A method of pressing solder bumps using a pressing apparatus before testing a wafer, including loading the wafer into the pressing apparatus, where the wafer includes a number of chips, and the wafer is aligned with respect to a test head of the pressing apparatus. The test head includes a substrate which has pressing structures arranged across a surface of the substrate facing the wafer. The pressing structures contact the solder bumps, where the solder bumps include a first surface topology and the pressing structures include a pressing surface topology prior to the contact. The caused contact includes altering a shape of each of the plurality of solder bumps, such that the plurality of solder bumps then a second surface topology after the caused contact, and the second surface topology of the solder bumps matches the pressing surface topology after the caused contact.

A method of pressing solder bumps using a pressing apparatus before testing a wafer, including loading the wafer into the pressing apparatus, where the wafer includes a number of chips, and the wafer is aligned with respect to a test head of the pressing apparatus. The test head includes a substrate which has pressing structures arranged across a surface of the substrate facing the wafer. The pressing structures contact the solder bumps, where the solder bumps include a first surface topology and the pressing structures include a pressing surface topology prior to the contact. The caused contact includes altering a shape of each of the plurality of solder bumps, such that the plurality of solder bumps then a second surface topology after the caused contact, and the second surface topology of the solder bumps matches the pressing surface topology after the caused contact.

A probe head that contains a coining surface and a plurality of probe tips integrated on a same side of the probe head is provided. The probe head has a first portion and a laterally adjacent second portion, wherein the first portion of the probe head contains the coining surface, and the second portion of the probe head contains the plurality of the probe tips. Each probe tip may, in some embodiments, extend outwards from a probe pedestal that is in contact with the second portion of the probe head. The probe head is traversed across the surface of a semiconductor wafer containing a plurality of solder bump arrays such that the coining surface contacts a specific array of solder bumps prior to contacting of the same specific array of solder bumps with the probe tips.

The Configurable Vertical Integration [CVI] invention pertains to methods and apparatus for the enhancement of yields of 3D or stacked integrated circuits and herein referred to as a CVI Integrated Circuit [CVI IC]. The CVI methods require no testing of circuit layer components prior to their fabrication as part of a 3D integrated circuit. The CVI invention uses active circuitry to configure the CVI IC as a means to isolate or prevent the use of defective circuitry. CVI circuit configuration method can be predominately described as a large grain method.

A testing method including the following steps is provided. A lead frame is provided, wherein the lead frame includes a frame body and a plurality of lead frame units which are connected with each other through the frame body and are arranged in array. Each of the lead frame units includes at least one first pin connected with the frame body and a plurality of second pins which are connected with each other. A plurality of controllers are bonded with the lead frame units and each of the controllers is electrically connected with the corresponding lead frame unit. The frame body of each of the lead frame units is electrically isolated from the second pins. A first electrical testing is performed to each of the lead frame units carrying the controllers.

A system includes an inert gas supply, a soak chamber, a test chamber, a transfer zone, and a heater. The soak chamber soaks an integrated circuit (IC) device in the inert gas prior to testing. The test chamber includes contact pins for testing the IC device in the inert gas by contacting the contact pins to leads of the IC device. The transfer zone is to transfer the IC device from the soak chamber to the test chamber. The heater heats the inert gas supplied to the soak chamber and the test chamber.

A probe head that contains a coining surface and a plurality of probe tips integrated on a same side of the probe head is provided. The probe head has a first portion and a laterally adjacent second portion, wherein the first portion of the probe head contains the coining surface, and the second portion of the probe head contains the plurality of the probe tips. Each probe tip may, in some embodiments, extend outwards from a probe pedestal that is in contact with the second portion of the probe head. The probe head is traversed across the surface of a semiconductor wafer containing a plurality of solder bump arrays such that the coining surface contacts a specific array of solder bumps prior to contacting of the same specific array of solder bumps with the probe tips.

The present invention relates to a method and an apparatus for a resurfaceable contact pad that uses an epoxy to encapsulate contact pads so that the epoxy and encapsulated contact pads are coplanar on a silicon redistribution interposer. These redistribution interposers electrically connect a wafer semi-conductor to a probe card where it is necessary to convert the course pad arrangement of one with a fine pad arrangement of the other through the use of an interposer board. The present invention relates to an apparatus and a method creates resurfaceable contact pads which may be resurfaced one or multiple times with an abrasive sanding operation to recreate a coplanar surface should any contact pad surfaces become damaged, allowing for a more cost-effective repair.

The present invention relates to a method and an apparatus for a resurfaceable contact pad that uses an epoxy to encapsulate contact pads so that the epoxy and encapsulated contact pads are coplanar on a silicon redistribution interposer. These redistribution interposers electrically connect a wafer semi-conductor to a probe card where it is necessary to convert the course pad arrangement of one with a fine pad arrangement of the other through the use of an interposer board. The present invention relates to an apparatus and a method creates resurfaceable contact pads which may be resurfaced one or multiple times with an abrasive sanding operation to recreate a coplanar surface should any contact pad surfaces become damaged, allowing for a more cost-effective repair.

Reverse decoration can be used to detect defects in a device. The wafer can include NAND stacks or other devices. The defect can be a channel bridge, a void, or other types of defects. Reverse decoration can preserve a defect and/or can improve defect detection. A portion of a layer may be removed from a device. A layer also may be added to the device, such as on the defect, and some of the layer may be removed.