A method for automatically detecting a sensor coupled to an electronic computer including steps of detecting the sensor and steps of configuring a hardware interface.

The invention relates to a universal interface (INT) arranged to be positioned between a detector (D) and a monitoring-control unit of equipment and comprising: a connector (40) with at least four input connection points configured for being connected to the detector (D) and notably comprising a connection point designed to be connected to a first output of the detector for receiving a first detector output signal (S1_D) and another connection point designed to be connected to a second output of the detector for receiving a second detector output signal (S2_D), a processing unit (UC) arranged for converting each detector output signal (S1_D, S2_D) into binary information to be sent to the monitoring-control unit of equipment and which is representative of a switched status or of a non-switched status of each output of the detector (D).

The present disclosure provides device and method for interface-control. The interface-control device includes: a control module having a controller and a first interface coupled to the controller, and a sensor module having a sensor circuit and a second interface coupled to the sensor circuit, the first interface and the second interface being connected through a matching connection. The first interface and the second interface each includes a first function pin for transferring first data reflecting a sensor type of the sensor circuit from the sensor circuit to the controller. The controller determines the sensor type of the sensor circuit based on the first data and processes measured data from the sensor circuit based on the sensor type.

A universal input/output circuit for building automation is provided that may avoid issues related to capacitor soakage, thereby giving more accurate measurements of electric resistance. To mitigate capacitor soakage, the voltage between the input/output terminals is held constant. A programmable source drives a current through a resistor that connects to the input/output terminals. The circuit then measures a value of electrical resistance. The measurement yields a voltage signal which is transferred from the input of an analog-to-digital converter to the input of a digital-to-analog converter. A unity gain amplifier applies the output voltage of the digital-to-analog converter D/A to one of terminals. The circuit is configured such that the voltage signal at the output of the amplifier matches or substantially matches the voltage obtained from the resistance measurement.

A method and system for determining short, open, and good connections using digital input and output (TO) structures in a device under test (DUT) continuity test, through the combined methods of using resistance-capacitance (RC) delay, time domain reflectometry (TDR), and forcing voltage on to a single IO pin of the DUT while measuring voltage on remaining IO pins of said DUT. In one embodiment, the combined methods are executed without the DUT in a test socket to produce a first set of test values and also with the DUT in a test socket to produce a second set of test values. The first and second sets of test values are compared to determine if one or more circuits of the DUT have a short circuit, an open circuit, or are a good (have an electrical connection that is not a short circuit or an open circuit) circuit.

A method and system for determining short, open, and good connections using digital input and output (TO) structures in a device under test (DUT) continuity test, through the combined methods of using resistance-capacitance (RC) delay, time domain reflectometry (TDR), and forcing voltage on to a single IO pin of the DUT while measuring voltage on remaining IO pins of said DUT. In one embodiment, the combined methods are executed without the DUT in a test socket to produce a first set of test values and also with the DUT in a test socket to produce a second set of test values. The first and second sets of test values are compared to determine if one or more circuits of the DUT have a short circuit, an open circuit, or are a good (have an electrical connection that is not a short circuit or an open circuit) circuit.

A method and system for determining short, open, and good connections using digital input and output (IO) structures in a device under test (DUT) continuity test, through the combined methods of using resistance-capacitance (RC) delay, time domain reflectometry (TDR), and forcing voltage on to a single IO pin of the DUT while measuring voltage on remaining IO pins of said DUT. In one embodiment, the combined methods are executed without the DUT in a test socket to produce a first set of test values and also with the DUT in a test socket to produce a second set of test values. The first and second sets of test values are compared to determine if one or more circuits of the DUT have a short circuit, an open circuit, or are a good (have an electrical connection that is not a short circuit or an open circuit) circuit.

A universal input/output circuit for building automation is provided that may avoid issues related to capacitor soakage, thereby giving more accurate measurements of electric resistance. To mitigate capacitor soakage, the voltage between the input/output terminals is held constant. A programmable source drives a current through a resistor that connects to the input/output terminals. The circuit then measures a value of electrical resistance. The measurement yields a voltage signal which is transferred from the input of an analog-to-digital converter to the input of a digital-to-analog converter. A unity gain amplifier applies the output voltage of the digital-to-analog converter D/A to one of terminals. The circuit is configured such that the voltage signal at the output of the amplifier matches or substantially matches the voltage obtained from the resistance measurement.