A device installed in a vehicle including a first thermal circuit, a second thermal circuit, and a third thermal circuit, is configured to arbitrate a heat request of the first thermal circuit, a heat request of the second thermal circuit, and a heat request of the third thermal circuit. The device is configured to acquire a heat absorption amount requested by the first thermal circuit, the second thermal circuit, and the third thermal circuit, and configured to set, as a target value of a transfer heat amount in which heat exchange is performed between the second thermal circuit and the third thermal circuit, a larger one of a heat dissipation amount requested by the second thermal circuit and a heat amount difference in which a heat dissipation amount requested by the third thermal circuit is subtracted from a heat absorption amount requested by the first thermal circuit.

An automation system includes a first control facility with a first fieldbus connection, a second control facility with a second fieldbus connection, a fieldbus, a peripheral board with at least one I/O peripheral module, wherein the peripheral board has an interface module with a third fieldbus connection, where the interface module has at least one I/O module which stores interconnection information featuring an assignment of input/outputs of the I/O peripheral module(s) to the control facilities, where the interface module additionally has a virtual I/O module, in which an output region is assigned to the first control facility, and furthermore an input region is assigned to the second controller, and where the virtual I/O module is configured such that the output data is copied from the output region of the first control facility into the input region as input data for the second control facility.

The present invention discloses a programmable controlled intelligent cooking machine which has an electrical control device and an automatic ingredient feeding device connected with the electrical control device; the automatic ingredient feeding device is adapted for receiving a standard package box with a plurality of compartments stocked with ingredients; the electrical control device is adapted for receiving preset recipe command and sending corresponding control command according to the recipe command; the automatic ingredient feeding device is adapted for providing major ingredients and accessory ingredients stocked in respective compartments of the standard package box according to a preset feeding sequence in the received corresponding control command; the combinations of feeding sequence for each Chinese dish can change. The present invention further discloses a feeding and cooking control method of a programmable controlled intelligent cooking machine.

A method includes: receiving a mathematical model of a control system, with state variables and control parameters; discretizing at least a part of a space to obtain a set of tuples; determining for each tuple at least one successor state; obtaining an initial winning set of tuples; determining an updated winning set of tuples, including comparing the at least one successor state with the initial winning set of tuples, where the comparison is distributed over available processing elements by choosing one processing element from the available processing elements for each tuple to perform the comparison and where the available processing elements are used simultaneously at least in part; repeating the determination of the updated winning set of tuples to obtain a new updated winning set of tuples if a convergence measure does not meet a criterion, and constructing a controller for the control system from the new updated winning set.

Disclosed are methods of advanced process control (APC) for particular processes. A particular process (e.g., a photolithography or etch process) is performed on a wafer to create a pattern of features. A parameter is measured on a target feature and the value of the parameter is used for APC. However, instead of performing APC based directly on the actual parameter value, APC is performed based on an adjusted parameter value. Specifically, an offset amount (which is previously determined based on an average of a distribution of parameter values across all of the features) is applied to the actual parameter value to acquire an adjusted parameter value, which better represents the majority of features in the pattern. Performing this APC method minimizes dimension variations from pattern to pattern each time the same pattern is generated on another region of the same wafer or on a different wafer using the particular process.

Heating and cooling systems at various geographical locations are controlled by a central energy management service unit to maintain comfortable indoor temperatures. In some weather conditions, people may intuitively prefer a slightly warmer or cooler indoor temperature. In systems equipped with environmental learning capabilities, an apparent outdoor temperature is determined based on the geographic location itself, the season at the geographic location, the forecasted actual temperature, and one or more seasonal weather factors such as wind velocity or humidity. The apparent temperature and a trained machine learning system are used to select an automated schedule for the geographic location to be directly transmitted to devices at the location. The automated schedule can vary from typical schedules by causing the heating and cooling systems to maintain a temperature that is slightly warmer or cooler than typical indoor temperatures.

A system and method for facilitating inspection of fire alarm systems includes a graphical user interface rendered on a touchscreen display of a mobile computing device receiving selections of inspection results. The graphical user interface includes a testing pane, which indicates devices that are currently being tested, and a selection pane, which indicates devices yet to be tested. The devices indicated by the selection pane are filtered according to the inferred location of the inspector or the inferred order of test. Selection of devices indicated by the selection pane results in those devices being indicated by the testing pane. Results of inspections of the devices indicated by the testing pane are then selected by the touchscreen display detecting gestures (e.g. swipes toward the left or right) corresponding to different results. The results are sent to a connected services system and stored in a connected services database.

A production system, including an engineering device configured to set a higher-level control device capable of controlling a control device configured to control one or more industrial machines, wherein the engineering device is configured to: display a name of each of a plurality of variables stored in the higher-level control device; receive specification of a variable to be subjected to at least one of collection or rewriting from among the plurality of variables; and perform setting of the at least one of the collection or rewriting of the specified variable.

A method of commissioning a plurality of controllers includes identifying a plurality of controllers that are operably coupled to a network in a building management system. Each of the plurality of controllers are configured to control one or more of a plurality of building management system components within a building management system. A first controller is selected as a source controller. Two or more of the remaining controllers are selected as target controllers. A synch operation is initiated that synchs the control logic of the source controller with each of the two or more target controllers over the network, resulting in each of the two or more target controllers having the control logic of the source controller. The source controller and the two or more target controllers are subsequently used to control one or more respective building management system components of the building management system.

Various embodiments include a method for automatic programming. The method may include: receiving a user's request to create a first global parameter of a specific type by detecting the user's dragging a control corresponding to the specific type from a first user interface and dropping the control on a second user interface; displaying a first popup window for editing the first global parameter on the second user interface; receiving the user's editing operations on the first global parameter in the first popup window; creating the first global parameter according to the user's editing operations; and displaying a new added first card of the first global parameter in a list of global parameters on a third user interface.