A system and method for controlling movement of a door or other apparatus, such as to provide and restrict access to a chicken coop, including a plurality of input devices, a plurality of output devices, and a microprocessor configured on a circuit board to detect signals from the input devices, process the signals, and based upon predetermined logic generate and transmit output signals to the output devices. One of the input devices is a wireless smart switch remotely controlled by a user, which transmits electric current based upon user input such that when the user input indicates an intention that the apparatus move in a first direction, the switch will transmit electric current, and when the user input indicates an intention that the apparatus move in a second direction, the switch will stop transmitting electric current.

The present invention provides a home automation and concierge system and method for a community. A user may access an interface to control home systems and device or use the concierge service to purchase goods and services available for at home delivery. An example method of concierge comprises receiving, by a server computing device comprising an operation module, a request for service(s) and/or product(s) from a user. A ranking of providers capable of completing said request to said user is provided. A selected provider from the ranking of providers to complete the request from said user is received. Completion of the request by said selected provider is enabled.

Methods and systems for identifying and correcting abnormal electrical activity about a structure are provided. An electricity monitoring device may monitor electrical activity including transmission of electricity via an electrical distribution board to devices about the structure. Electrical activity may be correlated with respective electrical devices to build an electrical profile indicative of the structure's electricity usage. Based on the electrical profile, abnormal electrical activity may be identified and corrective actions may be taken to mitigate or prevent structural damage.

The present invention relates to a method for incident management of home automation equipment comprising at least one home automation device (D) and at least one central control unit (U), the method being implemented by a management unit (Sv) and comprising the following steps: a step (EDSv1) of receiving a diagnosis request concerning at least one central control unit (U) belonging to the home automation equipment or at least one home automation device belonging to the home automation equipment (St); a step (EDS3) of sending at least one diagnosis request message to the at least one central control unit (U) concerned by the diagnosis request or to the at least one central control unit (U) to which the at least one home automation device concerned by the diagnosis request is attached; a step (EDSv8) of receiving a diagnosis result coming from a central control unit (U); a step (EDSv9) of providing a diagnosis report to the maintenance user (USAV), comprising: information concerning the communication between the management unit and the home automation device or the central control unit concerned by the diagnosis request, and/or, if the home automation device or the central control unit can communicate such a result: the last known values of the state variables for the home automation devices (D) and for the central control units (U); and/or the results of commands or connection attempts initiated by the end user (UsrF).

A method for operating an industrial system, an apparatus, a computer program product, a computer-readable medium and method for synchronizing a system model with a real system, wherein a) a system model including at least one device model configured to calculate simulated output values and/or state values from simulated input values using mathematical functions and which is expanded with at least one mathematical function inverse to the at least one mathematical function is provided, b) at least one real output value and/or state value is provided, c) the at least one real output value and/or state value is supplied to the expanded device model, d) via the functions, at least one input value is back-calculated from the at least one real output value and/or state value, and e) the at least one back-calculated input value and/or a derived value is used to synchronize the system model with the real system.

A controller for a central plant having subplants operating to produce resources consumed by a building. The controller includes a processing circuit including a processor and memory storing instructions executed by the processor. The memory includes an offline rank generator that receives historical subplant allocation data and generates subplant ranks based on the historical subplant allocation data, each of the subplant ranks is associated with one of the subplants and defines a priority of each subplant with respect to production of a resource relative to other subplants that produce the resource. The memory also includes a high level optimizer that uses the subplant ranks associated with each of the subplants to determine resource allocation of the subplants according to the subplant ranks. The processing circuit is operates the subplants according to the resource allocation.

Embodiments of a software defined automation system that provides a reference architecture for designing, managing and maintaining a highly available, scalable and flexible automation system. In some embodiments, an SDA system can include a localized subsystem including a system controller node and multiple compute nodes. The multiple compute nodes can be communicatively coupled to the system controller node via a first communication network. The system controller node can manage the multiple compute nodes and virtualization of a control system on a compute node via the first communication network. The virtualized control system includes virtualized control system elements connected to a virtual network that is connected to a second communication network to enable the virtualized control system elements to control a physical control system element via the second communication network connected to the virtual network.

Methods and systems for homeowner-directed risk mitigation for damage to a property associated with insurance-related events are provided. A smart home controller may analyze data received from a plurality of smart devices disposed on, or proximate to, a property as well as data received from an insurance provider. If it is determined that an actual or potential risk of property damage exists, the smart home controller may transmit an alert to a homeowner detailing the risk. The homeowner may respond to the alert by transmitting an instruction to mitigate or prevent damage associated with the risk back to the smart home controller. Subsequently, the smart home controller may transmit information about the actual or potential risks and any homeowner-directed mitigative actions to an insurance provider. The insurance provider may interpret the transmitted data and perform insurance activities, such as providing discounts and adjusting an insurance policy associated with the property.

A building management system including one or more circuits configured to receive a selection of an object associated with one of a building system, a piece of equipment, or a space of one or more building systems, one or more pieces of equipment, and/or one or more spaces of a building; determine the one or more pieces of equipment related to the object and/or the one or more spaces related to the object; and generate a graphical user interface illustrating (i) a relationship of the object with (a) the one or more pieces of equipment related to the object and/or (b) the one or more spaces related to the object and/or (ii) a control path between the object and (a) the one or more pieces of equipment related to the object and/or (b) the one or more spaces related to the object.

A building management system including a system manager, a zone coordinator, and one or more zone controllers configured to monitor and control building zones. The system manager includes a system bus datalink having an active node table stored therein. The zone coordinator includes a second system bus datalink and a zone bus datalink. A system bus connects the first system bus datalink to the second system bus datalink. A zone bus connects the zone bus datalink to the one or more zone controllers. The active node table includes a plurality of nodes, each node representing a system bus device communicating on the system bus. The system manager is configured to monitor the active node table for new nodes and to identify a new system bus device communicating on the system bus in response to a determination that the active node table includes a new node.