Abstract: Systems, computer-implemented methods and/or computer program products that facilitate automating home control are provided. In one embodiment a computer-implemented method comprises: using a voice recognition component to identify user identification by analyzing voice signatures; using a face recognition component to determine user identification by analyzing facial features; using an authentication component to verify user identification and authorize control access to functionality of one or more automated home control systems; using a communication component to facilitate communication between the one or more automated home control systems and one or more devices; using a service component to execute a set of functions based on authorized user commands and information communicated from the one or more devices; and using a machine learning component to learn user preferences by correlating a set of functions with the authorized users commands.

Abstract: Systems, computer-implemented methods and/or computer program products that facilitate automating home control are provided. In one embodiment a computer-implemented method comprises: using a voice recognition component to identify user identification by analyzing voice signatures; using a face recognition component to determine user identification by analyzing facial features; using an authentication component to verify user identification and authorize control access to functionality of one or more automated home control systems; using a communication component to facilitate communication between the one or more automated home control systems and one or more devices; using a service component to execute a set of functions based on authorized user commands and information communicated from the one or more devices; and using a machine learning component to learn user preferences by correlating a set of functions with the authorized users commands.

Abstract: Facilitating single node network connectivity for structure automation functionality is provided herein. A system can comprise a memory that stores executable components and a processor, operatively coupled to the memory, that executes the executable components. The executable components can comprise a management component that facilitates a communication with electronic devices within a structure and an initialization component that enables a streamlined security process based on an indication that the at least one electronic device is to be registered with the management component. Further, the executable components can comprise a negotiation component that performs a certificate authentication for the at least one electronic device. The certificate authentication can be automatically performed with a certificate authority during a backend process.

Abstract: A surveillance platform for the sensing, measuring, monitoring and controlling equipment and environments, such as food storage and retailing environments, data center environments, and other environments in which equipment performance, operating status, and environmental condition monitoring is desirable, is provided. The surveillance platform can facilitate reporting, visualizing, acknowledging, analyzing, calculating, event generating, notifying, trending, and tracking, of operational events occurring within the environment. Such techniques can be used to protect articles such as food articles, medical articles, computing devices and equipment, artifacts, documents, and the like.

Abstract: Systems and methods for managing and utilizing heat associated with battery charge and/or discharge cycles are described herein. A system as described herein includes a battery array comprising one or more batteries, a heat collector physically coupled to respective batteries of the battery array that captures heat associated with at least one of charge cycles or discharge cycles of the respective batteries of the battery array, and a routing controller communicatively coupled to the heat collector that initiates transference of the heat captured by the heat collector as an energy source to one or more subsystems that are distinct from the heat collector.

Abstract: At least one shingle is integrated with logic circuitry and various other components which enable high-level functionality and automated system diagnostics. Each shingle can automatically determine its absolute position on a rooftop and/or its position relative to other shingles in the smart shingle system. Each shingle can also detect various changes in its own power generation, efficiency, and/or operating conditions, as well as those of neighboring shingles. Each shingle can then leverage this information to conduct system diagnostics and possibly to generate and/or execute recommended solutions. In another embodiment, each shingle can be coupled to a centralized controller which can perform the same automapping and diagnostic functions. The controller can also monitor the power usage of the building to help optimize the power generation of the smart shingle system.

Abstract: Systems, computer-implemented methods and/or computer program products that facilitate automating home control are provided.

Abstract: Techniques regarding material flow regulation and power generation are provided herein. For example, one or more embodiments described herein can regard a device or system for regulating material flow and power generation. The system can comprise a processor that executes computer executable components stored in a memory. The system can also comprise a coupling component which can secure the system to a pipe. The system can further comprise a power generation component that can generate power from material flowing through the pipe and a power output component which can output power generated by the power generation component.

Abstract: Techniques regarding water heating control and hot water tanks are provided herein. For example, one or more embodiments described herein can regard a device or system for water tank heating regulation. The system can comprise a processor that executes computer executable components stored in a memory. The system can also comprise a mounting component that couples the system to a thermostat of a water heater. The system can further comprise an adapter component that attaches to a temperature adjustor of the thermostat; and a configuration component of the computer executable components that, when enabled by the processor, causes the adapter component to move the temperature adjustor make a temperature change at the thermostat.

Abstract: Systems, computer-implemented methods and/or computer program products that facilitate automating home control are provided. In one embodiment a computer-implemented method comprises: using a voice recognition component to identify user identification by analyzing voice signatures; using a face recognition component to determine user identification by analyzing facial features; using an authentication component to verify user identification and authorize control access to functionality of one or more automated home control systems; using a communication component to facilitate communication between the one or more automated home control systems and one or more devices; using a service component to execute a set of functions based on authorized user commands and information communicated from the one or more devices; and using a machine learning component to learn user preferences by correlating a set of functions with the authorized users commands.

Abstract: At least one shingle is integrated with logic circuitry and various other components which enable high-level functionality and automated system diagnostics. Each shingle can automatically determine its absolute position on a rooftop and/or its position relative to other shingles in the smart shingle system. Each shingle can also detect various changes in its own power generation, efficiency, and/or operating conditions, as well as those of neighboring shingles. Each shingle can then leverage this information to conduct system diagnostics and possibly to generate and/or execute recommended solutions. In another embodiment, each shingle can be coupled to a centralized controller which can perform the same automapping and diagnostic functions. The controller can also monitor the power usage of the building to help optimize the power generation of the smart shingle system.

Abstract: A surveillance platform for the sensing, measuring, monitoring and controlling equipment and environments, such as food storage and retailing environments, data center environments, and other environments in which equipment performance, operating status, and environmental condition monitoring is desirable, is provided. The surveillance platform can facilitate reporting, visualizing, acknowledging, analyzing, calculating, event generating, notifying, trending, and tracking, of operational events occurring within the environment. Such techniques can be used to protect articles such as food articles, medical articles, computing devices and equipment, artifacts, documents, and the like.

Abstract: At least one shingle is integrated with logic circuitry and various other components which enable high-level functionality and automated system diagnostics. Each shingle can automatically determine its absolute position on a rooftop and/or its position relative to other shingles in the smart shingle system. Each shingle can also detect various changes in its own power generation, efficiency, and/or operating conditions, as well as those of neighboring shingles. Each shingle can then leverage this information to conduct system diagnostics and possibly to generate and/or execute recommended solutions. In another embodiment, each shingle can be coupled to a centralized controller which can perform the same automapping and diagnostic functions. The controller can also monitor the power usage of the building to help optimize the power generation of the smart shingle system.

Abstract: A surveillance platform for the sensing, measuring, monitoring and controlling equipment and environments, such as food storage and retailing environments, data center environments, and other environments in which equipment performance, operating status, and environmental condition monitoring is desirable, is provided. The surveillance platform can facilitate reporting, visualizing, acknowledging, analyzing, calculating, event generating, notifying, trending, and tracking, of operational events occurring within the environment. Such techniques can be used to protect articles such as food articles, medical articles, computing devices and equipment, artifacts, documents, and the like.

Abstract: Thermostat and messaging devices (TMDs) and associated platforms for providing monitor and control functionality are disclosed. A TMD can be in communication with one or more sensors to facilitate intelligent heating and cooling as well has home automation. The TMD can facilitate communication with a plurality of different networking protocols such that it can receive communication signals from a plurality of different sensors and devices that operate using varying communication techniques. The TMD can also be configured to assist with geolocating a person who is calling for emergency services.

Abstract: Techniques regarding intelligent vehicles are provided herein. For example, one or more embodiments described herein can regard an intelligent vehicle that can comprise a sensor array configured to detect a parameter selected from a group comprising an internal parameter and an external parameter. The internal parameter can be associated with a first condition that is within the intelligent vehicle. The external parameter can be associated with a second condition that is outside the intelligent vehicle. The intelligent vehicle can also comprise a controller comprising processor, and the controller can be configured to generate a command based on the parameter. Further, the intelligent vehicle can comprise a communications interface configured to send the command to a device located outside the intelligent vehicle.

Abstract: Systems, computer-implemented methods and/or computer program products that facilitate automating home control are provided. In one embodiment a computer-implemented method comprises: using a voice recognition component to identify user identification by analyzing voice signatures; using a face recognition component to determine user identification by analyzing facial features; using an authentication component to verify user identification and authorize control access to functionality of one or more automated home control systems; using a communication component to facilitate communication between the one or more automated home control systems and one or more devices; using a service component to execute a set of functions based on authorized user commands and information communicated from the one or more devices; and using a machine learning component to learn user preferences by correlating a set of functions with the authorized users commands.

Abstract: At least one shingle is integrated with logic circuitry and various other components which enable high-level functionality and automated system diagnostics. Each shingle can automatically determine its absolute position on a rooftop and/or its position relative to other shingles in the smart shingle system. Each shingle can also detect various changes in its own power generation, efficiency, and/or operating conditions, as well as those of neighboring shingles. Each shingle can then leverage this information to conduct system diagnostics and possibly to generate and/or execute recommended solutions. In another embodiment, each shingle can be coupled to a centralized controller which can perform the same automapping and diagnostic functions. The controller can also monitor the power usage of the building to help optimize the power generation of the smart shingle system.

Abstract: Systems and methods for managing and utilizing heat associated with battery charge and/or discharge cycles are described herein. A system as described herein includes a battery array comprising one or more batteries, a heat collector physically coupled to respective batteries of the battery array that captures heat associated with at least one of charge cycles or discharge cycles of the respective batteries of the battery array, and a routing controller communicatively coupled to the heat collector that initiates transference of the heat captured by the heat collector as an energy source to one or more subsystems that are distinct from the heat collector.

Abstract: Facilitating structure automation functionality by automatically modifying a condition of an environment based on implementing a parameter adjustment at a remote device within the structure is provided herein. A method can comprise facilitating a communication link between a controller device, a first auxiliary device, and a second auxiliary device. Facilitating the communication link comprises defining a communication standard that controls a communication between the first auxiliary device and the second auxiliary device. The method can also comprise implementing a first change at the first auxiliary device based on a first determination that a first condition within an environment of the first auxiliary device is to be changed. Further, the method can comprise implementing a second change at the second auxiliary device based on a second determination that a second condition within the environment of the second auxiliary device is to be changed.