Abstract: A menu selection technique is based on orientation of a companion module used in a flexible load management (FLM) system. The FLM system includes a load center that utilizes circuit breakers in combination with companion modules (i.e., intelligent controllers). Each companion module has a graphical display as well as a push button included on a face of the module as an input device used to display and input information including icons, buttons, controls, messages, status, menus or other desired text on a user interface (UI) to enable a user to configure and operate the companion module. The companion module also includes an accelerometer configured to detect a gravitational orientation (i.e., a first orientation and an opposite or upside-down orientation) and movement of the module and, in response, generate a signal that is translated to a corresponding change in orientation of the information displayed on the UI, particularly when the companion module inserted into the load center.

Abstract: In one embodiment, an architecture for redundant control of wireless devices (e.g., wireless light fixtures, wireless light strips, wireless window shades, or other wireless devices) of a home automation system is provided that uses a combination of WLAN and WPAN communication. During normal operation of the home automation system, control commands generated in response to user input in a control application (app) on a control device (e.g., a remote control, mobile device, or other electronic device) are transmitted via a WLAN (e.g., Wi-Fi) to a bridge device (e.g., a lamp module or wireless keypad) proximate to the wireless device, which forwards the commands over a WPAN (e.g., BLE) to the wireless device. In the absence of an available WLAN connection (e.g., due to failure, prior to its configuration, etc.), the control device may send control commands via the WPAN (e.g., BLE) directly to the wireless device.

Abstract: In accordance with one aspect of the invention, an automation control device, such as a host or hub, is provided with functionality so that it becomes a multi-role automation control device. One such multi-role automation control device produces an on screen display which enables a user to select predetermined lighting scenes or television channels, and to control other devices.

Abstract: In accordance with one aspect of the invention, an automation control device, such as a host or hub, is provided with functionality so that it becomes a multi-role automation control device. The multi-role automation control device is capable of controlling an expanded variety of “smart” or other devices. The multi-role automation control device may be implemented using a variety of underlying devices including a host, hub, soundbar, “smart” thermostat, “smart” amplifier, audio speaker, or other device.

Abstract: A flexible load management (FLM) system and technique adaptively monitors and manages power consumption of a premises. The FLM system includes a virtual critical load panel (vCLP) that utilizes circuit breakers in combination with companion modules (i.e., intelligent controllers) to vary a prioritization arrangement of loads in the premises by time of day, season or even dynamically. The vCLP is a prioritized enumeration (i.e., prioritization) of the loads within the premises, wherein the loads are considered sufficiently important such that they are protected by a local power source. The vCLP is dynamically configurable by a user in real time according to an instantaneous demand for the prioritized loads that is used to determine a number of branch circuits associated with the loads that is able to be powered-on at any time.

Abstract: In one embodiment, a user-navigable 3-D virtual room-based user interface for a home automation system is provided. A control app renders and displays the user-navigable 3-D virtual room from a perspective defined by a virtual camera, wherein the control app renders the user-navigable 3-D virtual room based on data from at least one of a plurality of 2-D images of the physical room captured from different respective positions in the physical room. In response to an explicit navigation command or implicit action, the control app alters a position or orientation of the virtual camera. The control app re-renders and displays the user-navigable 3-D virtual room from a new perspective defined by the altered position or orientation, wherein the new perspective does not coincide with the position in the physical room from which any of the 2-D images were captured, by blending data from multiple 2-D images captured from different positions.

Abstract: In one embodiment, a user-navigable, three-dimensional (3-D) virtual room-based user interface for a home automation system is provided. Each user-navigable 3-D virtual room shows a substantially photo-realistic depiction of a corresponding physical room of the structure, including substantially photo-realistic depictions of boundaries of the physical room, furnishings present in the physical room, and devices present in the physical room that are under the control of the home automation system. A user may use explicit navigation commands or implicit actions to navigate within the user-navigable 3-D virtual room, moving a virtual camera in 3-D space to view the virtual room from different perspectives. By interacting with (e.g., touching, clicking on, etc.) substantially photorealistic depictions of the devices within the user-navigable 3-D virtual room, a user may is indicate changes to the state of corresponding devices in the physical room.

Abstract: A technique enables microgrid switchover using zero cross detection. A flexible load management system includes a virtual critical load panel (vCLP) that utilizes circuit breakers in combination with companion modules configured to sense power provided to one or more loads to identify zero-crossings. When a preconfigured number of consecutive, missed zero-crossings is detected, the companion module is alerted as to potential main power loss and transitions to a virtual critical load (vCL) mode for load adjustment prior to operation under local power. Upon detection of main power loss, the companion module is configured for load activation (or deactivation) via states of one or more vCL bits that configure each load for either ON or OFF state when operating under local power.

Abstract: A menu selection technique is based on orientation of a companion module used in a flexible load management (FLM) system. The FLM system includes a load center that utilizes circuit breakers in combination with companion modules (i.e., intelligent controllers). Each companion module has a graphical display as well as a push button included on a face of the module as an input device used to display and input information including icons, buttons, controls, messages, status, menus or other desired text on a user interface (UI) to enable a user to configure and operate the companion module. The companion module also includes an accelerometer configured to detect a gravitational orientation (i.e., a first orientation and an opposite or upside-down orientation) and movement of the module and, in response, generate a signal that is translated to a corresponding change in orientation of the information displayed on the UI, particularly when the companion module inserted into the load center.

Abstract: A technique enables microgrid switchover using zero cross detection. A flexible load management system includes a virtual critical load panel (vCLP) that utilizes circuit breakers in combination with companion modules configured to sense power provided to one or more loads to identify zero-crossings. When a preconfigured number of consecutive, missed zero-crossings is detected, the companion module is alerted as to potential main power loss and transitions to a virtual critical load (vCL) mode for load adjustment prior to operation under local power. Upon detection of main power loss, the companion module is configured for load activation (or deactivation) via states of one or more vCL bits that configure each load for either ON or OFF state when operating under local power.

Abstract: A power controller configured to fit in a circuit breaker panel powering one or more loads. The power controller is further configured to manage critical loads of the one or more loads each controlled by a component that is capable of being actuated by the power controller and operated from a smartphone via the power controller, wherein the critical loads need not be wired to a dedicated circuit breaker panel.

Abstract: A flexible load management (FLM) system and technique adaptively monitors and manages power consumption of a premises. The FLM system includes a virtual critical load panel (vCLP) that utilizes circuit breakers in combination with companion modules (i.e., intelligent controllers) to vary a prioritization arrangement of loads in the premises by time of day, season or even dynamically. The vCLP is a prioritized enumeration (i.e., prioritization) of the loads within the premises, wherein the loads are considered sufficiently important such that they are protected by a local power source. The vCLP is dynamically configurable by a user in real time according to an instantaneous demand for the prioritized loads that is used to determine a number of branch circuits associated with the loads that is able to be powered-on at any time.

Abstract: A power controller configured to fit in a circuit breaker panel powering one or more loads. The power controller is further configured to dynamically manage critical loads of the one or more loads each controlled by a component that is capable of being actuated by the power controller and operated from a smartphone via the power controller, wherein the critical loads need not be wired to a dedicated circuit breaker panel.

Abstract: A flexible load management (FLM) system and technique adaptively monitors and manages power consumption of a premises. The FLM system includes a virtual critical load panel (vCLP) that utilizes circuit breakers in combination with companion modules (i.e., intelligent controllers) to vary a prioritization arrangement of loads in the premises by time of day, season or even dynamically. The vCLP is a prioritized enumeration (i.e., prioritization) of the loads within the premises, wherein the loads are considered sufficiently important such that they are protected by a local power source. The vCLP is dynamically configurable by a user in real time according to an instantaneous demand for the prioritized loads that is used to determine a number of branch circuits associated with the loads that is able to be powered-on at any time.

Abstract: In one embodiment, a configuration application executing on a tablet computer or smartphone presents a configuration user interface on a touch screen for configuring a home automation system of a structure. A plurality of components of the home automation system that have wireless capabilities are detected. The configuration application receives an indication of a zone of the structure within which each component is located, the indication provided by the user dragging a representation of each component to a location provided in the configuration user interface. Based on the indication of the zone of the structure in which each component is located and the type of each component, automatically generate one or more user interface screens for accessing and controlling the components in each zone, where the automatically generated user interface screens are displayable during use of the home automation system.

Abstract: In one embodiment, graphical programming is used to configure a system of audio, video, lighting, HVAC and/or security components. Representations of components from a component library are displayed. Each representation of a component corresponds to a physical component that is available for inclusion in the system and associated with a corresponding component profile for that physical component that includes information regarding the component's capabilities. A selected plurality of representations of components from the component library are placed in a configuration workspace of the graphical user interface, to indicate their inclusion in the system. One or more realized services that the system is capable of providing are determined based on the selected plurality of components; and indications of the one or more realized services that the system is capable of providing are displayed to the user.

Abstract: A group of homes, businesses, or other electric power consuming premises are aggregated and commonly controlled to dynamically reduce loads in sufficient quantities, and with sufficient rapidity and duration, to participate as a market participant in the energy markets including participating as a peaking power plant. While the amount of reduced power consumption for a single premises is typically quite small, the total reduced consumption of an aggregation of just a few thousand homes or businesses may be on the order of hundreds of kilowatts. A premises power controller in conjunction with intelligent circuit breakers, which may include dimmers, enable dynamic management of individual loads in each premises.

Abstract: In one embodiment, a user-navigable, three-dimensional (3-D) virtual room-based user interface for a home automation system is provided. Each user-navigable 3-D virtual room shows a substantially photo-realistic depiction of a corresponding physical room of the structure, including substantially photo-realistic depictions of boundaries of the physical room, furnishings present in the physical room, and devices present in the physical room that are under the control of the home automation system. A user may use explicit navigation commands or implicit actions to navigate within the user-navigable 3-D virtual room, moving a virtual camera in 3-D space to view the virtual room from different perspectives. By interacting with (e.g., touching, clicking on, etc.) substantially photorealistic depictions of the devices within the user-navigable 3-D virtual room, a user may is indicate changes to the state of corresponding devices in the physical room.

Abstract: In one embodiment, an architecture for redundant control of wireless devices (e.g., wireless light fixtures, wireless light strips, wireless window shades, or other wireless devices) of a home automation system is provided that uses a combination of WLAN and WPAN communication. During normal operation of the home automation system, control commands generated in response to user input in a control application (app) on a control device (e.g., a remote control, mobile device, or other electronic device) are transmitted via a WLAN (e.g., Wi-Fi) to a bridge device (e.g., a lamp module or wireless keypad) proximate to the wireless device, which forwards the commands over a WPAN (e.g., BLE) to the wireless device. In the absence of an available WLAN connection (e.g., due to failure, prior to its configuration, etc.), the control device may send control commands via the WPAN (e.g., BLE) directly to the wireless device.

Abstract: An energy management system interoperates with an automation system to provide integrated control over essentially all power-consuming, power-generating, and power storage devices in a home or other environment. The energy management system provides configurable energy management scenes in which one or more values, each representing a desired operating condition, are associated with some or all of the loads of a home, business or other environment. Different energy management scenes may be configured for different environmental conditions including season, day of week, time of day, grid status, battery condition, and generator condition among others.