Abstract: A thermostat assembly includes a thermostat and a trim ring. The thermostat includes a user interface, a thermostat housing having a front portion with a front portion side wall and a back portion with a back portion side wall, the back portion side wall being offset from the front portion side wall, and a controller disposed within the thermostat housing and operably coupled to the user interface, the controller configured to accept input from a user via the user interface and provide one or more control signals to control the HVAC system. The trim ring includes an outer surface that transitions from a larger back side profile to a smaller front side profile. A front side of the trim ring includes a thermostat recess that is configured to receive at least part of the back portion of the thermostat.

Abstract: A building management system comprising a plurality of sensors, each sensor of the plurality of sensors configured to detect a condition of the building is disclosed. The system may further comprise a memory for storing one or more events, each event configured to identify an action from a sequence of sensed conditions, a communications module configured to communicate with a remote device over a network, and a controller operatively coupled to the first sensor, the second sensor, the memory, and the communications module. The controller may be configured to compare the plurality of sensed conditions to the one or more events to identify an action and determine what, if any response is required, and if a response is required, provide a notification to the remove device via the communications module.

Abstract: A monitoring system for monitoring a status of a building comprising a first sensor configured to detect a first condition in the space and a second sensor configured to detect a second condition in the space is disclosed. The system may further comprise a memory for storing one or more rules each configured to identify one or more issues in the space based on the first and/or second conditions in the space and a communications module configured to communicate with a remote device over a network. A controller may be configured to apply the one or more rules to the first and second detected conditions in the space to identify the one or more issues and provide a notification to the remote device via the communications module.

Abstract: A building monitoring system includes a first sensor configured to detect a first condition in the space, a second sensor configured to detect a second condition in the space, and a robotic sentinel. The robotic sentinel includes a memory for storing one or more rules each configured to identify an alert condition for the space based on the first and/or second conditions in the space, a communications module configured to communicate with a remote device over a network, and a controller operatively coupled to the sensors, the memory, and the communications module. The controller is configured to apply the one or more rules to the first and second detected conditions in the space to identify one or more alert conditions and determine what action is required by the robotic sentinel, and if action is required, command the robotic sentinel to travel to a location of the alert condition.

Abstract: A pet monitoring system comprising a first sensor configured to detect a first condition in the space and a second sensor configured to detect a second condition in the space is disclosed. The system may further comprise a memory for storing one or more rules each configured to identify an alert condition for a pet in the space based on the first and/or second conditions in the space, a communications module configured to communicate with a remote device over a network, and a controller. The controller is configured to apply the one or more rules to the first and second detected conditions in the space to identify one or more alert conditions and determine what, if any, action is required by an owner or caretaker of the pet, and if action is required, provide an alert to the remote device via the communications module.

Abstract: A pet monitoring system comprising a first sensor configured to detect a first condition in the space and a second sensor configured to detect a second condition in the space is disclosed. The system may further comprise a memory for storing one or more rules each configured to identify an alert condition for a pet in the space based on the first and/or second conditions in the space, a communications module configured to communicate with a remote device over a network, and a controller. The controller is configured to apply the one or more rules to the first and second detected conditions in the space to identify one or more alert conditions and determine what, if any, action is required by an owner or caretaker of the pet, and if action is required, provide an alert to the remote device via the communications module.

Abstract: A monitoring system for monitoring a person comprising a first device configured to detect a first event in or near the building and a second device configured to detect a second event in or near the building is disclosed. The system may further comprise a memory for storing one or more rules each configured to identify an alert condition for a person in or near the building based on the first and/or second events in or near the building and a communications module configured to communicate with a remote device over a network. A controller may be configured to apply the one or more rules to the first and second detected events in the space to identify one or more alert conditions and determine what, if any, action is required, and if action is required, provide an alert to the remote device via the communications module.

Abstract: A wireless sensor assembly includes a wall plate that is configured to be secured to a wall of a building using either a threaded fastener or a releasable adhesive strip, the wall plate including an aperture therethrough for accommodating the threaded fastener and a recess on a back surface of the wall plate to accommodate at least part of the releasable adhesive strip. The wireless sensor assembly includes a sensor housing including a front housing region and a back housing region, the back housing region configured to be releasably secured to the wall plate, the back housing region including a recess that is configured to receive at least part of the wall plate when the back housing region is releasably secured to the wall plate.

Abstract: A method for automatically generating an HVAC schedule for a building includes storing a thermal model for the building, the thermal model including an indication of the energy efficiency of an HVAC system of the building, receiving a weather forecast predicting future weather at the location of the building, receiving a cost estimate for energy that will be supplied to the HVAC system, receiving from a user a desired budget for a cost of operating the HVAC system over a future period of time, using the thermal model, the weather forecast, the cost estimate for energy and the desired budget of the user to generate an HVAC schedule covering the future period of time that is predicted to meet the desired budget of the user and controlling the HVAC system using the generated HVAC schedule.

Abstract: An HVAC controller includes a housing, a user interface and a controller that is operably coupled to the user interface and is configured to display a HOME screen on the user interface that provides the user with current system operating information and enabling the user to access a hierarchical menu structure for viewing and/or editing one or more settings of the HVAC controller. The hierarchical menu structure includes a plurality of menu branches each having two or more hierarchical menu levels with a leaf menu at the bottom of each branch, where for a first group of the leaf menus, the user must navigate “back” to return to the HOME screen while for a second group of the leaf menus, the user is returned to the HOME screen after the user indicates the user is done with the leaf menu, without having to wait for the timeout period.

Abstract: A wireless occupancy sensor that is configured to be deployed within a building space includes a sensor body, an occupancy sensor that is housed by the sensor body, a light emitting diode (LED) that is housed by the sensor body, a wireless transceiver that is housed by the sensor body and is configured to be in wireless communication with a remote device. A controller is housed by the sensor body and is operably coupled to the occupancy sensor, the LED and the wireless transceiver and is configured to receive via the wireless transceiver a request to illuminate the LED from the remote device and in response to receiving the request, illuminate the LED in order to help visually identify the wireless occupancy sensor in the building space.

Abstract: An HVAC controller is configured to receive signals from a plurality of sensors positioned in different spaces. The HVAC controller includes a controller that is configured to display one or more screens on a user interface that include a home screen including a selectable display element that indicates a number of the plurality of sensors that are currently being used by the controller in controlling the HVAC system. Upon selection of the selectable display element, the controller displays a sensor priority screen that includes a plurality of graphic constructs that each identify a building space and a current temperature for that building space. The controller is configured to control the HVAC system in accordance with the current temperature reported by each of the number of the plurality of sensors that are currently being used by the controller in controlling the HVAC system.

Abstract: The occupancy status of a building space may be determined by sensing an indication of motion in the building space, in response to sensing the indication of motion in the building space, starting an occupied time period having a length during which the building space is indicated as being occupied, determining a measure related to a number of subsequent sensed indications of motion in the building space during the occupied time period, and selectively adjusting the length of the occupied time period based on the measure related to the number of subsequent sensed indications of motion in the building space during the occupied time period.

Abstract: An HVAC controller is configured to automatically change between a HEAT mode and a COOL mode in accordance with a sensed temperature in the building structure, a HEAT temperature set point and a COOL temperature set point. The user is allowed to adjust the HEAT temperature set point and the COOL temperature set point, with the HVAC controller automatically adjusting one of the set points in response to the user making a change to the other of the other of the set points that violates a minimum deadband. If the user readjusts the user-adjusted set point in a way that no longer violates the minimum deadband, the HVAC controller will adjust the other set point back towards its previous setting.

Abstract: A thermostat assembly includes a thermostat and a trim ring. The thermostat includes a user interface, a thermostat housing having a front portion with a front portion side wall and a back portion with a back portion side wall, the back portion side wall being offset from the front portion side wall, and a controller disposed within the thermostat housing and operably coupled to the user interface, the controller configured to accept input from a user via the user interface and provide one or more control signals to control the HVAC system. The trim ring includes an outer surface that transitions from a larger back side profile to a smaller front side profile. A front side of the trim ring includes a thermostat recess that is configured to receive at least part of the back portion of the thermostat.