The present disclosure is a system for reducing greenhouse gas emissions that has an intra-grid sensor coupled to a secondary side of a transformer, and the transformer delivers power to a customer premise through a meter. Further, the intra-grid sensor measures an amount of power at the transformer to be delivered to the customer premise through the meter and transmits data indicative of the measured power at the transformer to a server. Also, the system has a processor resident on the server that ascertains non-technical loss based upon the data indicative of the measured power.

In an aspect of the disclosure, a method, a computer-readable medium, and an apparatus are provided. The apparatus may be a service processor. The service processor collects telemetry data from a host. The service processor manages the host. The service processor determines a subset of the telemetry data that are subscribed by a subscriber. The service processor sends the subset of the telemetry data to the subscriber.

An information processing system for monitoring a system. An embodiment of the present invention is a system (and concomitant methods and computer software embodied in non-transitory computer readable media) providing prioritized information and several extensions. These extensions include improved information flow between actors that participate in monitoring the system. These actors each have a model of its environment and may include either human operators, computational or software systems, or hardware systems that can act on information; for example, a pilot flying, a pilot monitoring, an aircraft itself, and responses taken and electronics readings therein. Components of the system comprise a metadata workbench, an information source, a condition monitor, and a notification terminal.

A data communication system, including master-side and slave-side data communication apparatuses configured to perform bidirectional communication with each other via a single-wire communication line. The master-side data communication apparatus includes first and second transistors performing switching according respectively to an input clock and write data, and a master-side data reproduction circuit reproducing read data transmitted from the slave-side. The slave-side data communication apparatus includes a clock reproduction circuit and a slave-side data reproduction circuit configured to respectively reproduce the input clock and the write data transmitted from the master-side, and a third transistor performing switching both according to the input clock reproduced by the clock reproduction circuit and according to the read data.

A method for optimizing the design of backplane and field bus routing for avionics network architectures determines a solution space of valid configurations defined by the intersection of universes corresponding to potential aircraft sensor locations, the data content relationships for each hosted application executing on the aircraft computing center, potential remote data concentrator (RDC) configurations, and potential backplane/field bus configurations for the avionics network architecture. The method includes identifying within the solution space, via an optimization engine, optimal configuration solutions of a desired optimality level based on connectivity constraints, system survivability constraints providing spatial separation of primary and redundant sensor and data collection systems, system robustness constraints associated with minimum functional capabilities for continued safe flight and landing capability, and an objective function characterizing overall desirability.

A spa is provided including a frame, a shell mounted to the frame defining a basin for holding water, at least one sensor for monitoring a spa component or water condition, a communications interface including a cellular transceiver, and a battery for providing power to the at least one sensor and to the communications interface when the spa is not connected to a power source. The spa also includes a controller in electrical communication with the at least one sensor and the communications interface. The controller is configured to, while the spa is not connected to the power source, receive information from the at least one sensor, process the received information, and cause the communications interface to wirelessly transmit the processed information to a remote source or central server.

A system for communication between BMSs of a battery pack including a plurality of BMSs connected to a parallel communication network, and a plurality of slave BMSs allocated with different communication identifiers, each having a variable field; and a master BMS for allocating a communication identifier to each of the plurality of slave BMSs through the parallel communication network, changing a priority determination value allocated to the variable field according to a predetermined condition, and performing communication with the plurality of slave BMSs based on the communication identifier.

The present invention relates generally to a system and method of networking and interconnecting a large number of various types of sensors to a remote location in an efficient manner Specifically, the invention utilizes a flexible, configurable, scalable and power-efficient sensor interface relay architecture to gather sensor data from various locations and then relay it to a remote location via the internet.

A method of controlling a battery including a first control circuit and a plurality of modules arranged in series between first and second terminals, each module including electric cells and switches and a second switch control circuit, the battery further including at least one first data transmission bus coupling the first control circuit to each second control circuit, the method including the transmission, by the first control circuit to the second control circuits, of first data representative of an electric cell configuration to be obtained to follow a set point for the delivery of a voltage and/or of a current between the first and second terminals, the second control circuits connecting or disconnecting the electric cells based on said first data and on a classification of the priorities of the electric cells.

Techniques are provided which may be implemented using various methods and/or apparatuses in a mobile device to address maximum permissible exposure (MPE) proximity sensor failure. A mobile device may include a maximum permissible exposure (MPE) sensor control unit to actively monitor signals associated with proper operation of the MPE proximity sensors. Upon detecting an anomaly in any of these signals, such as a value drop below a given threshold, an MPE sensor control Unit will inform an AP (application processor, or other processor or controller) which in turn trigger display of a warning message on the display of the mobile device or the issuance of other warnings such an audible or tactile alert to inform the end user about the maximum permissible exposure (MPE) proximity sensor malfunction and/or notify the end use of a condition resulting in deactivation of the 5G new radio transceiver.