The disclosure relates to a device for the wireless transmission of a signal transmitted from a sensor to a supply apparatus (for example a control system) via at least one line, having electrical connections for the line and having an electronic transmitter apparatus that has an electronic circuit for tapping the signal and a transmitter with which the tapped signal can be wirelessly transmitted. The device is in the form of a plug adapter that has a plug housing, wherein a first plug part and a second plug part are attached to the plug housing, wherein the first plug part is connected to the second plug part via at least one signal conductor arranged within the plug housing for wired transmission of the signal, and wherein the electronic transmitter apparatus is arranged in the plug housing in order to tap off the signal.

A leak in the membrane of a generally horizontal roof support deck includes dividing the membrane into separate zones and locating a sensor to detect moisture underneath the membrane. A unique digital code address is assigned to sensor where inputs of the sensors are connected to a single power and signaling cable system using a daisy chain. The serial bus controller is to interrogate each of the sensor devices using the address to identify zones where moisture is detected. A transmitting antenna is provided at each sensor which is switched on when moisture is detected for detecting of the sensor from above the membrane by a utility locate device to confirm the location of the sensor.

Electricity meter, arranged to measure electrical energy supplied to an installation by a distribution network comprising a plurality of phases, the electricity meter including a communication module arranged to implement a communication by power-line communication; a switching circuit arranged to selectively connect the communication module to one of the phases; a processing unit arranged to control the switching circuit so as to connect the communication module to an optimised phase, from among the phases, which is selected dynamically to optimise a quality of the communication by power-line communication.

A control circuit is configured to monitor and control the operation of a rechargeable battery. The rechargeable battery includes a plurality of interconnected battery cells which are connected to at least one pole connection of the battery by at least one circuit element such that the at least one pole can be electrically decoupled from the rechargeable battery. The control circuit further includes at least one cell monitoring device configured to detect operational parameters of at least one battery cell, and a first control device configured to determine battery properties by evaluating operational parameters. The first control device is connected to the at least one cell monitoring device by a first interface. The control circuit further includes a second control device configured to control the at least one circuit element and which is connected to the at least one cell monitoring device by a second interface.

The invention relates to a method for the secured digital transmission of current measurement values and to a battery (1) and a battery controller (10) which are suitable for carrying out the method. The method has the steps of detecting (S1, S2) an amplitude of a battery current (I.sub.B) in a battery (1) using a first and a second sensor (2, 3), generating (S3, S4) a first and a second bit sequence, each of which describes the detected amplitude, generating a mirrored second bit sequence (21) by reversing (S5) a sequence of the bits provided by the second bit sequence (20), simultaneously transmitting (S6) the first bit sequence via a first data bus (5) and the mirrored second bit sequence (21) via a second data bus (6) to a battery controller (10), generating a second bit sequence (20) by reversing (S7) a sequence of the bits provided by the mirrored second bit sequence (21) after the simultaneous transmission (S6), and finally detecting (S8) a possible error in the first bit sequence or the second bit sequence (20) by comparing the first bit sequence (20) with the second bit sequence (21). Transmission faults are thus detected in particular in a transmission path between the sensors of the battery and the battery controller, said faults being caused by a common disturbance. Additionally, faults can also be detected which are caused by a disturbance that only affects one of the sensors or a part of the transmission path.

A multi-function acquisition device comprising a connector having two connection terminals, and an electronic circuit that comprises an acquisition circuit configured for enabling the digital conversion of analogic signals from a sensor, and the memorization of the digitized signals in a memory; a harvesting circuit configured for enabling the transmission of data stored in the memory to a harvesting device; a charging circuit configured for enabling the charging of a battery with the power provided by a powering device. A control unit controls the activation of the acquisition circuit, the activation of the harvesting circuit, and the activation of the charging circuit.

An object of the invention is to improve communication quality in a power storage management system.

The above-mentioned problem may be solved by the following one solution. When a communication error where transmission, reception, or both transmission and reception of a signal is not allowed occurs between one or a plurality of a plurality of information acquisition devices that acquires states of a plurality of power storage cells and an information collection device that communicates with the plurality of information acquisition devices in a time-division manner, and collects information related to the states of the plurality of power storage cells acquired by the plurality of respective information acquisition devices, a process for resolving a communication error is executed by putting all the plurality of information acquisition devices in a state in which communication with the information collection device is allowed at all times. Here, the plurality of information acquisition devices is in a state in which communication with the information collection device is allowed in a first period in which the plurality of information acquisition devices communicates with the information collection device, and is in a state in which the state, in which communication with the information collection device is allowed, is canceled in a second period in which other information acquisition devices communicate with the information collection device in a relation of n to 1 (n is a positive natural number indicating the number of communication channels of the information collection device).

A system to control and to monitor the entirety of a sanitary facility by using various specialized connected devices that are distributed throughout the sanitary facility, communicating with one another and over the internet network. Each one of these connected devices carries out its function or functions by using the information communicated by the other connected devices. Each one of these connected devices carries out its function or some of its functions independently in the event of a breakdown in the communication with the other connected devices. From the mobile or fixed apparatuses such as a Smartphone, touchscreen tablet, computer, server, etc. that are connected to the Internet, the user or users can interact with the connected devices, can be alerted in real time to malfunctions, and can receive information regarding the condition of the sanitary facility.

A message bus is utilized for energy management/control. The publish/subscribe message bus present between site gateways, a central server farm, and other entities, facilitates exchange of messages pertaining to management and control of power generation and/or storage. On-site publishers/subscribers can include, e.g., PV inverters, battery devices, energy meters, etc. Non-site specific publishers/subscribers can include, e.g., web clients, database servers (for logging), and various server components of the message bus. Messages exchanged between publishers and subscribers can include control messages (e.g., begin charging battery X) and measurement messages (e.g., the current charge of battery X is Y). Embodiments may implement logic at a site gateway prioritizing transmission of messages to local site devices. Thus where a gateway cannot simultaneously transmit device control messages and device data acquisition messages (e.g., due to processing burden or congestion), site gateway logic can prioritize transmission of the control messages over the locally-generated data acquisition requests.

A method for operating a sensor arrangement in a motor vehicle on the basis of a DSI protocol is disclosed. The sensor arrangement has a central unit as a master and a plurality of sensor units, each having a receiver as slaves controlled by the master. The central unit and the sensor units are connected to a bus line and via the bus cable a communication takes place between the central unit and the sensor units. The method includes selecting a first group of sensor units by the central unit for a first measurement, assigning a first time slot or first time slots within a first cycle respectively to one of the sensor units from the first group by means of the central unit, and broadcasting corresponding first time slot information from the central unit to the sensor units.