Abstract: On a first level of the wireless building automation architecture, sensors and associated actuators communicate directly. The sensor performs control processes appropriate for the sensor and regardless of the type of actuator being used. The actuator performs control processes specific to the actuator regardless of the type of sensor being used. By direct wireless communication between sensors and actuators, the opportunity for a failed communications link using a hub and spoke arrangement may be avoided. Communication redundancy is provided by receiving the outputs of sensors at a controller, such as a controller on a second high speed or high bandwidth tier of the architecture. Regional control is implemented in the higher level tier. The higher level tier may override or control operation of components of the lower level tier as needed. The distributed control processing allows for more convenient room level integration.

Abstract: In a building environment, a distance associated with a building automation device is determined as a function of an interval or an inserted time delay between a wireless transmission of a signal and wireless reception of another signal. For example, a two-way communication is provided with an automatic interval or a desired time delay inserted before responding to a received transmission. By using two-way transmissions, the building automation devices may be free of clock synchronization. Acoustic signals may be used in a building environment to determine a distance. The building automation device may also use radio frequency information for communicating with other devices.

Abstract: A wireless automation device monitors a condition and wirelessly reports an event over an automation network in response to detecting a change in the condition. The condition is sampled at a variable periodic interval, and the event reported during intervals when a change in the condition is determined. The change may be determined according to detecting a value for the condition outside a variable range. The change may also be determined according to detecting differences in the value from values detected in prior intervals. The range and the periodic interval may vary according to an analysis of multiple samples of the condition.

Abstract: On a first level of the wireless building automation architecture, sensors and associated actuators communicate directly. The sensor performs control processes appropriate for the sensor and regardless of the type of actuator being used. The actuator performs control processes specific to the actuator regardless of the type of sensor being used. By direct wireless communication between sensors and actuators, the opportunity for a failed communications link using a hub and spoke arrangement may be avoided. Communication redundancy is provided by receiving the outputs of sensors at a controller, such as a controller on a second high speed or high bandwidth tier of the architecture. Regional control is implemented in the higher level tier. The higher level tier may override or control operation of components of the lower level tier as needed. The distributed control processing allows for more convenient room level integration.

Abstract: In a building environment, a distance associated with a building automation device is determined as a function of an interval or an inserted time delay between a wireless transmission of a signal and wireless reception of another signal. For example, a two-way communication is provided with an automatic interval or a desired time delay inserted before responding to a received transmission. By using two-way transmissions, the building automation devices may be free of clock synchronization. Acoustic signals may be used in a building environment to determine a distance. The building automation device may also use radio frequency information for communicating with other devices.

Abstract: A method for auto-addressing a device in communication with a controller is disclosed. The method includes communicating a pulse from a first contact of a controller, receiving the pulse at a second contact of a device in communication with the controller, communicating a number of pulses from a first contact of the device, and receiving the number of pulses at a second contact of the controller, wherein the number of pulses indicates a number of devices in communication with the controller.

Abstract: An automation component configured for wireless communication within a building automation system includes a wireless communications component, a processor in communication with the wireless communications component, and a memory in communication with the processor. The memory configured to store computer readable instructions which are executable by the processor to process a change-of-value message received via the wireless communications component, generate a change-of-value update in response to the change-of-value message, and communicate the change-of-value update via the wireless communication component. This change-of-value can occur in a polled (pull) fashion, or in a pushed (when it occurs) fashions.

Abstract: On a first level of the wireless building automation architecture, sensors and associated actuators communicate directly. The sensor performs control processes appropriate for the sensor and regardless of the type of actuator being used. The actuator performs control processes specific to the actuator regardless of the type of sensor being used. By direct wireless communication between sensors and actuators, the opportunity for a failed communications link using a hub and spoke arrangement may be avoided. Communication redundancy is provided by receiving the outputs of sensors at a controller, such as a controller on a second high speed or high bandwidth tier of the architecture. Regional control is implemented in the higher level tier. The higher level tier may override or control operation of components of the lower level tier as needed. The distributed control processing allows for more convenient room level integration.

Abstract: A method of performing diagnostics on a first hierarchical device operable within a building automation system is disclosed. The method includes compiling application code configured to control the first hierarchical device such that the application code includes a plurality of internal variables, providing a diagnostic module configured to monitor the plurality of internal variables, collecting internal variable diagnostic data related to the monitored plurality of internal variables, uploading the collected internal variable diagnostic data to a second hierarchical device, performing, at the second first hierarchical device, a layered diagnostic analysis on the internal variable diagnostic data, and identifying a first hierarchical device problem based on the analyzed internal variable diagnostic data.

Abstract: In building automation architectures, components may be associated through physical communications paths and at a different level through building automation applications. Building automation applications implement control processes for a building function. Due to changing needs, such as a failure of a physical communications path or the addition or removal of components, the building automation application may be more appropriately performed in a different device. By dynamically positioning or determining a processor for implementing a building automation application, an architecture or network may more optimally control building functions, such as by requiring less user input, more rapid response and/or avoiding building function failures.

Abstract: A network of wireless radios automatically conserves energy, directs the operation of equipment, and locates assets and personnel. The network may identify changes in the occupancy of a building area and automatically alter the building environment according to predetermined settings, personal preferences, or unexpected conditions. The wireless radios also may include sensors that monitor specific parameters, the parameters may relate to building environment conditions or operating equipment. The network may automatically alter the operating building equipment in response to the parameters received. The wireless radios also may be portable and mounted upon movable items, such as personal identification devices, office furniture, equipment, containers, or other assets. The network may locate the movable items within a building based upon signals received from the wireless radios. The network also may track the movement of the movable items within a building. The wireless radios may operable as a mesh network.

Abstract: An automation component configured for optimized wireless communication within a building automation system is disclosed. The automation component includes a wireless communications component, a processor in communication with the wireless communications component, a memory in communication with the processor, the memory configured to store computer readable instructions which are executable by the processor. The computer readable instructions being programmed to process at least one communication variable received via the wireless communications component; to optimize a communication or radio transmit power level associated with the wireless communication component, wherein the optimized communication power level is a function of the at least one communication variable; and an adjustment of the communication power level associated with the wireless communication component based on the optimized communication power level.

Abstract: In a building environment, a distance associated with a building automation device is determined as a function of an inserted time delay between a wireless transmission of a signal and wireless reception of another signal. For example, a two-way communication is provided with a time delay inserted before responding to a received transmission. By using two-way transmissions, the building automation devices may be free of clock synchronization. Acoustic signals may be used in a building environment to determine a distance. The building automation device may also use radio frequency information for communicating with other devices. Communication between devices allows a controller to coordinate the determination of distances associated with different devices within a network, such as through transmission of a test signal and assigning distance measurement operations to devices that receive the test signal with sufficient strength or other characteristics.

Abstract: In a building environment, a coordinate location or local position of various automation devices is determined. The location or position may be determined using a wireless distance measurement. Applications, associations, and utilizations for wireless building automation devices are developed according to location and/or positions of the devices. The position may be determined based on techniques for determining a relative distance of device from other devices and/or a reference point. The position may be mapped to the coordinate location within the building. Devices may be grouped, a commissioning table of binding associations between devices may be created, and addresses assigned to the building automation devices according to the location, the position and/or distances between the devices. Associations between devices may be established and updated based on proximity of the devices. Device communication also may be controlled according to position and distance information.

Abstract: In a building environment, a distance associated with a building automation device is determined as a function of an inserted time delay between a wireless transmission of a signal and wireless reception of another signal. For example, a two-way communication is provided with a time delay inserted before responding to a received transmission. By using two-way transmissions, the building automation devices may be free of clock synchronization. Acoustic signals may be used in a building environment to determine a distance. The building automation device may also use radio frequency information for communicating with other devices. Communication between devices allows a controller to coordinate the determination of distances associated with different devices within a network, such as through transmission of a test signal and assigning distance measurement operations to devices that receive the test signal with sufficient strength or other characteristics.

Abstract: In a building environment, coordinate locations for building automation devices is determined. The location may be based on triangulation methods for determining coordinate locations from wireless distance information for the building automation devices. Erroneous determinations for coordinate location are identified and a corrected coordinate location determined according to distance determinations.

Abstract: An automation component configured for wireless communication within a building automation system is disclosed. The automation component includes a communication module having a communication port, and a wireless communication component. The automation component further includes a processor in communication with the communication module, a memory in communication with the processor, the memory configured to store computer readable instructions which are executable by the processor. The computer readable instructions are programmed to receive a component identifier via the communications port, generate a binding request based on the received component identifier, and communicate the binding request via the wireless communication component.

Abstract: An automation component configured for wireless communication within a building automation system is disclosed. The automation component includes a wireless communications component, a processor in communications with the wireless communications component and a memory in communication with the processor, the memory configured to stored computer readable instructions which are executable by the processor. The computer readable instructions are programmed to generate a binding request including a device identifier, broadcast the binding request via the wireless communications component, and establish a binding relationship based on a received response to the binding request. A method for binding an automation component within a building automation system is further disclosed.

Abstract: A method for wireless communication within a building automation system is disclosed. The method includes establishing a communication connection between a wireless device and a controller, and communicating an upgrade packet to the wireless device from the controller. The method further includes executing the upgrade packet to upgrade the wireless device or a building automation component connected to the wireless device. A building automation system is further disclosed. The system includes a controller configured to provide a software module, and a wireless transceiver in communication with the controller and configured to communicate the software module. The system further includes a wireless device in communication with the wireless transceiver and configured to receive the software module to upgrade the wireless device.

Abstract: In building automation architectures, components may be associated through physical communications paths and at a different level through building automation applications. Building automation applications implement control processes for a building function. Due to changing needs, such as a failure of a physical communications path or the addition or removal of components, the building automation application may be more appropriately performed in a different device. By dynamically positioning or determining a processor for implementing a building automation application, an architecture or network may more optimally control building functions, such as by requiring less user input, more rapid response and/or avoiding building function failures.