In one embodiment, a device comprises: a first die having disposed thereon a first plurality of latches wherein ones of the first plurality of latches are operatively connected to an adjacent one of the first plurality of latches; and a second die having disposed thereon a second plurality of latches wherein ones of the second plurality of latches are operatively connected to an adjacent one of the second plurality of latches. Each latch of the first plurality of latches on said first die corresponds to a latch in the second plurality of latches on said second die. Each set of corresponding latches are operatively connected. A scan path comprises a closed loop comprising each of said first and second plurality of latches. One of the second plurality of latches is operatively connected to another one of the second plurality of latches via an inverter.

Electrical current flow in a ball grid array (BGA) package can be measured by an apparatus including an integrated circuit (IC) electrically connected to the BGA package. Solder balls connect the BGA package to a printed circuit board (PCB) and are arranged to provide a contiguous channel for a current sense wire. A subset of solder balls is electrically connected to supply current from the PCB through the BGA package to the IC. The current sense wire is attached to the upper surface of the PCB, within the contiguous channel, and surrounds the subset of solder balls. An amplifier is electrically connected to the current sense wire ends to amplify a voltage induced on the current sense wire by current flow into the BGA package. A sensing analog-to-digital converter (ADC) is electrically connected to convert a voltage at the output of the amplifier into digital output signals.

A system and method for evaluating the reliability of semiconductor die packages are configured to sort a plurality of semiconductor dies with a Known Good Die (KGD) subsystem based on a comparison of an inline part average testing (I-PAT) score of each of the plurality of semiconductor dies to a plurality of I-PAT score thresholds, where the semiconductor die data includes the I-PAT score for each of the plurality of semiconductor dies, where the I-PAT score represents a weighted defectivity of the corresponding semiconductor die. The semiconductor dies may be filtered to remove at-risk semiconductor dies prior to sorting. The semiconductor die data may be received from a plurality of semiconductor die supplier subsystems. The KGD subsystem may transmit semiconductor die reliability data about the sorted plurality of semiconductor dies to a plurality of semiconductor die packager subsystems.

Chip packages with improved tamper resistance and methods of using such chip packages to provide improved tamper resistance. A lead frame includes a die attach paddle, a plurality of outer lead fingers, and a plurality of inner lead fingers located between the outer lead fingers and the die attach paddle. A chip is attached to the die attach paddle. The chip includes a surface having an outer boundary and a plurality of bond pads arranged proximate to the outer boundary. A first plurality of wires extend from the outer lead fingers to respective locations on the surface of the chip that are interior of the outer boundary relative to the bond pads. A tamper detection circuit is coupled with the first plurality of wires. A second plurality of wires extend from the inner lead fingers to the bond pads on the chip. The second plurality of wires are located between the lead frame and the first plurality of wires.

A system may include a wafer that includes ICs and defines cavities. Each cavity may be formed in a BEOL layer of the wafer and proximate a different IC. The system may also include an interposer that includes a transparent layer configured to permit optical signals to pass through. The interposer may also include at least one waveguide located proximate the transparent layer. The at least one waveguide may be configured to adiabatically couple at least one optical signal out of the multiple ICs. Further, the interposer may include a redirecting element optically coupled to the at least one the waveguide. The redirecting element may be located proximate the transparent layer and may be configured to receive the at least one optical signal from the at least one waveguide. The redirecting element may also be configured to vertically redirect the at least one optical signal towards the transparent layer.

A testing system includes a subtractor and a divider. The subtractor is configured to receive a first voltage of a circuit being tested and a second voltage of the circuit, and to derive a difference between the first voltage and the second voltage. The divider is configured to receive the difference between the first voltage and the second voltage, and to derive a resistance of the circuit by dividing (i) the difference between the first voltage and the second voltage by (ii) a difference between a first current applied to the circuit and a second current applied to the circuit. The first voltage is corresponding to the first current, and the second voltage is corresponding to the second current.

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.

A method is provided and includes several operations: testing multiple scan chains in multiple shift cycles to obtain multiple values; determining at least one fail chain in the scan chains and determining at least one fail shift cycle corresponding to at least one fail value in the values; mapping the at least one fail chain and the at least one fail shift cycle to the scan chains to identify the at least one fail flip flop; and identifying at least one fault site corresponding to the at least one fail flip flop.

A semiconductor package testing apparatus comprises a package holder for holding a semiconductor package and which is positionable together with the semiconductor package at a test contactor station. There are probe pins located at the test contactor station for contacting a bottom surface of the semiconductor package and which are configured to apply an upwards force on the semiconductor package during testing of the semiconductor package. A restraining mechanism that is movable from a first position remote from the package holder and a second position over the package holder is configured to restrict lifting of the semiconductor package by the probe pins during testing of the semiconductor package when the restraining mechanism is at its second position.

A capacitive test apparatus for testing an electronic device contained within a package, the apparatus comprising: a plurality of conductive pads in electrical communication with the processor, wherein the plurality of conductive pads are configured to align with electrodes of the electronic device during testing and capacitively couple electrical stimuli to the electrodes via the package; processing circuitry configured to: apply the electrical stimuli to the plurality of conductive pads; receive one or more response signals induced by the electrical stimuli coupled through the package; and determine one or more electrical characteristics of the electronic device based on the one or more response signals.