System and method for controlling a custom modular measurement system. An editor may receive user input specifying one or more system definitions, each mapping message based commands, parameters, variables and/or metadata (information) accordant with a control protocol for standalone instruments to functions and data in a programming language, and generates the definitions accordingly, each being useable by a client application to interface with a custom modular measurement system that includes multiple logical instruments via the message based information. At least one of the definitions may be deployed onto the measurement system. A run-time engine of the measurement system may accept a message based command from the application, and call a corresponding function, which may invoke operation of at least one of the logical instruments. The logical instruments may be operated concurrently, including sharing use of a single physical measurement device by at least two of the logical instruments.

Network hardware devices organized in a wireless mesh network (WMN) in which one network hardware devices includes multiple radios. A processing device of a first network hardware device receives, via a first radio, a beacon frame from a second mesh network device, scans, via a second radio, for a second mesh frame of the second mesh network device, and receives the mesh frame. The processing device determines a first sector identifier that identifies an antenna from which the mesh frame is transmitted, a first signal strength indicator value corresponding to the mesh frame, an unused radio and an unused channel of the second mesh network device. The processing device sends a first message to the unused radio of the second mesh network device on the unused channel via the second radio, receives a second message, and configures the multiple radios to communicate with the second mesh network device.

A method includes transmitting, by a set of drive-sense circuits of a plurality of drive-sense circuits of a test system, a set of electrode signals on a set of test container electrodes of a test container of a test container array of the test system. The test container contains a content. The method further includes generating, by the set of drive-sense circuits, a set of sensed signals. The method further includes interpreting, by a processing module of the test system, the set of sensed signals as a plurality of impedance values and generating an impedance map based on the plurality of impedance values and with respect to positioning of the set of test container electrodes. The impedance map is representative of electrical characteristics of the content.

A method includes transmitting, by a set of drive-sense circuits of a plurality of drive-sense circuits of a test system, a set of electrode signals on a set of test container electrodes of a test container of a test container array of the test system. The test container contains a content. The method further includes generating, by the set of drive-sense circuits, a set of sensed signals. The method further includes interpreting, by a processing module of the test system, the set of sensed signals as a plurality of impedance values and generating an impedance map based on the plurality of impedance values and with respect to positioning of the set of test container electrodes. The impedance map is representative of electrical characteristics of the content.

A test system includes a test container array including a plurality of test containers, and a plurality of electrodes integrated into the test container array. The test system further includes a plurality of drive-sense circuits coupled to the plurality of electrodes. When enabled, and when the test container contains a content, the set of drive-sense circuits transmit a set of electrode signals on the set of electrodes and generate a set of sensed signals. The test system further includes a processing module that includes a bandpass filter circuit operable to convert a sensed signal of the set of sensed signals to a filtered signal of a set of filtered signals and a frequency interpreter operable to convert the set of filtered signals into a set of impedance values, where the set of impedance values are representative of electrical characteristics of the content.

A test system includes a test container array including a plurality of test containers, and a plurality of electrodes integrated into the test container array. The test system further includes a plurality of drive-sense circuits coupled to the plurality of electrodes. When enabled, and when the test container contains a content, the set of drive-sense circuits transmit a set of electrode signals on the set of electrodes and generate a set of sensed signals. The test system further includes a processing module that includes a bandpass filter circuit operable to convert a sensed signal of the set of sensed signals to a filtered signal of a set of filtered signals and a frequency interpreter operable to convert the set of filtered signals into a set of impedance values, where the set of impedance values are representative of electrical characteristics of the content.

A system includes a first terminal configured to transmit control data to a controlled terminal via a first communication link for controlling operation of the controlled terminal, and a second terminal configured to transmit control data to the controlled terminal via a second communication link for controlling operation of the controlled terminal. The second terminal is further configured to, in response to the first communication link being under interference, receive the control data from the first terminal via a third communication link and transmit the control data received from the first terminal to the controlled terminal via the second communication link.

A electronics control unit is in contemporaneous wireless power communication and wireless data communication with a network of sealed, sensors over a shared bidirectional power antenna. Sensors and sensor networks described below enable the development of networks that are secure and robust, and yet are lighter-weight and lower-cost than, for example, conventional automotive sensor networks.

The present disclosure relates to a sensor circuit having a first interface configured to receive a first sensor signal in response to a first measurement of a first physical quantity, a first analog-to-digital converter configured to sample the first sensor signal to generate a sampled first sensor signal, a second interface configured to receive a second sensor signal in response to a second measurement of the same first physical quantity, a third interface configured to receive at least one third sensor signal in response to at least one third measurement of at least one second physical quantity that is different from the first physical quantity, a multiplexer configured to multiplex the second and the at least one third sensor signal to a multiplexed sensor signal, and a second analog-to-digital converter coupled to the multiplexer and configured to sample the multiplexed sensor signal to generate a sampled multiplexed sensor signal.

The present disclosure relates to a sensor circuit having a first interface configured to receive a first sensor signal in response to a first measurement of a first physical quantity, a first analog-to-digital converter configured to sample the first sensor signal to generate a sampled first sensor signal, a second interface configured to receive a second sensor signal in response to a second measurement of the same first physical quantity, a third interface configured to receive at least one third sensor signal in response to at least one third measurement of at least one second physical quantity that is different from the first physical quantity, a multiplexer configured to multiplex the second and the at least one third sensor signal to a multiplexed sensor signal, and a second analog-to-digital converter coupled to the multiplexer and configured to sample the multiplexed sensor signal to generate a sampled multiplexed sensor signal.