A system includes a central analysis station and a display. The central analysis station may be configured to receive a unique identifier and performance data from each of a plurality of solar panels. The central analysis station may detect a problem in at least one of the plurality of solar panels based on the performance data. A display may be configured to display a status of the at least one of the plurality of solar panels based on the detected problem.

Techniques determine if an appliance having a fixed-rate of gas-consumption is degrading over time. In one example, a flowrate of gas at a service site is obtained. The flowrate of gas is disaggregated to obtain a flowrate of gas corresponding to an appliance having a generally fixed-rate of gas-consumption. The flowrate of gas of the appliance is compared to historical gas consumption by the appliance. Based at least in part on the comparing, it may be determined that performance of the appliance has changed over time. For example, the gas consumption of a hot water tank may increase due to mineral build-up in the bottom of the tank. Responsive to the determined degradation of the appliance, warnings may be sent, repairs may be made, and/or appliance(s) may be replaced.

Techniques for detecting and remediating a low gas pressure situation within a gas delivery system are described. In one example, a smart gas metering device measures gas pressure. The first device determines that the gas pressure value is less than a first threshold value, indicating a low gas pressure condition. The first smart metering device reports this condition to a second smart metering device, which may be nearby. In response, the first smart metering device receives gas pressure information from the second smart gas metering device. The first smart gas metering device then reports one of two conditions to a headend device, such as a main office server. In a first possibility, the report indicates a low gas pressure event confined to the first device. Alternatively, the report indicates a low gas pressure event within a distribution area comprising the first device and the second device.

Systems and methods for charging vehicles. In some embodiments, a system includes at least one mobile device and a utility network management center (“NMC”). The at least one mobile device is configured as an electronic utility device and includes a network interface card (“NIC”). The at least one mobile device is also associated with a utility billing account and at least one utility commodity meter. The utility NMC is configured to communicate with the at least one mobile device and the at least one utility commodity meter over a network, locate the at least one mobile device, and monitor a state of the at least one utility commodity meter. The utility NMC is also configured to determine a usage of a commodity based on the state of the at least one utility commodity meter, and bill the utility billing account associated with the mobile device for the usage of the commodity.

An environmental data collection system includes one or more smart sensors, a controller coupled to the one or more smart sensors, the controller including one or more modular decoders having a processor and a memory storing computer readable program code, that when executed by the processor, causes the modular decoder to configure communication and data retrieval between the one or more smart sensors and the controller, perform signal processing on data retrieved from the one or more smart sensors specific to the sensing capabilities of the one or more smart sensors, convert the signal processed data to a fixed bit format, and convey the fixed bit data to the controller.

The systems and methods described herein are directed to techniques for improving battery life performance of end devices in resource monitoring systems which transmit data using low-power, wide area network (LPWAN) technologies. Further, the techniques include providing sensor interfaces in the end devices configured to communicate with multiple types of metrology sensors. Additionally, the systems and methods include techniques for reducing the size of a concentrator of a gateway device which receives resource measurement data from end devices. The reduced size of the concentrator results in smaller, more compact gateway devices that consume less energy and reduce heat dissipation experienced in gateway devices. The concentrator may comply with modular interface standards, and include two radios configured for transmitting 1-watt signals. Lastly, the systems and methods include techniques for fully redundant radio architecture within a gateway device, allowing for maximum range and minimizing downtime due to transmission overlap.

A method operates a supply system having a measuring unit and a central unit. Information is transferred repeatedly at specific time intervals via a communication network by radio between the central unit and the measuring unit. The measuring unit or the central unit receives the information and then generates a receipt confirmation, which it transmits to the central unit or the measuring unit respectively. The central unit or the measuring unit, after transmitting the information, opens a receive window of a certain time length for receiving the receipt confirmation. As a result of a first trigger event, the time intervals between the repeat transmissions of the information are shortened, and/or an additional receive window for receiving the receipt confirmation is opened, and as a result of a second trigger event, the time intervals between the repeat transmissions are lengthened, and/or no additional receive windows are opened.

The present disclosure provides a method for measuring energy of natural gas in a full cycle, including obtaining a metering value of the natural gas used by a user in a time period based on a metering device, and determining a consumption amount of natural gas based on the metering value and a pricing scheme.

A method for operating a power consumption metering system and a power consumption metering system are disclosed. In an embodiment a method include measuring, by a sensor deployed at a monitored site, high speed power consumption values over time to obtain a high speed value pattern of power consumption with a resolution of more than 1000 values per second, determining one or more harmonics of the high speed value pattern, measuring, by the sensor, low speed power consumption values over time to obtain a low speed value pattern of the power consumption with a resolution of less than 100 values per second, providing the harmonics and the low speed value pattern to a cloud based data processing system and identifying a status of a power consumer of the monitored site dependent on the measured harmonics and the low speed value pattern.

An enclosure for a utility metering device is configured to reduce internal air temperatures. In an example, the utility metering device has a solar shield and/or filtered ventilation air passage(s). In the example, an enclosure is attached to a base. Opening(s) may be defined in the enclosure, to allow air to remove heat from the metering device by convection. The openings may be covered with filters, to prevent the entry of water, dust, insects, etc. A solar shield may cover at least an upper surface of the enclosure. An air pocket may be defined between the solar shield and at least the upper surface of the enclosure. Air from within the enclosure may be ventilated into the air pocket, and air from within the air pocket may be ventilated into the atmosphere. The ventilation removes heat from within the enclosure, while the solar shield rejects addition of heat energy.