A testing method and apparatus is disclosed for testing an integrated circuit device (100) which has a dedicated ground bias pad (121) connected across a high voltage electrostatic discharge clamp circuit (123) to a well-driving ground pad (122) by applying a first voltage to the dedicated ground bias pad to bias a wafer substrate (101) while simultaneously applying a second voltage to the well-driving ground pad to bias the well region (103), where the first and second voltage create a stressing voltage across a buried insulator layer (102, 105) in the integrated circuit device so that a screening test can be conducted to screen for a defect (106) in the buried insulator layer by measuring a leakage current.

The disclosure discloses an IGBT module reliability evaluation method and device based on bonding wire degradation, which belong to the field of IGBT reliability evaluation. The realization of the method includes: obtaining a relationship between a IGBT chip conduction voltage drop U.sub.ces and an operating current I.sub.c along with a chip junction temperature T.sub.c; for an IGBT module under test, obtaining the conduction voltage drop U.sub.ces-c of the IGBT chip through the operating current I.sub.c and the chip junction temperature T.sub.c; obtaining an external conduction voltage drop U.sub.ces-m of the IGBT module by using a voltmeter; performing subtraction to obtain a voltage drop at a junction of a IGBT chip and a bonding wire, and combining the operating current to obtain a resistance at the junction; determining that the IGBT module has failed when the resistance at the junction increases to 5% of an equivalent impedance of the IGBT module.

A method for characterizing an integrated circuit that includes ramping the supply voltage to an integrated circuit as a function of time for each of the transistors in the integrated circuit, and measuring a power supply current for the integrated circuit during the ramping of the power supply voltage. The measured peaks in the power supply current are a current pulse that identifies an operation state in which each of the transistors are in an on state. The peaks in the power supply current are compared to the reference peaks for the power supply current for a reference circuit having a same functionality as the integrated circuit to determine the integrated circuit's fitness.

A device for detecting the polarity of a current or voltage, the detection device including a circuit portion with a detection node configured to produce at the detection node a measurement voltage which is an image of a fraction of the detected current or voltage, and a detection circuit with transistor(s), coupled to the detection node, and provided with amplifier(s), with a comparator transistor having a source gate voltage which depends on the measurement voltage. The comparator transistor further includes a source set at a first fixed potential and a source-gate voltage which depends on the measurement voltage or a gate set at a second fixed potential and a source-gate voltage which depends on the measurement voltage, the detection circuit being configured to compare the measurement potential with a threshold and to output a binary detection signal indicating the polarity of the detected current or voltage.

Circuitry for testing an integrated capacitor that includes a first capacitor, a supply node for connecting to a voltage supply, a test node for connecting to the integrated capacitor, and a charge monitoring circuit. The circuitry is operable in a sequence of states including a first state in which the first capacitor is connected to the supply node and is disconnected from the test node so as to charge the first capacitor to a test voltage and a second state in which the first capacitor is disconnected from the supply node and is connected to the test node to apply the test voltage to the integrated capacitor. The charge monitoring circuit is configured to monitor a charge transfer from the first capacitor to the integrated capacitor in said second state and to generate a measurement value based on an amount of the charge transfer.

The present application discloses a method and apparatus for calculating the kink current of SOI device, which is used to solve the problem that the kink current calculation in the prior art is not accurate and is not suitable for circuit simulation. The method includes: obtaining the impact ionization factor, the parasitic transistor effect factor, and the drain saturation current of the SOI device respectively; and calculating the kink current of the SOI device according to the impact ionization factor, the parasitic transistor effect factor, and the drain saturation current.

A method and device for monitoring a multi-die power module in a half-bridge switch configuration are provided. The method and device are designed to set dies in a non conductive state, select one die which is blocking a voltage, inject a current in a gate of the selected die in order to charge an input parasitic capacitance of the selected die, monitor a voltage that is representative of a voltage on the gate of the selected die, and memorize the value of the monitored voltage when the value of the monitored voltage is stabilized.

The disclosure discloses an IGBT module reliability evaluation method and device based on bonding wire degradation, which belong to the field of IGBT reliability evaluation. The realization of the method includes: obtaining a relationship between a IGBT chip conduction voltage drop U.sub.ces and an operating current I.sub.c along with a chip junction temperature T.sub.c; for an IGBT module under test, obtaining the conduction voltage drop U.sub.ces-c of the IGBT chip through the operating current I.sub.c and the chip junction temperature T.sub.c; obtaining an external conduction voltage drop U.sub.ces-m of the IGBT module by using a voltmeter; performing subtraction to obtain a voltage drop at a junction of a IGBT chip and a bonding wire, and combining the operating current to obtain a resistance at the junction; determining that the IGBT module has failed when the resistance at the junction increases to 5% of an equivalent impedance of the IGBT module.

A testing method and apparatus is disclosed for testing an integrated circuit device (100) which has a dedicated ground bias pad (121) connected across a high voltage electrostatic discharge clamp circuit (123) to a well-driving ground pad (122) by applying a first voltage to the dedicated ground bias pad to bias a wafer substrate (101) while simultaneously applying a second voltage to the well-driving ground pad to bias the well region (103), where the first and second voltage create a stressing voltage across a buried insulator layer (102, 105) in the integrated circuit device so that a screening test can be conducted to screen for a defect (106) in the buried insulator layer by measuring a leakage current.

A variety of applications can include systems and methods that include a memory system tester having an analyzer coupled to a test flow controller. The test flow controller can be arranged to generate test signals to a memory system with the analyzer arranged to couple to test pads of a package platform for the memory system. The analyzer can provide data to the test flow controller to conduct testing and/or debugging of the memory system, with the data based on real time monitoring of the test pads of the package platform. In various embodiments, the analyzer can provide data feedback to the test flow controller in real time such that the test flow controller can control the flow of test signals to the memory system in real time. Additional apparatus, systems, and methods are disclosed.