To monitor or control a machine, current operating signals are captured continuously, and a current operating state is measured continuously. On the basis of the captured operating, a simulated operating state is determined continuously by a concurrent simulator. In addition, upon detection of a difference between the simulated operating state and the measured operating state, a difference pattern that quantifies the deviation or a change in the measured operating state is compared with a plurality of specified difference types which are characteristic of a modification of the machine or a machine operation, and each of the difference types is assigned a difference-type-specific simulator variant. Depending on the result of the comparison, one of the difference types is then selected. On the basis of the simulator variant assigned to the selected deviation type, the concurrent simulator is adapted, and the machine is monitored or controlled using the adapted concurrent simulator.

To monitor or control a machine, current operating signals are captured continuously, and a current operating state is measured continuously. On the basis of the captured operating, a simulated operating state is determined continuously by a concurrent simulator. In addition, upon detection of a difference between the simulated operating state and the measured operating state, a difference pattern that quantifies the deviation or a change in the measured operating state is compared with a plurality of specified difference types which are characteristic of a modification of the machine or a machine operation, and each of the difference types is assigned a difference-type-specific simulator variant. Depending on the result of the comparison, one of the difference types is then selected. On the basis of the simulator variant assigned to the selected deviation type, the concurrent simulator is adapted, and the machine is monitored or controlled using the adapted concurrent simulator.

A method of operating an appliance includes performing at least one operating cycle of the appliance. The one more operating cycle include operating a mechanical component of the appliance according to a closed-loop control algorithm. The method may also include monitoring an output of the closed-loop control algorithm during the operating cycle of the appliance, such as throughout the operating cycle of the appliance. The method may further include detecting an abnormal output of the closed-loop control algorithm or determining that the output of the closed-loop control algorithm during the operating cycle of the appliance is an abnormal output.

A method of operating an appliance includes performing at least one operating cycle of the appliance. The one more operating cycle include operating a mechanical component of the appliance according to a closed-loop control algorithm. The method may also include monitoring an output of the closed-loop control algorithm during the operating cycle of the appliance, such as throughout the operating cycle of the appliance. The method may further include detecting an abnormal output of the closed-loop control algorithm or determining that the output of the closed-loop control algorithm during the operating cycle of the appliance is an abnormal output.

The present disclosure relates to a mechatronic assembly for positioning a member including a control unit and an actuator, the control unit including a control algorithm and a power bridge, the algorithm controlling the power bridge, the power bridge outputting a two-wire electric signal, the actuator including a polyphase brushless electric motor having N phases (N being or higher), binary probes for detecting the position of the rotor of the motor, and power switches suitable for supplying the N phases of the motor from the two-wire electric signal, and states of the power switches is controlled directly by a signal emitted by the detection probes.

The present disclosure relates to a mechatronic assembly for positioning a member including a control unit and an actuator, the control unit including a control algorithm and a power bridge, the algorithm controlling the power bridge, the power bridge outputting a two-wire electric signal, the actuator including a polyphase brushless electric motor having N phases (N being or higher), binary probes for detecting the position of the rotor of the motor, and power switches suitable for supplying the N phases of the motor from the two-wire electric signal, and states of the power switches is controlled directly by a signal emitted by the detection probes.

A personal digital ID device provides a digital identifier to a service for a predetermined duration in response to user interaction. The user interaction may include a button press. The personal digital ID device may be in the form of a bracelet, a key fob, or other form factor. The service may be provided by a mobile device, in the cloud, or elsewhere.

A personal digital ID device provides a digital identifier to a service for a predetermined duration in response to user interaction. The user interaction may include a button press. The personal digital ID device may be in the form of a bracelet, a key fob, or other form factor. The service may be provided by a mobile device, in the cloud, or elsewhere.

A driving safety controlling method is provided. The controlling method is running on a wearable device, a smart key and a vehicle. The control controlling method comprises steps: obtaining sensing data stored in a first storage unit of the wearable device; obtaining a unique identifier stored in a second storage unit of the smart key and controlling a first wireless communication unit of the smart key to transmit a high-frequency signal containing the unique identifier and the sensing data to the vehicle; obtaining a predefined identifier and a range from a third storage unit of the vehicle, comparing the unique identifier with the predefined identifier, and comparing the sensing data with the range; and controlling a prompt unit to generate a prompting when the unique identifier is determined to match with the predefined identifier and the sensing data is within the range.

In an apparatus, a determiner determines whether a two-MG frequency ratio of a first electrical frequency of a first MG to a second electrical frequency of a second MG is within a specific frequency-ratio range. The specific frequency-ratio range includes 1/6n where n is an integer excluding zero. An update-cycle controller controls an update cycle of a command voltage according to the determined result such that the update cycle during a specific drive of the first MG is longer than the update cycle during a usual drive of the first MG while a cycle of a carrier signal is maintained during both the usual and specific drives. The specific drive represents drive of the first MG while the two-MG frequency ratio is within the specific frequency-ratio range. The usual drive represents drive of the first MG while the two-MG frequency ratio is out of the specific frequency-ratio range.