Abstract: System and method for designing and deploying a building-related service in a building automation management system (BAMS) based on a software-defined master system (SDMS) architecture. The master system of the BAMS comprising a plurality of building automation systems (BASs) receives a request to create a building-related service involving dynamic coordination between at least two BASs. The request may include a workflow comprising a set of actions and configurations defining the building-related service. The master system uses system description data generated from the workflow to instantiate a blueprint that defines data exchanges with the at least two BASs, information about target hosts, and any dependencies to be resolved. Upon parsing the blueprint to resolve any dependencies, the master system builds a deployment plan that includes a sequence of steps and configurations for implementing the building-related service.

Abstract: The CLOUD-AUTHENTICATED SITE RESOURCE MANAGEMENT DEVICES, APPARATUSES, METHODS AND SYSTEMS (“CASRM”) transforms resource-use, weather, and user settings inputs into resource management schedule and control outputs. The CASRM achieves data transformation via using a building automation management device, comprising at least a processor a memory storing processor-executable instructions to receive, at a virtual cloud network controller, a data packet from a source building resource control device and to access a virtual routing table corresponding to a local virtual network associated with a control entity. The building automation management device may also determine a destination building resource control device based on the virtual routing table and at least one destination address in the data packet, and may send the data packet to the destination building resource control device.

Abstract: Systems and methods for automated management of buildings and rooms employ a common set of components that may be paired together to form a modular room control interface. The components may comprise a base plate and a front plate that are in data communication with each other when connected together. The base plate may include one set of room monitoring and control functions and the front plate may include a different set of room monitoring and control functions. Different combinations of base plates and front plates may then be paired together to achieve a desired functionality in the modular room control interface. Such an arrangement provides a room control interface that can be quickly and easily configured for any number of different room monitoring and control functions as needed.

Abstract: Systems and methods for automated management of buildings and rooms employ a common set of components that may be paired together to form a modular room control interface. The components may comprise a base plate and a front plate that are in data communication with each other when connected together. The base plate may include one set of room monitoring and control functions and the front plate may include a different set of room monitoring and control functions. Different combinations of base plates and front plates may then be paired together to achieve a desired functionality in the modular room control interface. Such an arrangement provides a room control interface that can be quickly and easily configured for any number of different room monitoring and control functions as needed.

Abstract: The CLOUD-AUTHENTICATED SITE RESOURCE MANAGEMENT DEVICES, APPARATUSES, METHODS AND SYSTEMS (“CASRM”) transforms resource-use, weather, and user settings inputs into resource management schedule and control outputs. The CASRM achieves data transformation via using a building automation management device, comprising at least a processor a memory storing processor-executable instructions to receive, at a virtual cloud network controller, a data packet from a source building resource control device and to access a virtual routing table corresponding to a local virtual network associated with a control entity. The building automation management device may also determine a destination building resource control device based on the virtual routing table and at least one destination address in the data packet, and may send the data packet to the destination building resource control device.

Abstract: A server associated with a building automation system of a building, determines an occurrence of an emergency in the building, based on detection of the emergency by sensors distributed in the building. The server transmits to a remote emergency service, an alert of the detected emergency. In response, the server receives from the remote emergency service, an authorized login to temporarily transfer to the remote emergency service, control of the building automation system to respond to the detected emergency. In response to the authorized login, the server transfers the control to the remote emergency service, and causes the remote emergency service to transmit a command to devices in the building automation system. When the command is received by the devices, it modifies or alters operation of the devices. After the detected emergency has been resolved, the server disables the temporary transfer of control by the remote emergency service.

Abstract: A server associated with a building automation emergency response system, receives indications of a detected emergency from sensors distributed among zones in the building, comprising a sensor reading level and a sensor identity. The server determines a zone danger level, based on the sensor identity and on the sensor reading levels. The server calculates an evacuation route commencing from user interfaces distributed among the zones. The user interfaces include a display device. The evacuation route is calculated to traverse the zones with a lower route danger level. The evacuation route is directed toward a safe exit, based on a floor plan. The server then transmits a depiction of the evacuation route to the user interfaces for display. The server continues receiving updated indications from the sensors, determines updated route danger levels, calculates an updated evacuation route, and transmits an updated depiction of the evacuation route to the user interfaces for display.

Abstract: System and methods for reconfiguring rooms or zones within an area in building automation are disclosed. One of the methods includes receiving a user request to group together at least a first segment and a second segment in a zone and verifying the user request using one or more rules. Upon verification of the user request, the method automatically links each object in the master segment to the corresponding object in the second segment to create the zone. Within this zone, a control program of the master segment provides a synchronized control of the environmental control equipment in the master segment and the second segment. This method of zoning provides the flexibility to perform rezoning on the fly without requiring traditional engineering, redesign or reprogramming.

Abstract: According to one aspect, embodiments of the invention provide a self-aligning connector system for connecting an actuator to a valve body of a valve, comprising an actuator adapter plug having a conical protrusion and a peripheral groove formed in an outer surface of the actuator adapter plug, and a valve adapter sub-assembly comprising an outer housing having a bore configured to receive the actuator adapter plug, and an expansion spring coupled to the outer housing and configured to provide radial pressure on the outer housing to receive the conical protrusion of the actuator adapter plug and latch onto the peripheral groove.

Abstract: The CLOUD-AUTHENTICATED SITE RESOURCE MANAGEMENT DEVICES, APPARATUSES, METHODS AND SYSTEMS (“CASRM”) transforms resource-use, weather, and user settings inputs into resource management schedule and control outputs. The CASRM achieves data transformation via using a building automation management device, comprising at least a processor a memory storing processor-executable instructions to receive, at a virtual cloud network controller, a data packet from a source building resource control device and to access a virtual routing table corresponding to a local virtual network associated with a control entity. The building automation management device may also determine a destination building resource control device based on the virtual routing table and at least one destination address in the data packet, and may send the data packet to the destination building resource control device.

Abstract: The DYNAMIC ADAPTABLE ENVIRONMENT RESOURCE MANAGEMENT CONTROLLER APPARATUSES, METHODS AND SYSTEMS (“DAERMC”) transforms various user, component and environment inputs into responsive environment outputs. In some implementations, the DAERMC allows users to manage a plurality of locations via mobile electronic devices (e.g., electronic mobile devices, resource management devices, and/or the like), and may be able to integrate and provide a plurality of information from said devices, including location data, current and projected weather data, current and future resource usage data, messages and/or like notifications, resource usage schedules, resource usage reports, resource usage settings, overrides, and/or the like.

Abstract: A valve arrangement including a valve and a valve actuation arrangement is provided. The valve has a known flow profile. The valve includes a valve member and a valve stem operably coupled to the valve member for adjusting the position of the valve member. The valve actuation arrangement is operably coupled to the valve stem. The valve actuation arrangement includes a drive arrangement and a control arrangement. The drive arrangement is operably coupled to the valve stem and configured to adjust an actual stem position of the valve stem based on an actual stem positional signal. The control arrangement is configured to generate the actual stem positional signal. The control arrangement is configured to generate the actual stem positional signal based on an input control signal representing a desired stem position based on a desired flow profile being different than the known flow profile.

Abstract: A valve arrangement including a valve and a valve actuation arrangement is provided. The valve has a known flow profile. The valve includes a valve member and a valve stem operably coupled to the valve member for adjusting the position of the valve member. The valve actuation arrangement is operably coupled to the valve stem. The valve actuation arrangement includes a drive arrangement and a control arrangement. The drive arrangement is operably coupled to the valve stem and configured to adjust an actual stem position of the valve stem based on an actual stem positional signal. The control arrangement is configured to generate the actual stem positional signal. The control arrangement is configured to generate the actual stem positional signal based on an input control signal representing a desired stem position based on a desired flow profile being different than the known flow profile.

Abstract: The embodiments describe programmable peripheral units for use in a building automation system. The program-mable peripheral units communicate with controllers and other system components. The programmable peripheral units have end device components to actuate the building environment.

Abstract: There is provided a method for displaying alarm events to an operator. Alarm events, each being associated with the properties age, state and priority, are received from an alarm generating system. The alarm events are represented by graphical objects which are displayed in a graphical user interface. The sizes of the graphical objects are determined based on at least two of the properties being associated with the alarm event, and the position of the graphical objects is related to the size of the graphical object and/or one or more of the properties being associated with the alarm event represented by the graphical object.

Abstract: The CLOUD-AUTHENTICATED SITE RESOURCE MANAGEMENT DEVICES, APPARATUSES, METHODS AND SYSTEMS (“CASRM”) transforms resource-use, weather, and user settings inputs into resource management schedule and control outputs. The CASRM achieves data transformation via using a building automation management device, comprising at least a processor a memory storing processor-executable instructions to receive, at a virtual cloud network controller, a data packet from a source building resource control device and to access a virtual routing table corresponding to a local virtual network associated with a control entity. The building automation management device may also determine a destination building resource control device based on the virtual routing table and at least one destination address in the data packet, and may send the data packet to the destination building resource control device.

Abstract: According to at least one embodiment, a computer system for binding widgets to devices is provided. The computer system includes one or more memory elements collectively storing a plurality of widgets including a plurality of default identifiers and a plurality of identifiers of a plurality of devices associated with an identified space. The computer system also includes at least one processor in data communication with the one or more memory elements and a deployment component executable by the at least one processor. The deployment component is configured to receive a request to bind the plurality of widgets to the plurality of devices and bind, in response to receiving the request, the plurality of widgets to the plurality of devices using the plurality of identifiers.

Abstract: Systems and methods for automated management of buildings and rooms employ a common set of components that may be paired together to form a modular room control interface. The components may comprise a base plate and a front plate that are in data communication with each other when connected together. The base plate may include one set of room monitoring and control functions and the front plate may include a different set of room monitoring and control functions. Different combinations of base plates and front plates may then be paired together to achieve a desired functionality in the modular room control interface. Such an arrangement provides a room control interface that can be quickly and easily configured for any number of different room monitoring and control functions as needed.

Abstract: An actuator assembly includes a housing, and a clamp disposed within the housing. The clamp is configured to attach the actuator assembly to a damper jackshaft or valve stem or valve linkage shaft. The jackshaft is operable to control the position of one or more damper blades. The valve stem and valve linkage shaft control the position of the valve plug. The clamp is accessible via a slotted opening which is unobstructed at one end. A motor is configured to rotate the clamping device within the housing. A control module is coupled to the motor and configured to control the damper or valve actuator assembly. In embodiments, a communications module facilitates communications to and from the damper actuator assembly over a network, and allows both remote monitoring of the damper and remote control of the damper actuator assembly or of the valve and remote control of the valve actuator assembly.

Abstract: According to various aspects and embodiments, a system and method for controlling temperature in a control zone within a building is provided. According to some embodiments, the method includes receiving measured wind condition data external to the building and measured tracer gas concentration data in the control zone for a sample time interval and calculating an air flow characteristic for the sample time interval based on the measured tracer gas concentration data. The method further includes using the air flow characteristic in a temperature control loop for the control zone. According to some embodiments, the air flow characteristic is an air change rate (ACR) that may be used in determining a preheat time interval.