The invention relates to a communication system for a vehicle, which device includes a sensor device, wherein the sensor device is arranged to capture sensor data when the sensor device moves. A receiving device receives reference data from an external management system and a processing device determines a difference between the captured sensor data and the corresponding reference data, wherein the determined difference between the captured sensor and the corresponding reference data is transmitted to the external management system.

A battery management unit includes a plurality of monitoring IC chips each configured to detect at least one operating parameter of at least one battery cell or battery module, which has a predetermined number of battery cells and is connected to a first bus. The battery management unit further includes a control unit and a basis monitoring IC chip which is likewise connected to the first bus and is configured to communicate with each of the monitoring IC chips via the first bus. The basis monitoring IC chip and the control unit are connected to a second bus and are configured to communicate with each other via the second bus. The basis monitoring IC chip and the control unit are arranged on a common circuit board.

A network includes a supervisory sensor in communication with a wireless network and a non-supervisory sensor in communication with the supervisory sensor, wherein the non-supervisory sensor communicates with the wireless network through the supervisory sensor. The supervisory sensor may be configured to receive downloads from a server communicating through the wireless network and to collect data from the non-supervisory sensor. The supervisory sensor may be configured to transmit the collected data to a server on the wireless network. Moreover, the non-supervisory sensor and the supervisory sensor each have an active state and an inactive state and wherein the supervisory sensor may be in the active state while the non-supervisory sensor is in the inactive state.

Methods and apparatus, including computer program products, are provided for remote monitoring. In some example implementations, there is provided a method. The method may include receiving, at a remote monitor, a notification message representative of an event detected, by a server, from analyte sensor data obtained from a receiver monitoring an analyte state of a host; presenting, at the remote monitor, the notification message to activate the remote monitor, wherein the remote monitor is configured by the server to receive the notification message to augment the receiver monitoring of the analyte state of the host; accessing, by the remote monitor, the server, in response to the presenting of the notification message; and receiving, in response to the accessing, information including at least the analyte sensor data. Related systems, methods, and articles of manufacture are also disclosed.

The present disclosure relates to methodologies, systems, and devices for monitoring metrics associated with a marine vessel. A marine monitoring system includes a machine type communication (MTC) server; a computing device in communication with the MTC server; a user application residing on the computing device; and a marine electronic device located at a marine vessel. The marine electronic device is in communication with the MTC server, and is configured to connect to one or more wired or wireless marine sensors.

Embodiments described herein include an acoustic telemetry system for use with an apparatus configured to rotate. The acoustic telemetry system includes one or more sensor nodes and at least one receiver node. In at least one embodiment, the telemetry system also includes at least one hub node positioned on the apparatus. Each sensor node is attached to or embedded in the apparatus. Each sensor node obtains data related to one or more operating conditions of the apparatus and the environment surrounding the apparatus. The one or more sensor nodes encode and transmit the data to the hub node or the receiver node using ultrasonic acoustic waves. In at least one embodiment, the hub node transmits the data to the receiver node. The receiver node decodes the data and monitors the one or more operating conditions of the apparatus.

Aspects include a water-leak-detection and -monitoring system for a building including a first area, comprising a memory, a communication interface configured to be communicatively coupled to a water-flow sensor coupled to a pipe in the first area, at least one of a humidity sensor, a temperature sensor, or a liquid-water sensor configured to sense information indicative of a presence of water in the first area, and an analytical engine in communication with a base unit, the memory, the communication interface, and the at least one of the humidity sensor, the temperature sensor, or the liquid-water sensor, the analytical engine being configured to determine whether a leak is present in the building based on data from the water-flow sensor, and determine, responsive to determining that the leak is present, if the leak is in the first area based on the information indicative of the presence of water in the first area.

A method and system for the post-adjustment (i.e., offline) of event timestamps to implement virtual time synchronization amongst detection node clocks. In existing methodologies with the goal of clock synchronization, clocks (and timestamps generated therefrom) are disciplined or adjusted at the recordation time of the events on a detection node (e.g., a switch/router, an Internet-of-Things (IoT) device, a wireless sensor, etc.). However, there is no particular reason for these clocks or timestamps to be accurate during the recordation time, but rather, should be accurate at their use or interpretation time. Further, through these recordation time adjustments, clock drifts and timing errors may be gradually introduced, leading to runaway inaccuracies. The disclosed method and system intentionally avoids the disciplining of clocks at event recordation times on the detection node and, instead, adjusts timestamps during interpretation times, to overcome the aforementioned issues.

A storage battery monitoring method receives identification information indicating a storage battery system and characteristic data of a storage battery, the characteristic data including history information which indicates charging and discharging history of the storage battery; determines, based on the received history information, a deterioration model corresponding to the storage battery from among deterioration models managed in a database, the deterioration models each indicating a relationship between a state of health and a number of charging and discharging cycles performed by the battery as indicated by the charging and discharging history; generates control data for suppressing deterioration of the storage battery at a predetermined point in time according to the corresponding deterioration model; and transmits the generated control data to cause the storage battery system to control the storage battery.

Techniques are discussed for performing a demand reset in a wireless meter reading environment, in a manner such that demand data may not be lost. In response to receiving a command from a mobile device of a requester, a meter may store demand value(s) in a log, reset register(s) that store the demand value(s) and wirelessly provide the demand value(s) to the mobile device of the requester. Due to the lack of reliability associated with wireless communications between the meter and a requestor, the requestor may not actually receive the demand value(s). Upon receiving a subsequent command for the demand value(s), the meter may determine that the command is a replay, and provide the demand value(s) without resetting the register(s). Techniques are also discussed for generating the commands, securing the commands, and providing the commands to mobile devices in route packages.