A method of probing printed circuit boards that includes providing a circuit board design including a plurality of probe points, and selecting a probe point including a location ink from the plurality of probe points in the circuit board design to be probed on a physical printed circuit board design. The method continues with probing at least one probe point of the plurality of probe points with a probe that activates the location ink. Activation of the location ink by the probe indicates the selected probe point including the locating ink.

A method for testing printed circuit boards (20) in a test apparatus having a carrying apparatus for the printed circuit board (20) and having test modules for measuring physical variables of components (EB) and contact points (29) on the printed circuit board (20), in which the width of the printed circuit board (20) defines an X direction, its length defines a Y direction and its thickness defines a Z direction inside the test apparatus, reference points, the X, Y and Z positions of which relative to the carrying apparatus are known, are present on the printed circuit board (20) or outside the latter, the X and Y positions of the components (EB) and contact points (29) relative to the reference points are known, the measurement of the physical variables depends on an actual Z position of the printed circuit board at the X and Y positions of the component (EB) or contact point (29) to be measured, and the actual Z position of the printed circuit board at the X and Y positions of the component (EB) or contact point (29) to be measured is determined by means of an interpolation method starting from the X, Y and Z positions of selected reference points.

Various embodiments include methods and apparatuses to test production tools and related electrical components therefor including individual printed-circuit boards (PCBs). In one example, a test-plug hardware-platform includes at least one input/output (I/O) connector, and a configurable control system to provide command and operational signals through the I/O connector and collect data through the I/O connector from at least one PCB under test. A wireless-mesh network within the test-plug hardware-platform can interface wirelessly with at least the PCB under test. The at least one PCB operating within a production tool or other piece of equipment. Other methods and systems are disclosed.

The present invention is directed to a system for testing printed circuit boards. The system is configured to test the simultaneously test a multiplicity of printed circuit boards. The system examines the electrical characteristics of a printed circuit board and is operable to identify if a printed circuit board meets a desired characteristic.

The invention relates to a system in particular a quantum sensor system, for testing a device-under-test, DUT, comprising: an optically excitable medium which is arranged to receive electromagnetic, EM, radiation emitted by the DUT, at least one light source configured to irradiate the medium with at least one light beam, wherein the medium is optically excited by the at least one light beam, a field generator unit configured to generate an electric and/or magnetic field within the medium, wherein a resonance frequency of the excited medium is modified by an amplitude of the electric and/or magnetic field, wherein an optical parameter, in particular a luminescence, of the exited medium is locally modified if a frequency of the EM radiation corresponds to the resonance frequency at a position in the medium, an image detector configured to acquire an image of the medium, wherein the image shows an intensity profile that results from the modification of the optical parameter, a processor configured to analyze the DUT based on the acquired image.

An automatic circuit board test system includes at least one switch module of board under test connected with a test board, a control module and a test process module. The test board includes a first signal interface, a second signal interface and a third signal interface and a repeater. The second signal interface and the third signal interface are mutually connected by a signal cable. The first signal interface is connected with the repeater. The at least one switch module of board under test is connected with the second signal interface and the third signal interface. The control module is connected with the at least one switch module of board under test. The control module controls the at least one switch module of board under test. The test process module is connected with the control module and the first signal interface by at least two serial port buses.

The invention relates to a marking device (02) for marking circuit boards (04) tested by means of a test device (01, 08), wherein the marking device (02) can be fixed to the test device (01, 08) in a defined target position, and wherein the marking device (02) has a marking member (06) which can engage the surface (05) of a circuit board (04), and wherein the marking member (06) can be driven by a drive mechanism (16) in order to apply a marking to the surface (05) of the circuit board (04) by an operating movement of the marking member (06) depending on the test result. The marking device (02) includes a fixation module (10) and a quick change module (11), wherein the marking device (02) can be fixed to the test device (01, 08) in the defined target position by means of the fixation module (10), and wherein the quick change module (11) includes the marking member (06) and the drive mechanism (16), and wherein the quick change module (11) can be replaced without removing the fixation module (10).

A sensor device is provided for detecting electrical defects in a device under test (DUT). The sensor device includes a signal line configured to conduct a stimulus signal through a first conductor in the DUT; an inductor connected in series with the signal line for providing an inductance; and a ground line arranged adjacent to the signal line and configured to provide a ground path through a second conductor in the DUT for the stimulus signal conducted through the signal line and the first conductor. A resonance frequency for the signal line is determined based on the inductance and an effective capacitance of the signal line generated in response to the stimulus signal. An increase in the resonance frequency indicates an open defect in the first conductor and/or the second conductor, and a decrease in the resonance frequency indicates a short defect between the first conductor and the second conductor.

The present application discloses a testing device of array substrates and a testing method. The testing device of array substrates includes: a machine and testing interfaces, the testing interfaces being disposed on the machine; and testers disposed above the machine. There are at least two sets of testers, and the testers synchronously operate according to a preset scheme.

An inspection device is provided, which is capable of detecting a short circuit failure even when a connector is provided on a wiring board. The inspection device is configured to inspect a short circuit failure generated at any connected part of a plurality of pins 153 to a wiring board via solder. The plurality of pins 153 is included in a connector provided on the wiring board. The inspection device includes: a wiring 11 connected to certain pins 153 of the plurality of pins 153; a second wiring 12 connected to remaining pins 153 of the plurality of pins 153; and a tester unit connected to the first wiring 11 and to the second wiring 12 so as to inspect insulation between the certain pins 153 and the remaining pins 153.