Abstract: A passivation structure and fabricating method thereof includes providing a chip having a main die region and a scribe line region defined thereon and a plurality of metal pads respectively positioned in the main die region and the scribe line region, forming a first patterned passivation layer having a plurality of first openings and second openings respectively exposing the metal pads in the main die region and the scribe line region on the chip, and forming a second patterned passivation layer filling the first openings in the scribe line region and having a plurality of third openings corresponding to the first openings thus exposing the metal pads in the main die region.

Abstract: A semiconductor device includes: a semiconductor element (1) having an internal circuit (17); and electrode pads (22, 22, . . . ) provided for the semiconductor element (1). The electrode pads (22, 22, . . . ) are electrically connected to the internal circuit (17) via control portions (31) for controlling electrical connection between the electrode pads (22, 22, . . . ) and the internal circuit (17).

Abstract: The present invention relates to methods and apparatus for providing composition control to thin compound semiconductor films for radiation detector and photovoltaic applications. In one aspect of the invention, there is provided a method in which the molar ratio of the elements in a plurality of layers are detected so that tuning of the multi-element layer can occur to obtain the multi-element layer that has a predetermined molar ratio range. In another aspect of the invention, there is provided a method in which the thickness of a sub-layer and layers thereover of Cu, In and/or Ga are detected and tuned in order to provide tuned thicknesses that are substantially the same as pre-determined thicknesses.

Abstract: The present invention provides a signal transmitting/receiving method comprising: disposing a ferromagnetic film between a semiconductor device having an inductor and an external device which includes an external inductor provided in a position corresponding to the inductor of the semiconductor device; disposing the inductor and the external inductor so as to face each other via the ferromagnetic film therebetween; and in a state in which the inductor and the external inductor face each other, transmitting and receiving the signals between the inductor and the external inductor by electromagnetic induction.

Abstract: A wafer translator is provided with a patterned layer of wafer bonding thermoset plastic and is removably attached with a wafer so as to form a wafer/wafer translator pair. The wafer translator acts as a mechanical support during a thinning process as well as during a wafer dicing operation. The singulated integrated circuits are then removed from the wafer translator. In some embodiments, wafer level testing of the integrated circuits on the wafer is performed subsequent to the wafer thinning process but before the wafer and wafer translator are separated. In other embodiments, wafer level testing of the integrated circuits on the wafer is performed subsequent to the wafer dicing operation but before the diced wafer and wafer translator are separated.

Abstract: A semiconductor device manufacturing method includes the steps of: forming a transistor on a surface side of a silicon layer of a silicon-on-insulator substrate, the silicon-on-insulator substrate being formed by laminating a substrate, an insulating layer, and the silicon layer; forming a first insulating film covering the transistor and a wiring section including a part electrically connected to the transistor on the silicon-on-insulator substrate; measuring a threshold voltage of the transistor through the wiring section; forming a supporting substrate on a surface of the first insulating film with a second insulating film interposed between the supporting substrate and the first insulating film; removing at least a part of the substrate and the insulating layer on a back side of the silicon-on-insulator substrate; and adjusting the threshold voltage of the transistor on a basis of the measured threshold voltage.

Abstract: A method of measuring a shifted extent of a shifted epitaxy layer by an N+ buried layer using difference between contact resistances is described. An N-type buried layer comprising a stepped portion is formed at a P-type substrate. An epitaxy layer is formed, comprising a stepped portion, on the N-type buried layer. A plug is formed in the epitaxy layer. An insulating layer is formed on the epitaxy layer. A plurality of contacts are formed in the insulating layer. Resistances of the plurality of contacts are measured and a shifting extent of the stepped portion of the epitaxy layer is calculated using the plurality of contact resistances.

Abstract: A method of measuring a diffusion length of a minority carrier in a silicon wafer by a surface photovoltage method including irradiating the surface-treated silicon wafer with ultraviolet radiation in an oxygen-containing atmosphere, and measuring a diffusion length of a minority carrier in a silicon wafer by a surface photovoltage method.

Abstract: Provided is a semiconductor device in which a connection between connection terminals and land of the semiconductor device can be checked with the semiconductor device kept in a sound condition, the connection not being allowed to be checked with a semiconductor chip. The semiconductor device of the present invention includes: a package substrate; a semiconductor chip mounted on the package substrate; a first land formed in a first principal surface of the package substrate; a second land formed in a second principal surface of the package substrate; first connection terminals connected to the second land and having the connection thereto not allowed to be checked with the semiconductor chip; a connection interconnection for connecting the first land and the second land; a second connection terminal formed in the second principal surface of the package substrate; and a branch interconnection for connecting the connection interconnection and the second connection terminal.

Abstract: In one embodiment, a high voltage element is formed overlying a doped semiconductor region that can be depleted during the operation of the high voltage element includes a conductor overlying a space in a resistor.

Abstract: An interconnect structure includes: a plurality of dielectric layers having aligned process control monitor (PCM) pads, and a conductive structure above a topmost one of the PCM pads. The conductive structure electrically connects the topmost PCM pad to a device under test above a level of the topmost PCM pad. The conductive structure is sized and shaped so as to leave a majority portion of the topmost PCM pad exposed for access by a test probe.

Abstract: A semiconductor integrated circuit device for driving an LCD, COG chip packaging is performed. To achieve this, an elongate and relatively thick gold bump electrode is formed over an aluminum-based pad having a relatively small area. In a wafer probe test performed after formation of the gold bump electrode, a cantilever type probe needle having gold as a main component and having an almost perpendicularly bent tip portion is used. The diameter of this probe needle in the vicinity of its tip is usually almost the same as the width of the gold bump electrode. This makes it difficult to perform the wafer probe test stably. To counteract this, a plurality of bump electrode rows for outputting a display device drive signal are formed such that the width of inner bump electrodes is made greater than the width of outer bump electrodes.

Abstract: The present invention discloses a semiconductor device. The semiconductor device includes an integrated circuit and a connecting component. The integrated circuit includes a first pad; a second pad; a first current guiding circuit, coupled to the first pad and a first reference voltage, for selectively guiding a first specific electrical signal received from the first pad to the first reference voltage; and a second current guiding circuit, coupled to the second pad and a second reference voltage, for selectively guiding a second specific electrical signal received from the second pad to the second reference voltage; and the connecting component is external to the integrated circuit for coupling the first pad and the second pad.

Abstract: In a semiconductor device, electrical measurement data may be obtained with enhanced spatial resolution, for instance from within the entire die region, by providing a distributed sensor structure, each of which may be individually accessed by an appropriate interconnect structure, while nevertheless maintaining the required number of terminals and test signals at a low level.

Abstract: The semiconductor device according to an aspect of the invention includes: an internal circuit area having an internal circuit; an I/O circuit area positioned outside the internal circuit area; and an electrode pad placed across an outer edge of the I/O circuit area. In the electrode pad, an area outside the outer edge of the I/O circuit area is a bonding area, and an area inside the outer edge is a probe area.

Abstract: A manufacturing method for a semiconductor device comprises: mounting a semiconductor element, having an alignment mark, on a substrate; forming a composite of metal film and insulating film such that the surface of the semiconductor element is covered therewith; and removing a part of the composite of metal film and insulating film so as to expose the alignment mark. The position of each electrode of the semiconductor element mounted on the substrate is determined based upon detection results obtained by detection of the exposed alignment mark.

Abstract: A semiconductor manufacturing apparatus includes: an ion source and a beam line for introducing an ion beam into a target film which is formed over a wafer with an insulating film interposed therebetween; a flood gun for supplying the target film with electrons for neutralizing charges contained in the ion beam; a rotating disk for subjecting the target film to mechanical scanning of the ion beam in two directions composed of r-? directions; a rear Faraday cage for measuring the current density produced by the ion beam; a disk-rotational-speed controller and a disk-scanning-speed controller for changing the scanning speed of the target film; and a beam current/current density measuring instrument for controlling, according to the current density, the scanning speed of the target film.

Abstract: A doping process, including applying pressure to at least one first phase of a semiconductor containing an electrically inactive dopant and removing the pressure to cause at least one phase transformation of the semiconductor to at least one second phase, wherein the at least one phase transformation activates the dopant so that the at least one second phase includes at least one doped phase of the semiconductor in which the dopant is electrically active.

Abstract: Provided is a heat treatment apparatus including a treatment chamber housing a silicon substrate, a heater being provided in the treatment chamber and heating the silicon substrate, and an atmosphere adjustment mechanism reducing a concentration of oxygen contained in an atmosphere inside the treatment chamber to less than an oxygen concentration in the air. The atmosphere adjustment mechanism is provided with an oxygen trap, for example.

Abstract: In the method of manufacturing a semiconductor device, first, values of diffusion parameters of a semiconductor device are acquired in a middle of manufacturing the semiconductor device. Next, a target value of another diffusion parameter to be determined by a processing implemented in a subsequent process of the semiconductor device manufacturing process is calculated. The another diffusion parameter is calculated by substituting the acquired values of diffusion parameters and a desired value of an electrical characteristic of the semiconductor device into a predetermined prediction expression. The prediction expression is an expression showing a corresponding relationship between the electrical characteristic and a plurality of types of diffusion parameters of the semiconductor device. Subsequently, processing conditions for the processing implemented in the subsequent process to realize the target value is determined.

Abstract: An FOM (figure of merit) enabling evaluation from a cost aspect, as well as evaluation of electrical performance, is newly proposed to provide a method of manufacturing based on the FOM a semiconductor chip intended for a lower cost production in addition to satisfying electrical performance. An FOMC of a semiconductor chip is defined as the product of a term represented by electrical performance of a substrate S and a term represented by a semiconductor chip cost CC; the FOMC of each of the semiconductor chips on substrates SS, SC of different type is determined by calculation of the product thereof. Based on the magnitudes of the calculation results, a desired substrate is selected from the substrates SS, SC and then a semiconductor chip is fabricated by forming a semiconductor element on the desired substrate selected.

Abstract: A method and apparatus for improving a thin film scribing procedure is presented. Embodiments of the invention include a method and apparatus for determining a scribe setting for removal of an absorber layer of a photovoltaic device that improves contact resistance between a back contact layer and a front contact layer of the device.

Abstract: According to an exemplary embodiment, a method for site-specific trimming of a wafer to provide a target parameter value for a plurality of devices on the wafer includes performing a first measurement of a parameter at a subset of the number of devices on the wafer. The method further includes forming a top layer over the wafer after performing the first measurement. The method further includes performing a second measurement of the parameter at the subset of the devices on the wafer after forming the top layer. The method further includes determining an amount of the top layer to remove across the wafer to provide the target parameter value for the devices by utilizing the first and second measurements of the parameter. The method can be utilized to, for example, achieve a more uniform characteristic frequency for bulk acoustic wave (BAW) filters.

Abstract: A method of measuring a resistivity of a sidewall of a contact hole formed in a semiconductor device, wherein said semiconductor device includes a first electrode formed on a substrate; a second electrode formed on the first electrode with an insulating film in between; a resist pattern formed on the first electrode and the second electrode; a contact hole formed in the first electrode and the second electrode; and an organic film deposited on the sidewall of the contact hole, includes the steps of: placing a probe needle on the first electrode and the second electrode so that the probe needle contacts with the first electrode and the second electrode several times; establishing electrical conductivity of the probe needle relative to the first electrode and the second electrode; and measuring the resistivity of the organic film between the first electrode and the second electrode.

Abstract: A method, for reducing occurrence of short-circuit failure in an organic functional device (101, 201, 401) comprising a first transparent electrode layer (104), a second electrode layer (105) and an organic functional layer (103) sandwiched between said first and second electrode layers (104; 105). The method comprises the steps of identifying (301) a portion of said organic functional device (101, 201, 401), said portion containing a defect (102a-g) leading to an increased risk of short-circuit failure, selecting (302) a segment (108a-g) of said second electrode layer (105), said segment corresponding to said portion, and electrically isolating (303) said segment (108a-g) from a remainder of said second electrode layer (105), thereby eliminating short-circuit failure resulting from said defect (102a-g).

Abstract: A product workpiece can be processed to form product dice. A test mask can allow intentional changes to be made to a feature on the product workpiece to examine how the altered feature performs. Use of the test mask may be used or not used based on the needs or desires of skilled artisans. By using the test mask, a separate dedicated test structure is not required to be formed in a scribe lane or within an area that could otherwise be used for a product die. Thus, the sampling level by using the test mask can be varied. Also, separate test workpieces, which may not be processed using a significantly different process flow or at significantly different times as compared to product workpieces, are not required. The product workpiece with the altered feature can be electrically tested without the need to form test or bond pads.

Abstract: A method for fabricating a semiconductor component with an encapsulated through wire interconnect includes the steps of providing a substrate having a first side, a second side and a substrate contact; forming a via in the substrate contact and the substrate to the second side; placing a wire in the via; forming a first contact on the wire proximate to the first side and a second contact on the wire proximate to the second side; and forming a polymer layer on the first side leaving the first contact exposed. The polymer layer can be formed using a film assisted molding process including the steps of: forming a mold film on tip portions of the bonding members, molding the polymer layer, and then removing the mold film to expose the tip portions of the bonding members. The through wire interconnect provides a multi level interconnect having contacts on opposing sides of the semiconductor substrate.

Abstract: Noise measuring circuitry of the present invention can be used to observe power supply noise waveforms, ground level noise waveforms, and a spatial distribution of noise at different positions in an integrated circuit having plural circuit blocks that perform digital signal processing, by being integrated into the integrated circuit (i.e., embedded), distributed at different positions. The distributed noise measuring circuitry can be manufactured using a CMOS process to manufacture the integrated circuit. The power supply noise measuring circuit and the ground level noise measuring circuit comprise a source follower, a select read out switch, and source-grounded amplifier. These noise measuring circuits can be configured by several (about 6) MOS transistors, so the layout for the measuring circuit can be small and can be achieved by using a logic gate circuit of the same size as that of a standard cell type logic gate circuit.

Abstract: A protection system implemented on one die of a multi-die package provides a discharge path for excess voltages incurred on one or more other die of the package. Ground paths are provided for certain circuitry in the package that have high noise-sensitivity, and ground paths are provided for certain circuitry in the package that have low noise-sensitivity relative to the high noise-sensitivity circuitry. The grounds of high noise-sensitivity circuitry of multiple die are shorted together, resulting in a common high noise-sensitivity ground. The grounds of low noise-sensitivity circuitry of multiple die are shorted together, resulting in a common low noise-sensitivity ground. A pre-designated removable path is included on the package external to the die, which shorts the common high noise-sensitivity ground and the common low noise-sensitivity ground. The removable path may be removed during manufacturing, if noise present on the shorted grounds results in unacceptable performance degradation.

Abstract: A serpentine double gated diode array for monitoring stress induced defects is disclosed. The diode array is configured with adjacent gate segments and gate loops in close proximity to active areas to maximize a sensitivity to stress induced defects. The diode array is compatible with conventional electrical testing. Scanning capacitance microscopy (SCM) and scanning spreading resistance microscopy (SSRM) may be used to isolate individual stress induced defects. Variations in the gate configuration allow estimation of effects of circuit layout on formation of stress induced defects.

Abstract: A pair of split-gate fin field effect transistors (finFETs) in an IC, each containing a signal gate and a control gate, in which an adjustable voltage source, preferably in the form of a digital-to-analog-converter (DAC), is connected to the control gate of one of the finFETs, is disclosed. Threshold measurement circuits on the signal gates enable a threshold adjustment voltage from the adjustable voltage source to reduce the threshold mismatch between the finFETs. Adding a second DAC to the second finFET allows a simpler DAC design. Threshold correction may be performed during the operational life of the IC. Implementations in a differential input stage of an amplifier and in a current mirror circuit are described.

Abstract: The present invention provides a method for evaluating a semiconductor wafer, including at least: forming an oxide film on a front surface of a semiconductor wafer; partially removing the oxide film to form windows at two positions; diffusing a dopant having a conductivity type different from a conductivity type of a semiconductor as an evaluation target through the windows at the two positions and forming diffused portions in the semiconductor as the evaluation target to form PN junctions; and performing leakage current measurement and/or DLTS measurement in a part between the two diffused portions to evaluate the semiconductor wafer. As a result, there is provided the method for evaluating a semiconductor wafer that can perform junction leakage current measurement or DLTS measurement to easily evaluate a quality of the inside of the semiconductor wafer. In particular, there can be provided the method that can evaluate not only a PW or an EPW but also the inside of an SOI layer of an SOI wafer.

Abstract: An adapter board includes a package substrate having a first surface and a second surface and further including a board having wirings formed therein, pads disposed in the device side, and the pads disposed in the bump side, an insulating resin layer joined to the first surface, through holes formed in the positions corresponding to the pads in the insulating resin layer, vias formed in the through holes, and pads covering the through holes, wherein the pads are electrically coupled to the pads through the wirings, and the pads are electrically coupled to the pads through the vias.

Abstract: A semiconductor device that suppresses partial discharging to a semiconductor substrate caused by local concentration of current. The semiconductor device includes a semiconductor substrate, a gate electrode buried in the semiconductor substrate, a conductor buried in the semiconductor substrate further inward from the gate electrode, a wiring layer formed in the semiconductor substrate in connection with the conductor, and an insulation film arranged between the gate electrode and the conductor. The conductor is higher than the surface of the semiconductor substrate.

Abstract: Systems and methods for forming an encapsulated device include a hermetic seal which seals an insulating environment between two substrates, one of which supports the device. The hermetic seal is formed by an alloy of two metal layers, one deposited on a first substrate and the other deposited on the second substrate, along with a raised feature formed on the first or the second substrate. At least one of the metal layers may be deposited conformally over the raised feature. The raised feature penetrates the molten material of the first or the second metal layers during formation of the alloy, and produces a spectrum of stoichiometries for the formation of the desired alloy, as a function of the distance from the raised feature. At some distance from the raised feature, the proper ratio of the first metal to the second metal exists to form an alloy of the preferred stoichiometry.

Abstract: One embodiment provides a circuit arrangement integrated in a semiconductor body. At least one power semiconductor component integrated in the semiconductor body and having a control connection and a load connection is provided. A resistance component is thermally coupled to the power semiconductor component and likewise integrated into the semiconductor body and arranged between the control connection and the load connection of the power semiconductor component. The resistance component has a temperature-dependent resistance characteristic curve. A driving and evaluation unit is designed to evaluate the current through the resistance component or the voltage drop across the resistance component and provides a temperature signal dependent thereon.

Abstract: One embodiment of the present invention relates to a scribe seal integrity detector. In this embodiment a scribe seal integrity detector is formed in an integrated circuit chip die. The scribe seal integrity comprises a scribe seal structure that extends along at least a portion of the periphery of the integrated chip die and a detector test structure. The detector test structure and the scribe seal form an electrical system configured to be accessed for a monitoring of one or more electrical parameters to determine and characterize scribe seal integrity of the integrated circuit chip die. The results of the electric measurements are analyzed for statistically relevant reliability characterization. Other methods and circuits are also disclosed.

Abstract: A method is provided for detecting laser optical paths in integrated circuit (IC) packages. The method provides an IC die encapsulated as a package in a compound of glass spheres and epoxy. Power is supplied to the IC. The IC is scanned with a laser. Typically, a laser wavelength is used that is minimally absorbed by the glass spheres in the epoxy compound of the IC package, and changes in current to the IC are detected. A detected current change is cross-referenced against a scanned IC package surface region. This process identifies an optical pathway underlying the scanned IC package surface region. In some aspects, this process leads to the identification of a glass sphere-collecting package structure underlying the optical pathway. Examples of a glass sphere-collecting structure might include an inner lead wire, lead frame edge, or die edge.

Abstract: A thin silicon solar cell having a back dielectric passivation and rear contact with local back surface field is described. Specifically, the solar cell may be fabricated from a crystalline silicon wafer having a thickness from 50 to 500 micrometers. A barrier layer and a dielectric layer are applied at least to the back surface of the silicon wafer to protect the silicon wafer from deformation when the rear contact is formed. At least one opening is made to the dielectric layer. An aluminum contact that provides a back surface field is formed in the opening and on the dielectric layer. The aluminum contact may be applied by screen printing an aluminum paste having from one to 12 atomic percent silicon and then applying a heat treatment at 750 degrees Celsius.

Abstract: A semiconductor laser device manufacturing method includes, sequentially, a first aging step S1, a first inspection step S2, a mounting step S3, a second aging step S4 and a second inspection step S5. Since the first aging step S1 on a semiconductor laser chip with a high-temperature direct current conduction is performed before the mounting step S3, threshold current and drive current of the semiconductor laser chip before mounting can be reduced.

Abstract: A semiconductor device for fingerprint sensors reduces a mounting area of the semiconductor device and improves a processing capacity of assembling and testing process. The semiconductor device has a functional surface that provides a predetermined function. A semiconductor element has a circuit formation surface on which a plurality of electrodes are formed and a back surface opposite to the circuit formation surface. A part of the circuit formation surface functions as the functional surface. Wiring is formed on the back surface of the semiconductor element. A plurality of connection parts extends between the circuit formation surface and the back surface of the semiconductor element so as to electrically connect the electrodes to the wiring. A plurality of external connection terminals are exposed outside the semiconductor device on a side of the back surface of the semiconductor element.

Abstract: An encapsulated device includes a micro device on a substrate, a micro chamber that encapsulates the micro device on the substrate; and a layer of hermetic-sealing material that provides at least some degree of hermeticity on one or more outer surfaces of the micro chamber to at least partially hermetically seal the micro device in the micro chamber.

Abstract: A method for creating a testing pattern for sampling the sheet resistance of a test wafer for tuning an annealing process includes establishing a center point for the wafer and determining a plurality of sample points having a radial displacement from the center point of the wafer and an angular displacement, the radial displacement of successive sample points decreasing in radial distance from one another as the distance from the center point increases and the angular displacement between each successive sample point being constant.

Abstract: A process management method for managing manufacturing variability of an interconnection included in a semiconductor device is provided. The process management method includes: calculating interconnect resistance and interconnect capacitance regarding an interconnection included in the semiconductor device, under a condition that manufacturing variability of a width and a thickness of the interconnection is expressed by points on a predetermined circle of equal probability of a joint probability density function; and defining, based on the calculated interconnect resistance and interconnect capacitance, a variation range of interconnect resistance and interconnect capacitance caused by manufacturing variability. The variation range is defined two-dimensionally in a coordinate system where a first axis represents interconnect resistance and a second axis represents interconnect capacitance.

Abstract: Test structures for electrically detecting BEOL failures are provided. In an embodiment, the structure comprises: an input/output connection disposed above a primary conductive pad which is embedded in an insulator; a dielectric layer disposed upon the insulator; a primary via extending through the dielectric layer down to the primary conductive pad for providing electrical connection between the input/output connection and the primary conductive pad; and a secondary via filled with a conductive material in electrical connection with the input/output connection, the secondary via extending through the dielectric layer down to a secondary interconnect in electrical connection with a secondary conductive pad that is insulated from the primary conductive pad.

Abstract: The present invention provides a method for evaluating dopant contamination of a semiconductor wafer, wherein a resistivity of a bulk portion of the semiconductor wafer is measured by an eddy current method, a resistivity in a surface layer of the semiconductor wafer is measured by a surface photovoltage method, and an amount of dopant contamination of the semiconductor wafer is calculated from a difference between a value of the resistivity of the bulk portion measured by the eddy current method and a value of the resistivity in the surface layer measured by the surface photovoltage method. As a result of this, it is possible to provide the method for evaluating dopant contamination of a semiconductor wafer, which can measure the amount of dopant contamination of a whole surface layer of the semiconductor wafer without contact, nondestructively, and accurately.

Abstract: An embodiment for manufacturing an electronic circuit forms at least one first structure on a semiconductor substrate, determines at least one electrically defined characteristic of the at least one first structure, selects a reticle corresponding to the measured characteristic, and forms at least one additional structure on the semiconductor substrate with the selected reticle.

Abstract: A method of fabricating a semiconductor device according to one embodiment includes: forming a plurality of Si-based pattern portions above a semiconductor substrate, the plurality of Si-based pattern portions being adjacent in a direction substantially parallel to a surface of the semiconductor substrate via insulating films; forming a metal film above the plurality of Si-based pattern portions and the insulating films so as to contact with the plurality of Si-based pattern portions; processing whole areas or upper portions of the plurality of Si-based pattern portions into a plurality of silicide layers by a silicidation reaction between the plurality of Si-based pattern portions and the metal film by heat treatment; and removing the plurality of silicide layers formed above the insulating films by applying planarizing treatment to the plurality of silicide layers.

Abstract: Methods for processing semiconductor wafers are described herein. One embodiment includes removing portions of a first side of the semiconductor wafer to form a number of trenches of a particular depth in rows and columns. The method further includes forming a passivation layer on side walls of the number of trenches. The method also includes cutting a second side of the semiconductor wafer in rows and columns aligned with the number of trenches such that the semiconductor wafer singulates into a number of dice.

Abstract: In the present invention, a method of testing an unpackaged integrated circuit die is disclosed. The die has a plurality of first input/output pads. A serial electrical connection is fabricated in the die between all of the input/output pads of the die which are not of the first plurality (hereinafter: “second plurality”). The second plurality has a start input and an end output. The start input of the second plurality is connected to the output of one selected input buffer of the input pad of the first plurality and the end output of the second plurality is also connected to the input of one selected output pad of the first plurality. The second plurality of input/output pads are tested through selected input pad and selected output pad of the first plurality without electrical probes making contact during the wafer sort. The present invention also relates to an integrated circuit die so fabricated as to facilitate testing.