According to an embodiment, a conversion device converts a first automaton into a second automaton, which both are weighted finite state automatons. The first automaton has a boundary of a path assigned with an input symbol, an appearance position of the boundary, and identifiers for identifying paths. The second automaton has path(s) except unnecessary path(s). The device includes a specifying unit and a search unit. The specifying unit is configured to specify, as a start position, a state of the head of a retrieved path in which a combined weight, which is obtained by adding an accumulated weight from an initial state to the state of the head of the retrieved path in the first automaton and a weight of the best path from the state of the head of the retrieved path to a final state, is best. The search unit is configured to search for a path in which a weight from the start position to a final state in the first automaton is best until reaching next boundary.

According to an embodiment, a conversion device converts a first automaton into a second automaton, which both are weighted finite state automatons. The first automaton has a boundary of a path assigned with an input symbol, an appearance position of the boundary, and identifiers for identifying paths. The second automaton has path(s) except unnecessary path(s). The device includes a specifying unit and a search unit. The specifying unit is configured to specify, as a start position, a state of the head of a retrieved path in which a combined weight, which is obtained by adding an accumulated weight from an initial state to the state of the head of the retrieved path in the first automaton and a weight of the best path from the state of the head of the retrieved path to a final state, is best. The search unit is configured to search for a path in which a weight from the start position to a final state in the first automaton is best until reaching next boundary.

Provided is a mode control method that includes obtaining a PWM signal; obtaining a duty cycle of the PWM signal; obtaining a target rotational speed of an electric pump based on the duty cycle of the PWM signal; in response to determining that the target rotational speed of the electric pump is equal to 0 and the target rotational speed of the electric pump remains equal to 0 for the set duration, entering the sleep mode by the microcontroller; and in response to determining that the target rotational speed of the electric pump is not equal to 0 or the target rotational speed of the electric pump does not remain equal to 0 for the set duration, entering the working mode by the microcontroller. Further provided are a mode control system, an electronic device and a storage medium.

Provided is a mode control method that includes obtaining a PWM signal; obtaining a duty cycle of the PWM signal; obtaining a target rotational speed of an electric pump based on the duty cycle of the PWM signal; in response to determining that the target rotational speed of the electric pump is equal to 0 and the target rotational speed of the electric pump remains equal to 0 for the set duration, entering the sleep mode by the microcontroller; and in response to determining that the target rotational speed of the electric pump is not equal to 0 or the target rotational speed of the electric pump does not remain equal to 0 for the set duration, entering the working mode by the microcontroller. Further provided are a mode control system, an electronic device and a storage medium.

A sauna operational state control system has a controller comprising an I/O interface interfacing a heater, a state controller configurable in a plurality of sauna operational states including standby and heating states and a heater controller which operably controls the heater via the I/O interface. The state controller is configured to receive schedule data, calculate a session start time according to the schedule data, calculate a heating time period, and calculate a heating time period start time according to the session start time and the heating time period. The state controller monitors time and, at the heating time period start time, enters the heating state wherein the heater controller operates the heater. As such, the present state controller allows for time-based anticipatory operational state control of a sauna including ensuring reaching of temperature setpoint parameters.

The present application belongs to the technical field of smart appliances, and relates to a delivery control method, which comprises the steps of: transferring goods to a delivery device according to the number of personnel; and controlling the delivery device to move to a set target position. By adopting the method, the corresponding quantity of goods can be configured based on the number of personnel, and moved to the target position by the delivery device, so that the required quantity of goods can be distributed to the target position without requiring a user to give control instructions, thereby providing convenience for the user; meanwhile, the required quantity can be distributed at a time, thereby improving the distribution efficiency and improving the user experience. The present application further discloses a delivery control device and a delivery device.

A device includes a plurality of blocks. Each block of the plurality of blocks includes a plurality of rows. Each row of the plurality of rows includes a plurality of configurable elements and a routing line, whereby each configurable element of the plurality of configurable elements includes a data analysis element comprising a plurality of memory cells, wherein the data analysis element is configured to analyze at least a portion of a data stream and to output a result of the analysis. Each configurable element of the plurality of configurable elements also includes a multiplexer configured to transmit the result to the routing line.

According to a method according to the invention for controlling at least one manipulator, in particular a robot, a plurality of control commands (P, B, F) are worked through, in that in a state machine (ZM) the respective command runs through an active state (-A), wherein in a state machine at least one control command runs through a preliminary state (-E) that is placed ahead of its active state and/or a post-operational state (-P) that is placed after its active state, and/or a plurality of control commands are processed at the same time.

According to a method according to the invention for controlling at least one manipulator, in particular a robot, a plurality of control commands (P, B, F) are worked through, in that in a state machine (ZM) the respective command runs through an active state (-A), wherein in a state machine at least one control command runs through a preliminary state (-E) that is placed ahead of its active state and/or a post-operational state (-P) that is placed after its active state, and/or a plurality of control commands are processed at the same time.

Example embodiments of the present disclosure include an integration system comprising a machine-readable medium (e.g., a memory) and a reconfigurable logic device (e.g., an FPGA). The machine-readable medium stores configuration data that configures the reconfigurable logic device to include a first channel adapter, a first message processor, a second message processor, a message channel, and a second channel adapter. The first channel adapter is configured to receive input data written by a first message endpoint. The first message processor is configured to perform a first message processing operation on messages received from the first channel adapter that include the input data. The second message processor is configured to perform a second message processing operation on messages received from the first message processor. The message channel facilitates communication between the first and second message processors. The second channel adapter is configured to forward output data to a second message endpoint for further processing.