A chamber module and a test handler including the same are disclosed. The chamber module includes a soak chamber providing a temperature adjusting space for adjusting a temperature of semiconductor devices, an elevating member disposed in the soak chamber and for elevating a tray in which the semiconductor devices are accommodated, a guide member extending in a vertical direction in the soak chamber and for guiding movement of the elevating member, and a temperature adjusting part for adjusting a temperature of the guide member.

An electronic device including a processor and a sensor may be provided. The processor obtains a first degree of degradation of a first core based on a first parameter value associated with a lifetime of the first core and a first operating level associated with an operation of the first core. The processor obtains a second degree of degradation of a second core based on a second parameter value associated with a lifetime of the second core and a second operating level associated with an operation of the second core. The processor schedules a task of the first core and the second core based on the first degree of degradation and the second degree of degradation. The sensor provides the first parameter value and the first operating level to the first core and the second parameter value and the second operating level to the second core.

An inspection apparatus includes a stage on which a substrate having an inspection target is placed, a probe card, a light irradiator, and a controller. The probe card has probes that supply a current to the inspection target. The light irradiator irradiates light to heat the substrate. The controller controls the light irradiator to excecute uniformly heating the inspection target by the light from the light irradiator, and heating an outer peripheral portion of the inspection target by the light from the light irradiator.

An aging detector for an electrical circuit component and a method for monitoring an aging of a circuit component includes an input of the aging detector recording a parameter of the circuit component, with the aging circuit being configured to, based on the recorded parameter, determine a corresponding response threshold and/or a response or adapt the response threshold and/or the response, and to initiate the response to the parameter exceeding the specific response threshold.

Examples relate to control apparatus, a control device, a method and a computer program for determining a device-specific supply voltage for a semiconductor device, and to a corresponding semiconductor device and corresponding systems. The control apparatus is configured to obtain measurement data of measurement circuitry of the semiconductor device, the measurement data being related to a progress of aging of the semiconductor device. The control apparatus is configured to determine the device-specific supply voltage of the semiconductor device based on the measurement data. The control apparatus is configured to provide information on the device-specific supply voltage for a supply voltage control apparatus.

A process and system for testing includes: arranging devices in a temperature-controlled environment; applying a negative gate bias voltage (Vgs) to the devices; applying a drain voltage (Vds) to the devices; measuring currents and/or voltages of the devices to generate device test data; determining a failure of one or more of the devices based on the device test data generated from the device currents and/or the voltages to generate failure data; and outputting the failure data for the of devices.

Techniques regarding determining device operability via a metal-induced layer exchange are provided. For example, one or more embodiments described herein can comprise an apparatus, which can comprise a dielectric membrane positioned between an amorphous semiconductor resistor layer and an electrically conductive metal layer. The dielectric membrane can facilitate a metal induced layer exchange that can experiences catalyzation by heat generated from operation of a semiconductor device positioned adjacent to the apparatus.

Embodiments disclosed herein include a thermal testing unit. In an embodiment, the thermal testing unit comprises a nozzle frame, and a nozzle plate within the frame. In an embodiment, the nozzle plate comprises a plurality of orifices through a thickness of the nozzle plate. In an embodiment, the thermal testing unit further comprises a housing attached to the nozzle plate.

Provided is a technique for enhancing the accuracy of deterioration diagnosis in a semiconductor device. The semiconductor device relating to the technique disclosed in the present specification is provided with a case, a semiconductor chip inside the case, a metal wire bonded to an upper surface of the semiconductor chip, at least one test piece inside the case, and a pair of terminals provided outside the case and connected to the test piece. The test piece is separated from the metal wire inside the case.

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.