A high temperature fixture, said fixture comprising: at least three noble metal electrodes, arranged in parallel, among which two adjacent noble metal electrodes are used for clamping a test sample; noble metal wires connected to the noble metal electrodes at one end, and to a test device at the other end for transmitting test signals generated by the test sample to the test device through the noble metal electrodes; and a thermocouple for measuring the temperature of the test materials.

Described embodiments include a fault monitoring system comprising a fault logic circuit having a fault logic input adaptable to be coupled to sensor inputs, and first and second fault logic outputs. The fault logic circuit compares a plurality of data values provided by respective sensor inputs to respective fault thresholds, and provides respective fault signals at the first fault logic output responsive to a fault event in which a respective data value exceeds its respective fault threshold. A timer has a timer input coupled to the reset output, and a timer output. A data register has a first data register input coupled to the write control output, a second data register input coupled to the timer output, and a data register output. The data register receives fault data that includes an event identifier, a timer value, and a timer expiration indicator.

Various embodiments related to identifying a candidate defect region in a semiconductor device are disclosed. For example, one embodiment includes receiving an electrical test mismatch reported for a scan chain; generating a physical representation of portion of a logical design of the semiconductor device, the physical representation including location information for physical instantiations of logical cells and logical interconnections included in the portion of the logical design; identifying a suspect logical region in the physical representation, the suspect logical region including a portion of the logical cells and the logical interconnections electrically connected with the scan chain; generating a candidate defect region within the semiconductor device, the candidate defect region being defined, via the physical representation, to include the physical instantiations of logical cells and logical interconnections included in the suspect logical region; and displaying the candidate defect region.

A method for qualifying circuit board fabrication, assembly, and repair processes includes establishing primary assembly process specifications and secondary repair process specifications. A group of test circuit boards is assembled using the primary assembly process, with each board having a section of components linked together to provide functional circuits and a section of components daisy-chained together to provide non-functional circuits, and with each section also including SIR test patterns and CAF test patterns. A subset of the assembled test boards is then repaired using the secondary repair process. A sample of each set of the test boards is exposed to test conditions including thermal cycle test conditions, humidity test conditions, and vibration test conditions. Inner layer build quality, surface cleanliness, circuit performance, and solder joint quality are then evaluated using the provided circuitry.

Methods for reliability testing include applying a stress voltage to a device under test (DUT); measuring a leakage current across the DUT; triggering measurement of optical emissions from the DUT based on the timing of the measurement of the leakage current; and correlating measurements of the leakage current with measurements of the optical emissions to determine a time and location of a defect occurrence within the DUT by locating instances of increased noise in the leakage current that correspond in time with instances of increased optical emissions.

Methods for reliability testing include applying a stress voltage to a device under test (DUT); measuring a leakage current across the DUT; triggering measurement of optical emissions from the DUT based on the timing of the measurement of the leakage current; and correlating measurements of the leakage current with measurements of the optical emissions to determine a time and location of a defect occurrence within the DUT by locating instances of increased noise in the leakage current that correspond in time with instances of increased optical emissions.

Various devices, systems and methods are disclosed where a noise signal component of a sensor signal is used to obtain information about a sensor device. A device may include an evaluation circuit that is configured to receive a sensor signal having a noise signal component, and the evaluation circuit is further configured to evaluate the noise signal component to obtain information about a sensor device generating the sensor signal.

Systems, apparatuses, semiconductor products and methods for circuit testing, specifically non-contact circuit testing are provided that allow for the wireless, non-contact testing of an electrical component. For example, non-contact circuit testing is performed using a non-contact testing apparatus that include a circuit cover with a conductive material and an oscilloscope. The circuit cover is places over an electrical component to form a parallel plate capacitor with electrical component. The parallel plate capacitor is formed with an air dielectric between the electrical component and the circuit cover. An electrical signal is initiated at the electrical component to cause a voltage through the parallel plate capacitor. An oscilloscope probe is used to measure the voltage of the parallel plate capacitor to determine a connectivity of the electrical component without contacting the electrical component.

Systems for reliability testing include a picometer configured to measure a leakage current across a device under test (DUT); a camera configured to measure optical emissions from the DUT based on a timing of the measurement of the leakage current; and a test system configured to apply a stress voltage to the DUT and to correlate the leakage current with the optical emissions using a processor to determine a time and location of a defect occurrence within the DUT by locating instances of increased noise in the leakage current that correspond in time with instances of increased optical emissions.

Described embodiments include a fault monitoring system comprising a fault logic circuit having a fault logic input adaptable to be coupled to sensor inputs, and first and second fault logic outputs. The fault logic circuit compares a plurality of data values provided by respective sensor inputs to respective fault thresholds, and provides respective fault signals at the first fault logic output responsive to a fault event in which a respective data value exceeds its respective fault threshold. A timer has a timer input coupled to the reset output, and a timer output. A data register has a first data register input coupled to the write control output, a second data register input coupled to the timer output, and a data register output. The data register receives fault data that includes an event identifier, a timer value, and a timer expiration indicator.