceeding a bandwidth of a rotary actuator), generating a processed rotary actuator command based, at least in part, on the preliminary rotary actuator command, the processed rotary actuator command having frequency content within a bandwidth of the rotary actuator and generating a first linear actuator command and a second linear actuator command based, at least in part, on the processed rotary actuator command. The processed rotary actuator command can be output to the rotary actuator, the first linear actuator command can be output to a first linear actuator and the second linear actuator command can be output to a second linear actuator.

One embodiment of the present invention can be characterized as a method for controlling a multi-axis machine tool that includes obtaining a preliminary rotary actuator command (wherein the rotary actuator command has frequency content exceeding a bandwidth of a rotary actuator), generating a processed rotary actuator command based, at least in part, on the preliminary rotary actuator command, the processed rotary actuator command having frequency content within a bandwidth of the rotary actuator and generating a first linear actuator command and a second linear actuator command based, at least in part, on the processed rotary actuator command. The processed rotary actuator command can be output to the rotary actuator, the first linear actuator command can be output to a first linear actuator and the second linear actuator command can be output to a second linear actuator.

A device test method performed in a substrate test apparatus which includes a mounting table for mounting thereon a substrate on which a device having an electrode is formed, the mounting table being movable by a X-direction motor and a Y-direction motor, and a probe card arranged to face the mounting table. A measuring electrode is arranged to correspond to the electrode of the device, the probe card has a probe that is engageable with the measuring electrode, and the X-direction motor or Y-direction motor generates torque to keep the mounting table from moving when measuring an electrical characteristic of the device. In the device test method, after the probe is engaged with the measuring electrode, when measuring an electrical characteristic of the device, the maximum value of the torque generated by the X-direction motor or Y-direction motor is limited to a predetermined value or less.