The present disclosure relates to a clinical workflow, method, system and apparatus for performing an remote ocular health examination of a patient using medical equipment adapted to apparatus and emulating software and remote administration tool technology application. According to various embodiments portable medical equipment kit (OEK) can be assembled anywhere in the world connected to a computer. The MCB will have proprietary software to provide indirect to direct connection via layers. In an example embodiment, a method includes instructing a patient to position their eyes onto a camera where the image of the eyes are viewed on computer software. Where an on demand doctor can control the software that controls the cameras and review real time or near realtime the ocular images or videos via a indirect to direct connection to the main control base via a remote administration tool technology and emulating software using an internet connection.

A wireless enabled load control device having integrated voice control is disclosed. The load control device may be connected to a variety of local and remote devices, including lighting devices and smart appliances, as well as various cloud service platforms. The load control device may receive a voice command from a user. The load control device may transmit the voice command to a first cloud service platform for processing to determine an instruction included in the voice command. The determined instruction may be provided to a second cloud service platform connected to the first cloud service platform. The first and second cloud service platforms may be connected to a device to be controlled based on the voice command. The cloud service platforms can adjust an operation of the device based on the determined instruction.

Novel tools and techniques are provided for implementing customer resource telemetry and use as a service. In various embodiments, a computing system might receive, from a user, a request to access at least one network-accessible resource associated with a customer of a service provider, the user being unassociated and unrelated with the customer; might identify at least one of a user identification, a company, or a class of user associated with the user; might determine whether at least one resource record associated with the customer indicates that the user has permission to access the at least one network-accessible resource, based on the identification. If so, the computing system might provide the user with access to the at least one network-accessible resource associated with the customer. If not, the computing system might deny, to the user, access to the at least one network-accessible resource associated with the customer.

A power distribution system and method can include a controller and a set of power-using devices. Each power-using device in the set can include a sensor configured to measure a parameter and transmit a sensor signal representing the parameter to the controller, and the controller can respond to the transmitted sensor signal.

A plant system includes: an access node connected to a network; a plurality of controllers configured to perform distributed control on a plurality of field devices provided in a plant; and a wireless communication unit provided in each group of a plurality of groups into which the plurality of controllers are grouped and connected to each controller in the corresponding group via a wired connection, and configured to connect each controller to the access node via a wireless connection.

An embodiment provides a method for transferring information from at least one instrument to an application, including: establishing a central protocol structure, wherein the central protocol structure defines a format for information transmitted utilizing the central protocol structure; transmitting over a short-range wireless communication channel information from the at least one device to the application, wherein the information is formatted in a broadcast packet in view of the central protocol structure; receiving, at the application, information from the at least one device; and performing, within the application, an action with respect to the information within the application, wherein the performing comprises deciphering the information contained in view of the central protocol structure.

An apparatus, system, and methods for displaying information and advertisements in public or private venues including a body portion adapted to a seat structure or other seat supported apparatus, either as a base unit or a retrofit apparatus, wherein the seat structure or seating apparatus may provide the structure and housing for electronics necessary to power and control an electronic display that may be disposed on an adjustable modular bracket system that may be attached to a seat, a seat back, a cupholder, a cupholder attachment apparatus, a portable or mobile device attachment apparatus, which may be accessible, visible, and/or useable by a patron at a public venue.

Global Internet of things (IoT) quality of service (QoS) is provided through self-forming, self-healing, and/or collaborative edge IoT gateways. Moreover, global IoT services are provided by logically extending cellular networks with roaming partners to backhaul, track, and/or manage the globally deployed edge IoT gateways. In one aspect, real-time QoS and/or monitoring capabilities for the global IoT services can be provided through a communication between the edge IoT gateways and an edge gateway controller deployed within a cloud. The edge IoT gateways form a structured mesh network to coordinate workload execution under control of the edge gateway controller, which can facilitate a highly efficient QoS and/or SLA management for mobile IoT sensors, to provide a secure monitoring and/or diagnostic capability for the global IoT services.

A cyber-physical system may have monitoring nodes that generate a series of current monitoring node values over time that represent current operation of the system. A hierarchical abnormality localization computer platform accesses a multi-level hierarchy of elements, and elements in a first level of the hierarchy are associated with elements in at least one lower level of the hierarchy and at least some elements may be associated with monitoring nodes. The computer platform may then determine, based on feature vectors and a decision boundary, an abnormality status for a first element in the highest level of the hierarchy. If the abnormality status indicates an abnormality, the computer platform may determine an abnormality status for elements, associated with the first element, in at least one level of the hierarchy lower than the level of the first element. These determinations may be repeated until an abnormality is localized to a monitoring node.

A system for controlling power distribution within a vehicular communication network, including a power source equipment comprising a first port in communication with a network node module of a device, and a Power over Ethernet (POE) management module. The POE management module is configured to enable POE to the device via the first port, monitor a current draw of the device, determine whether the current draw of the device exceeds a threshold, and disable POE to the device, responsive to determining that the current draw exceeds the threshold.