An electronic device comprising a semiconductor chip which comprises a plurality of structures formed in the semiconductor chip, wherein the semiconductor chip is a member of a set of semiconductor chips, the set of semiconductor chips comprises a plurality of subsets of semiconductor chips, and the semiconductor chip is a member of only one of the subsets. The plurality of structures of the semiconductor chip includes a set of common structures which is the same for all of the semiconductor chips of the set, and a set of non-common structures, wherein the non-common structures of the semiconductor chip of the subset is different from a non-common circuit of the semiconductor chips in every other subset. At least a first portion of the non-common structures and a first portion of the common structures form a first non-common circuit, wherein the first non-common circuit of the semiconductor chips of each subset is different from a non-common circuit of the semiconductor chips in every other subset. At least a second portion of the non-common structures is adapted to store or generate a first predetermined value which uniquely identifies the first non-common circuit, wherein the first predetermined value is readable from outside the semiconductor chip by automated reading means.

Methods, systems, and apparatuses are described for integrated circuit controlled ejection system (ICCES) for massively parallel integrated circuit assembly (MPICA). A unique Integrated Circuit (IC) die ejection head assembly system is described, which utilizes Three-Dimensional (3D) printing to achieve very high resolution manufacturing to meet the precision tolerances required for very small IC die sizes.

An integrated circuit includes an array of devices with a logic pattern to implement a physically unclonable function (PUF) for chip authentication. The logic pattern is determined in accordance with processing variations during the manufacturing. The array of devices includes one or more components having a first state and one or more components having a second state. A combination of the first and second states provides the logic pattern.

A semiconductor device 1a includes: a first external terminal 31 to which a first voltage is to be applied; a second external terminal 32 to which a second voltage is to be applied; a third external terminal 33; first wiring 17 connected to the first external terminal 31; second wiring 18 connected to the second external terminal 32; an internal block circuit 11 connected to the first wiring 17; a first resistor 12 and a transistor 14 serially connected between the first wiring 17 and the second wiring 18; and a second resistor 13 connected between the first wiring 17 and the second wiring 18. The transistor 14 turns on or off based on a test signal fed from the third external terminal 33. This configuration enables product identification using a resistance value, even if a predetermined resistance value cannot be changed.

Various methods and structures for fabricating a semiconductor chip structure comprising a chip identification fingerprint layer. A semiconductor chip structure includes a substrate and a chip identification layer disposed on the substrate, the chip identification layer comprising random patterns of electrically conductive material in trenches formed in a semiconductor layer. The chip identification layer is sandwiched between two layers of electrodes that have a crossbar structure. A first crossbar in the crossbar structure is located on a first side of the chip identification layer and includes a first set of electrical contacts in a first grid pattern contacting the first side of the chip identification layer. A second crossbar in the crossbar structure is located on a second side of the chip identification layer and includes a second set of electrical contacts in a second grid pattern contacting the second side of the chip identification layer.

The various technologies presented herein relate to measuring a signal generated by a die-based test circuit incorporated into an IC and utilizing the measured signal to authenticate the IC. The signal can be based upon a sensor response generated by the test circuit fabricated into the die, wherein the sensor response is based upon a property of the die material. The signal can be compared with a reference value obtained from one or more test circuit(s) respectively located on one or more reference dies, wherein the reference dies are respectively cut from different wafers, and the location at which the reference dies were cut is known. If the measured signal matches the reference value, the die is deemed to be from the same cut location as the dies from which the reference value was obtained. If the measured signal does not match the reference value, the die is not authenticated.

Embodiments herein include methods, systems, and apparatuses for die screening using inline defect information. Such embodiments may include receiving a plurality of defects, receiving wafersort electrical data for a plurality of dies, classifying each of the defects as a defect-of-interest or nuisance, determining a defect-of-interest confidence for each of the defects-of-interest, determining a die return index for each of the dies containing at least one of the defects-of-interest, determining a die return index cutline, and generating an inking map. Each of the defects may be associated with a die in the plurality of dies. Each of the dies may be tagged as passing a wafersort electrical test or failing the wafersort electrical test. Classifying each of the defects as a defect-of-interest or nuisance may be accomplished using a defect classification model, which may include machine learning. The inking map may be electronically communicated to an inking system.

Several embodiments of reclaimable semiconductor device packages and assemblies are disclosed herein. A semiconductor device assembly (100) includes a package (101) having a housing (102) and a package contact (104) arranged to receive a signal indicative of a reclamation state. A plurality of modules of semiconductor dies (106) are located within the housing and electrically coupled to the package contact (104). The dies (106) of the first and second modules dies are configured to store a module configuration state. The first and second modules (107a, 107b) are enabled for operation based, at least in part, on the reclamation state and the module configuration state.

A mechanism is provided to secure integrated circuit devices that combines a high degree of security with a low overhead, both in area and cost, thereby making it appropriate for smaller, cheaper integrated circuits. A determination is made whether a device die is on a wafer or if the device die is incorporated into a package. Only if the device die is incorporated in a package can the functional logic of device die be activated, and then only if a challenge-response query is satisfied. In some embodiments, a random number generator is used during wafer testing to form a pair of numbers, along with a die identifier, that is unique for each device die. A final test is then performed in which the device die can be activated if the device die is incorporated in a package, and the die identifierrandom number pair is authenticated.

A method for marking a semiconductor substrate at the die level for providing unique authentication and serialization includes projecting a first pattern of actinic radiation onto a layer of photoresist on the substrate using mask-based photolithography, the first pattern defining semiconductor device structures and projecting a second pattern of actinic radiation onto the layer of photoresist using direct-write projection, the second pattern defining a unique wiring structure having a unique electrical signature.