Abstract: Techniques are described for providing a smart-mesh socket. The smart-mesh socket may be sized and shaped to be engaged with a conventional electrical socket of one or more types (e.g., a USB receptacle providing DC electrical power) to provide power to one or more circuits housed within the smart-mesh socket. These circuits may include, for example, a main circuit that includes at least a dual processor for controlling the operation and communications of at least two communication circuits. The dual processors may execute instructions for an operating system, thus allowing the smart-mesh socket to provide enhanced capabilities for networked devices. One or more first communication circuits may each include one or more transceivers that allow the first communication circuit to send and receive communications with other devices over wireless network(s) using one or multiple wireless communication protocols.

Abstract: Techniques are described for providing a smart-mesh socket. The smart-mesh socket may be sized and shaped to be engaged with a conventional electrical socket of one or more types (e.g., a USB receptacle providing DC electrical power) to provide power to one or more circuits housed within the smart-mesh socket. These circuits may include, for example, a main circuit that includes at least a dual processor for controlling the operation and communications of at least two communication circuits. The dual processors may execute instructions for an operating system, thus allowing the smart-mesh socket to provide enhanced capabilities for networked devices. One or more first communication circuits may each include one or more transceivers that allow the first communication circuit to send and receive communications with other devices over wireless network(s) using one or multiple wireless communication protocols.

Abstract: Techniques are described for providing a smart-mesh socket. The smart-mesh socket may be sized and shaped to be engaged with any convention light socket to provide power to one or more circuits housed within the smart-mesh socket. These circuits may include, for example, a main circuit that includes at least a dual processor for controlling the operation and communications of at least two communication circuits. The dual processors may execute instructions for an operating system, thus allowing the smart-mesh socket to provide enhanced capabilities for networked devices. The first communication circuit may include a transceiver that allows the first communication circuit to send and receive communications with other devices over a wireless network. The second communication circuit may include a passive receiver that allows the second communication circuit to track and monitor devices as those device move through a smart-mesh network.

Abstract: Techniques are described for controlling distributed operations of devices, such as for devices that are each part of or otherwise associated with a mechanical system containing actuators to manipulate a surrounding environment and optionally further containing sensors to obtain information from the surrounding environment, and with such a device controlling the associated system to perform industrial operations. The described techniques may include identifying a group of multiple such devices to perform one or more assigned tasks, such as in a cooperative distributed manner with each device performing part of the assigned tasks, and/or in a competitive manner with some or all devices independently performing at least one assigned task. The performances of the devices may further be evaluated in various manners, and the devices selected to perform one or more tasks may be identified in various manners (including based at least in part on past performance evaluations).

Abstract: Techniques are described for controlling distributed operations of devices, such as for devices that are each part of or otherwise associated with a mechanical system containing actuators to manipulate a surrounding environment and optionally further containing sensors to obtain information from the surrounding environment, and with such a device controlling the associated system to perform industrial operations. The described techniques may include identifying a group of multiple such devices to perform one or more assigned tasks, such as in a cooperative distributed manner with each device performing part of the assigned tasks, and/or in a competitive manner with some or all devices independently performing at least one assigned task. The performances of the devices may further be evaluated in various manners, and the devices selected to perform one or more tasks may be identified in various manners (including based at least in part on past performance evaluations).

Abstract: Techniques are described for providing a smart-mesh socket. The smart-mesh socket may be sized and shaped to be engaged with any convention light socket to provide power to one or more circuits housed within the smart-mesh socket. These circuits may include, for example, a main circuit that includes at least a dual processor for controlling the operation and communications of at least two communication circuits. The dual processors may execute instructions for an operating system, thus allowing the smart-mesh socket to provide enhanced capabilities for networked devices. The first communication circuit may include a transceiver that allows the first communication circuit to send and receive communications with other devices over a wireless network. The second communication circuit may include a passive receiver that allows the second communication circuit to track and monitor devices as those device move through a smart-mesh network.

Abstract: Techniques are described for controlling distributed operations of devices, such as for devices that are each part of or otherwise associated with a mechanical system containing actuators to manipulate a surrounding environment and optionally further containing sensors to obtain information from the surrounding environment, and with such a device controlling the associated system to perform industrial operations. The described techniques may include identifying a group of multiple such devices to perform one or more assigned tasks, such as in a cooperative distributed manner with each device performing part of the assigned tasks, and/or in a competitive manner with some or all devices independently performing at least one assigned task. The performances of the devices may further be evaluated in various manners, and the devices selected to perform one or more tasks may be identified in various manners (including based at least in part on past performance evaluations).