A system for diagnosing an additive manufacturing device is provided. The system includes a first module configured to: obtain one or more parameters for a digital twin of a component of the additive manufacturing device based on raw data from the component of the additive manufacturing device; and generate physics features for the digital twin of the component of the additive manufacturing device based on the one or more parameters and one or more transfer functions, a second module configured to obtain one or more classifiers for classifying the component as a first condition or a second condition based on physics features; and a third module configured to: determine a health of the component based on the generated physics features of the first model and the one or more classifiers.

Aspects of the disclosure relate to computing platforms that utilize improved techniques for dynamic event verification. A computing platform may receive first source data comprising driving data associated with a vehicle over a time period. Based on the first source data, the computing device may determine that the vehicle experienced an event, resulting in an event output. In response to determining the event output, the computing device may generate a request for second source data associated with the vehicle over the time period. The computing device may receive, from a sensor device, the second source data. Based on a comparison of the first source data to the second source data, the computing platform may determine an event comparison output. The computing platform may determine that the event comparison output exceeds a predetermined comparison threshold, and may send an indication of an event in response.

The present invention relates to a connector (100) for a water system. The connector comprises an inlet connector (105), a connector body and an outlet connector (120) arranged in sequence. The connector body is open-sided so as to form a tundish having an open air gap between the inlet and outlet connectors (105, 120), through which water can fall in use. The connector (100) further comprises a sensor for detecting the presence of water within the connector body.

An apparatus state data structure for controlling a technical apparatus includes at least one capability data field and at least one associated data field. Each capability data field indicates a respective functionality of the technical apparatus. Each associated data field is associated with a respective capability data field. The at least one associated data field includes at least one required component state data field and at least one required diagnostic data field. Each required component state data field indicates a configuration of a respective component required for the functionality of the capability data field associated with the respective required component state data field. Each required diagnostic data field indicates a respective operational state of a component of the technical apparatus required for the functionality of the capability data field associated with the respective required diagnostic data field.

A control system, for example for an optical system, includes: an actuating element; a measuring element for acquiring actuating element measurement data of the actuating element; a regulating unit for generating a regulating signal for regulating the actuating element depending on the acquired actuating element meas-urement data; and a state monitoring unit for monitoring a state of the control system depending on the acquired actuating element measurement data. The state monitoring unit includes: a first processing unit for generating preprocessed state data depending on (i) the acquired actuating element measurement data and a physical model and/or a mathematical model of the actuating element, or (ii) the acquired actuating element measurement data, a physical model and/or a mathematical model of the actuating element and the generated regulating signal; and a second processing unit for determining the state of the control system depending on the preprocessed state data.

The present invention provides a bioreactor controller with a simple user interface comprising a microcontroller and a linear motor. The bioreactor controller is microcontroller-based, has a greater temporal accuracy, and inexpensive. The microcontroller of the bioreactor controller selects a protocol mode and a setup mode by the user, runs the protocol mode if the setup mode is not selected by the user, stops running the protocol mode for a predetermined time if the protocol mode is selected by the user until the user is completed with calculations and record-keeping, detects movement error of the bioreactor controller, and informs the error to the user.

A system for monitoring at least one HVAC system includes at least one remotely accessible server, at least one probe or sensor operatively connected to the at least one HVAC system and configured to acquire operational data, and a communication module operatively connected to the at least one probe or sensor and configured to transmit the operational data acquired to the at least one remotely accessible server. The remotely accessibly server includes a processor and a memory unit and is programmed to receive and store operational data acquired for the HVAC system, and identify any operational abnormalities by analysing the operational data. Responsive to an operational abnormality being identified, the server is further programmed to designate a tiered maintenance status for the HVAC system and transmit a corresponding tiered maintenance request to a technician based on the tiered maintenance status designated.

An electrical device such as, for example, a mechanical interlock including one or more interconnected electrical components configured to detect or monitor an operational state or condition is hereby disclosed. In one embodiment, the electrical device may include a communications bus, one or more sensor modules coupled to the communications bus, and a sensor hub module coupled to the communications bus, wherein the sensor module(s) generate signal(s) including data indicating a sensed condition. A communications module coupled to the sensor hub module may transmit the data indicating the sensed condition to a remote device, a remote computer network, or a remote cloud service. Additionally, and/or alternatively, the device may include a water detection sensor including first and second curved conductive traces. Additionally, and/or alternatively, the device may include a voltage limiter circuit providing a DC output voltage from a high voltage AC input.

The present disclosure discloses an electronic control device. The electronic control device includes a memory unit, a control executing unit, and a test executing unit. The memory unit includes a rewritable region, which stores a control program, and a non-rewritable region, which stores test data and an anticipated test result. The control executing unit acquires input data and calculates a control value by executing the control program using the input data. The test data corresponds to the input data. The test executing unit: executes the test by running the control program using the test data in response to rewriting of the control program; determines whether the control program after rewriting works normally by comparing a test result calculated based on the test data and the anticipated test result; and permits start of the control program according to the determining result.

A method, data presenting device and computer program product are provided for assisting a remote user. The data presenting device includes a communication interface, a camera having a field of view in which images are captured, a projector having a presentation area in which presentation items may be presented, and a control unit which receives field of view control commands a command to project a presentation item in the presentation area, controls the field of view of the camera and controls the projector to project the presentation item in the presentation area, wherein the control of the projection in the presentation area is made independently of the control of the field of view.