Abstract: An architecture of the layout of the MTCMOS standard cell designed for low power consumption is supplemented so that the pick-up cells are included in the power line of the MTCMOS cell. Therefore, when the logic circuit is constructed using the library layout of the MTCMOS cell in which the related pick-up cells are not included, pick-up cells consisting of only the ends of the pick-up cells are not needed every 50 ?m during the placement of the MTCMOS standard cell. The flexibility of the cell placement may thereby be improved. In addition, since additional space for the pick-up cells is not required, the size of the MTCMOS may be reduced, saving space on the semiconductor substrate.

Abstract: In one embodiment, a semiconductor memory device includes a substrate having first and second active regions. The first active region includes a first source and drain regions and the second active region includes a second source and drain regions. A first interlayer dielectric is located over the substrate. A first conductive structure extends through the first interlayer dielectric. A first bit line is on the first interlayer dielectric. A second interlayer dielectric is on the first interlayer dielectric. A contact hole extends through the second and first interlayer dielectrics. The device includes a second conductive structure within the contact hole and extending through the first and second interlayer dielectrics. A second bit line is on the second interlayer dielectric. A width of the contact hole at a bottom of the second interlayer dielectric is less than or substantially equal to a width at a top of the second interlayer dielectric.

Abstract: Design time (TAT) is reduced in a layout design of a semiconductor integrated circuit having a well supplied with a potential different from a substrate potential. A layout design method of the present invention includes preparing a first cell pattern placed on a semiconductor substrate of a first conductive type, preparing a second cell pattern having a deep well of a second conductive type, placing the first cell pattern in a first circuit region, and placing the second cell pattern in a second region different from the first circuit region. This reduces TAT in chip design.

Abstract: A process for forming active transistors for a semiconductor memory device by the steps of: forming transistor gates having generally vertical sidewalls in a memory array section and in periphery section; implanting a first type of conductive dopants into exposed silicon defined as active area regions of the transistor gates; forming temporary oxide spacers on the generally vertical sidewalls of the transistor gates; after the step of forming temporary spacers, implanting a second type of conductive dopants into the exposed silicon regions to form source/drain regions of the active transistors; after the step of implanting a second type of conductive dopants, growing an epitaxial silicon over exposed silicon regions; removing the temporary oxide spacers; and forming permanent nitride spacers on the generally vertical sidewalls of the transistor gates.

Abstract: A semiconductor device includes an Nch transistor having a first gate electrode and a Pch transistor having a second gate electrode. The first gate electrode and the second gate electrode are made of materials causing stresses of different magnitudes.

Abstract: An impact sensor comprises a silicon substrate; an insulating layer formed over the silicon substrate; a plurality of beams having flexibility that are formed of conductive silicon material; a fixing portion to fix a fixed end of each of the beams, the fixing portion being formed of conductive silicon material; a fixed end line at whose one end is formed the fixing portion, the fixed end line being formed of conductive silicon material on the insulating layer; and a free end line having a pressing portion that faces a free end of each of the beams via a space, the free end line being formed of conductive silicon material on the insulating layer. Respective beam widths, each measured in a direction orthogonal to a length direction joining the fixed end and the free end, of the plurality of beams are set different from each other, thus reducing the space occupied by the sensor.

Abstract: The present invention is directed to structures and methods of fabricating electromechanical memory cells having nanotube crossbar elements. Such memory cells include a substrate having transistor with a contact that electrically contacts with the transistor. A first support layer is formed over the substrate with an opening that defines a lower chamber above the electrical contact. A nanotube crossbar element is arranged to span the lower chamber. A second support layer is formed with an opening that defines a top chamber above the lower chamber, the top chamber including an extension region that extends beyond an edge of the lower chamber to expose a portion of the top surface of the first support layer. A roof layer covers the top of the top chamber and includes an aperture that exposes a portion of the extension region of the top chamber and includes a plug that extends into the aperture in the roof layer to seal the top and bottom chambers.

Abstract: A microelectromechanical system (MEMS) device includes a semiconductor substrate, a MEMS including a fixed electrode and a movable electrode formed on the semiconductor substrate through an insulating layer, and a well formed in the semiconductor substrate below the fixed electrode. The well is one of an n-type well and a p-type well. The p-type well applies a positive voltage to the fixed electrode while the n-type well applies a negative voltage to the fixed electrode.

Abstract: Systems and methods are provided for shielding integrated circuits from electromagnetic or electrostatic fields by locating an active device layer between two conductors that are electrically coupled together. In certain embodiments, a sensor comprises a conductive substrate that provides structural support and shielding to circuit elements in a semiconductor device layer. The device layer is between the conductive substrate and a shield layer that are electrically coupled together to create a shield or “Faraday box.” In certain embodiments, the device layer is substantially isolated from the conductive substrate and the shield layer by insulative layers. In certain embodiments, an input voltage powers the device layer and is also coupled to the substrate and the shield layer. Thus, the conductive substrate and the shield layer absorb and/or repel electrostatic charges or ions in a medium surrounding the sensor.

Abstract: A STT-MRAM integration scheme is disclosed wherein the connection between a MTJ and CMOS metal is simplified by forming an intermediate via contact (VAC) on a CMOS landing pad, a metal (VAM) pad that contacts and covers the VAC, and a MTJ on the VAM. A dual damascene process is performed to connect BIT line metal to CMOS landing pads through VAC/VAM/MTJ stacks in a device region, and to connect BIT line connection pads to CMOS connection pads through BIT connection vias outside the device region. The VAM pad is a single layer or composite made of Ta, TaN, or other conductors which serves as a diffusion barrier, has a highly smooth surface for MTJ formation, and provides excellent selectivity with refill dielectric materials during a chemical mechanical polish process. Each VAC is from 500 to 3000 Angstroms thick to minimize additional circuit resistance and minimize etch burden.

Abstract: A photoelectric conversion apparatus has a plurality of photoelectric conversion elements arranged on a semiconductor substrate, a plurality of wiring layers arranged on the semiconductor substrate through the first and second insulation layers, and a high refractive index region which is arranged in an opening part that is arranged in the interlayer insulation layer so as to correspond to the photoelectric conversion element and has a higher refractive index than the interlayer insulation layers, wherein an area of a cross section parallel to a photoreceiving plane of the photoelectric conversion element in the high refractive index region increases as the position approaches to an upper part of the substrate from a photoreceiving plane of the photoelectric conversion element, namely, as the position approaches to a light-incident plane, and the increasing rate continuously increases with the increase of the area.

Abstract: A pattern mask for forming a microlens includes mask pattern parts alternately arranged and corresponding to pixel regions in a matrix, wherein neighboring corners of the mask pattern parts overlap with each other.

Abstract: In a solid-state imaging device, the pixel circuit formed on the first surface side of the semiconductor substrate is shared by a plurality of light reception regions. The second surface side of the semiconductor substrate is made the light incident side of the light reception regions. The second surface side regions of the light reception regions formed in the second surface side part of the semiconductor substrate are arranged at approximately even intervals and the first surface side regions of the light reception regions formed in the first surface side part of the semiconductor substrate are arranged at uneven intervals, respectively, and the second surface side regions and the first surface side regions are joined respectively in the semiconductor substrate so that the light reception regions extend from the second surface side to the first surface side of the semiconductor substrate.

Abstract: A semiconductor device includes: a semiconductor substrate having an imaging region in which a plurality of photoreceptors are arranged, and a peripheral circuit region arranged around the imaging region; a plurality of microlenses formed on the imaging region; a low-refractive-index film formed on the semiconductor substrate to cover the plurality of microlenses and part of the peripheral circuit region; and a transparent substrate formed on part of the low-refractive-index film above the imaging region. A through hole is formed in part of the low-refractive-index film above an amplifier circuit arranged in the peripheral circuit region.

Abstract: A photodetector for detecting megavoltage (MV) radiation comprises a semiconductor conversion layer having a first surface and a second surface disposed opposite the first surface, a first electrode coupled to the first surface, a second electrode coupled to the second surface, and a low density substrate including a detector array coupled to the second electrode opposite the semiconductor conversion layer. The photodetector includes a sufficient thickness of a high density material to create a sufficient number of photoelectrons from incident MV radiation, so that the photoelectrons can be received by the conversion layer and converted to a sufficient of recharge carriers for detection by the detector array.

Abstract: In one aspect, the present invention provides a silicon photodetector having a surface layer that is doped with sulfur inclusions with an average concentration in a range of about 0.5 atom percent to about 1.5 atom percent. The surface layer forms a diode junction with an underlying portion of the substrate. A plurality of electrical contacts allow application of a reverse bias voltage to the junction in order to facilitate generation of an electrical signal, e.g., a photocurrent, in response to irradiation of the surface layer. The photodetector exhibits a responsivity greater than about 1 A/W for incident wavelengths in a range of about 250 nm to about 1050 nm, and a responsivity greater than about 0.1 A/W for longer wavelengths, e.g., up to about 3.5 microns.

Abstract: A semiconductor integrated circuit including digital circuits and analog circuits integrated over a single substrate includes the substrate including portions where the digital circuits and the analog circuits are to be formed, and a plurality of deep-wells formed to a certain thickness inside the substrate to surround portions where devices of the digital circuits and devices of the analog circuits are to be formed to reduce interference between the devices of the analog circuits and the digital circuits.

Abstract: Provided are a semiconductor device and a method of fabricating the same. The semiconductor device includes a plurality of device isolation layers disposed in a semiconductor substrate, the device isolation layers extending in a word line direction and spaced apart from each other; a plurality of floating gate devices extending in a bit line direction perpendicular to the device isolation layer and spaced apart from each other; a source region and a drain region disposed at sides of the floating gate device; an insulation layer disposed on the floating gate device and the source region, and a polysilicon line extending in the word line direction and connected to the drain region.

Abstract: An integrated circuit resistor is provided that comprises a mesa 14 between electrical contacts 16 and 18. The electrical resistance between electrical contacts 16 and 18 is selectively increased through the formation of recesses 20 and 22 in the mesa 14. The size of recesses 20and 22 can be used to tune the value of the electrical resistance between contacts 16 and 18.

Abstract: A capacitor-equipped semiconductor device includes a semiconductor chip having a plurality of electrode terminals; a sheet-like substrate at least having a film capacitor; and a mounting substrate. The mounting substrate is provided on one side thereof with chip connection terminals and ground terminals. The chip connection terminals are disposed to correspond to the electrode terminals of the semiconductor chip. The ground terminals are disposed to correspond to the one electrode terminals of the film capacitor of the sheet-like substrate. The mounting substrate is provided on the other side thereof with external connection terminals connected to the chip connection terminals and the ground terminals and used to mount the mounting substrate on an external substrate.

Abstract: This application relates to a semiconductor device comprising a first chip comprising a first electrode on a first face of the first chip, and a second chip attached to the first electrode, wherein the second chip comprises a transformer comprising a first winding and a second winding.

Abstract: An apparatus and method for holding a semiconductor device in a wafer. A bar is connected to the wafer. A first sidewall comprises a first end and a second, and is connected to the bar at its first end. A first tab comprises a first end and a second end, and is connected to the second end of the first sidewall at its first end and connected to the first side of the semiconductor device at its second end. The thickness of the first tab is less than the thickness of the bar and the thickness of the first sidewall.

Abstract: The present invention generally provides semiconductor substrates having submicron-sized surface features generated by irradiating the surface with ultra short laser pulses. In one aspect, a method of processing a semiconductor substrate is disclosed that includes placing at least a portion of a surface of the substrate in contact with a fluid, and exposing that surface portion to one or more femtosecond pulses so as to modify the topography of that portion. The modification can include, e.g., generating a plurality of submicron-sized spikes in an upper layer of the surface.

Abstract: A microelectronic assembly in which a semiconductor device structure is directionally positioned on an off-axis substrate (201). In an illustrative implementation, a laser diode is oriented on a GaN substrate (201) wherein the GaN substrate includes a GaN (0001) surface off-cut from the <0001> direction predominantly towards either the <1120> or the <1100> family of directions. For a <1120> off-cut substrate, a laser diode cavity (207) may be oriented along the <1100> direction parallel to lattice surface steps (202) of the substrate (201) in order to have a cleaved laser facet that is orthogonal to the surface lattice steps. For <1100> off-cut substrate, the laser diode cavity may be oriented along the <1100> direction orthogonal to lattice surface steps (207) of the substrate (201) in order to provide a cleave laser facet that is aligned with the surface lattice steps.

Abstract: The present invention relates to high performance three-dimensional (3D) field effect transistors (FETs). Specifically, a 3D semiconductor structure having a bottom surface oriented along one of a first set of equivalent crystal planes and multiple additional surfaces oriented along a second, different set of equivalent crystal planes can be used to form a high performance 3D FET with carrier channels oriented along the second, different set of equivalent crystal planes. More importantly, such a 3D semiconductor structure can be readily formed over the same substrate with an additional 3D semiconductor structure having a bottom surface and multiple additional surfaces all oriented along the first set of equivalent crystal planes. The additional 3D semiconductor structure can be used to form an additional 3D FET, which is complementary to the above-described 3D FET and has carrier channels oriented along the first set of equivalent crystal planes.

Abstract: The present invention provides a process for manufacturing an integrated circuit (IC) package and an integrated circuit (IC) package. The process, without limitation, includes providing an integrated circuit chip having a configuration, and forming a layer of overcoat material over the integrated circuit chip based upon the configuration.

Abstract: A process for growth of boron-based nanostructures, such as nanotubes and nanowires, with a controlled diameter and with controlled chemical (such as composition, doping) as well as physical (such as electrical and superconducting) properties is described. The boron nanostructures are grown on a metal-substituted MCM-41 template with pores having a uniform pore diameter of less than approximately 4 nm, and can be doped with a Group Ia or Group IIa electron donor element during or after growth of the nanostructure. Preliminary data based on magnetic susceptibility measurements suggest that Mg-doped boron nanotubes have a superconducting transition temperature on the order of 100 K.

Abstract: An integrated circuit package comprises an integrated circuit die comprising a first pad, a second pad adjacent to the first pad, a third pad adjacent to the second pad, and a fourth pad adjacent to the third pad. A lead frame comprising a first lead, a second lead adjacent to the first lead, a third lead adjacent to the second lead, and a fourth lead adjacent to the third lead. First, second, third and fourth bondwires connect the first, second, third and fourth leads to the first, second, third and fourth pads, respectively. The first and second leads and the third and fourth leads are spaced at a first distance and the second and third leads are spaced at a second distance that is different than the first distance.

Abstract: A semiconductor power device package having a lead frame-based integrated inductor is disclosed. The semiconductor power device package includes a lead frame having a plurality of leads, a inductor core attached to the lead frame such that a plurality of lead ends are exposed through a window formed in the inductor core, a plurality of bonding wires, ones of the plurality of bonding wires coupling each of the plurality of lead ends to adjacent leads about the inductor core to form the inductor, and a power integrated circuit coupled to the inductor. In alternative embodiments, a top lead frame couples each of the plurality of lead ends to adjacent leads about the inductor core by means of a connection chip.

Abstract: The present invention relates to a semiconductor device including a semiconductor chip encapsulated by an encapsulation resin and a manufacturing method thereof, and an object of the invention is to provide the semiconductor chip and its manufacturing method in which the reduction in size may be attempted. It includes a semiconductor chip 15, an external connection terminal pad 18 electrically connected to the semiconductor chip 15, and an encapsulation resin 16 encapsulating the semiconductor chip 15, wherein a wiring pattern 12 on which the external connection terminal pad 18 is formed is provided between the semiconductor chip 15 and the external connection terminal pad 18, and the semiconductor chip 15 is flip-chip bonded to the wiring pattern 12.

Abstract: A semiconductor package assembly may include a lead frame having a die bonding pad and plurality of leads coupled to the first die bonding pad. A vertical semiconductor device may be bonded to the die bonding pad. The device may have a conductive pad electrically connected to one lead through a first bond wire. An electrically isolated conductive trace may be formed from a layer of conductive material of the first semiconductor device. The conductive trace provides an electrically conductive path between the first bond wire and a second bond wire. The conductive path may either pass underneath a third bond wire thereby avoiding the third bond wire crossing another bond wire, or the conductive path may result in a reduced length for the first and second bond wires that is less than a predetermined maximum length.

Abstract: A power module includes: an encapsulation-target portion having at least one semiconductor element; and an encapsulation member that has first and second planes between which the encapsulation-target portion is interposed, and that encapsulates the encapsulation-target portion. The encapsulation member has, on the at least one semiconductor element, at least one opening that exposes part of a surface of the encapsulation-target portion the surface being on a side of the first plane. Thus, a semiconductor device of which size can be reduced can be provided.

Abstract: A semiconductor device and a fabrication method thereof are provided. An opening having at least one slanted side is formed on a substrate. At least one chip and at least one passive component are mounted on the substrate. An encapsulant having a cutaway corner is formed on the substrate to encapsulate the chip and the passive component, wherein the cutaway corner of the encapsulant is spaced apart from the slanted side of the opening by a predetermined distance. A singulation process is performed to cut the encapsulant to form a package with a chamfer. The package is embedded in a lid to form the semiconductor device, wherein a portion of the substrate located between the slanted side of the opening and the cutaway corner of the encapsulant is exposed from the encapsulant to form an exposed portion. The present invention also provides a carrier for the semiconductor device.

Abstract: An integrated circuit package system comprising: connecting an integrated circuit die with a bottom connection structure; placing an adhesive encapsulation over the integrated circuit die and the bottom connection structure with the bottom connection structure exposed; and placing a top connection structure over the adhesive encapsulation at an opposing side to the bottom connection structure.

Abstract: A decoupling capacitor, a wafer stack package including the decoupling capacitor, and a method of fabricating the wafer stack package are provided. The decoupling capacitor may include a first electrode formed on an upper surface of a first wafer, a second electrode formed on a lower surface of a second wafer, and an adhesive material having a high dielectric constant and combining the first wafer with the second wafer. In the decoupling capacitor the first and second electrodes operate as two electrodes of the decoupling capacitor, and the adhesive material operates as a dielectric of the decoupling capacitor.

Abstract: A semiconductor device is provided that forms a three-dimensional semiconductor device having semiconductor devices stacked on one another. In this semiconductor device, a hole is formed in a silicon semiconductor substrate that has an integrated circuit unit and an electrode pad formed on a principal surface on the outer side. The hole is formed by etching, with the electrode pad serving as an etching stopper layer. An embedded electrode is formed in the hole. This embedded electrode serves to electrically lead the electrode pad to the principal surface on the bottom side of the silicon semiconductor substrate.

Abstract: A method of manufacture of an integrated circuit packaging system includes: forming a carrier having a top side and a bottom side; forming an edge terminal pad on the top side and an inner terminal pad on the bottom side; connecting an integrated circuit die to an inner portion of the edge terminal pad; and encapsulating the integrated circuit die and the inner portion of the edge terminal pad with the outer portion of the edge terminal pad exposed.

Abstract: The present invention discloses a structure of package comprising: a substrate with a die receiving through hole and a contact conductive via formed therein, a die disposed within the die receiving through hole, a surrounding material filled in the gap except the die area of the die receiving though hole, a re-distribution layer formed on the substrate and coupled to the contact conductive via, a protection layer formed over the re-distribution layer, a cover material formed over the protection layer; and a terminal contact pad formed on the lower surface of the substrate and under the contact conductive via and the die to couple the contact conductive via.

Abstract: An insulation covering structure for a semiconductor element with a single die dimension includes: a semiconductor element with a single die dimension and an insulation covering layer. The semiconductor element has a front side surface, a rear side surface, a left side surface, a right side surface, a bottom surface, and a top surface. The top surface of the semiconductor element has two metal pads. The insulation covering layer covers the front side surface, the rear side surface, the left side surface, the right side surface, and the bottom surface of the semiconductor element. A manufacturing process for covering the semiconductor element with a single die dimension is also disclosed.

Abstract: On a semiconductor element loading face, wiring patterns are drawn out from those formed in the vicinity of the edge of the semiconductor element of the loading pads formed to correspond to the electrode terminals of the semiconductor element, and connected to via pads formed in the vicinity of the edge of the semiconductor element loading face; area pads constructed of the loading pads corresponding to the electrode terminals formed in the central region of the semiconductor element and its vicinity are electrically connected to external connecting terminal pads formed in the central region on the other side of the wiring board and its vicinity, through the nearest area pad vias encircled by the external connecting terminal pads and passing through the wiring board and the wiring patterns; and a plurality of the loading pads constituting the area pads commonly use one of the area pad vias.

Abstract: The present invention provides a 3D electronic packaging unit having a conductive supporting substrate that can achieve multi-chip stacking through the signal contacts on the both sides of the unit. The packaging unit can be batched manufactured on wafers or substrates, and thus reduce the manufacturing cost of each individual packaging unit; moreover, the conductive supporting substrate can be utilized to provide signal transmission of the electronic elements, and the supporting substrate can be used as a ground terminal for the carried electronic elements to enhance electric performance of the electronic elements. The supporting substrate is also a good thermal conductor that can release effectively heat energy generated by the electronic elements and accumulated inside the package to the outside of the package along the substrate to enhance reliability of the packaging structure.

Abstract: A semiconductor package includes a semiconductor chip having bonding pads formed on a top surface and a first via hole and a second via hole formed on both-side edges; a passive element formed within the first via hole; a via wiring formed within the second via hole; a first wiring connected to the bonding pad at one end and connected to the passive element and the via wiring on a top surface of the semiconductor chip; a second wiring formed on a back surface of the semiconductor chip and formed to connect with the passive element and the via wiring; a first passivation film formed in such a way to expose one portion of the first wiring on a top surface of the semiconductor chip; and a second passivation film formed in such a way to expose one portion of the second wiring on a bottom surface of the semiconductor chip.

Abstract: According to the present invention, a recess portion is formed in a package substrate which is formed of a multilayer organic substrate having a multilayer wiring, and an LSI chip is accommodated within the recess portion. Wiring traces are formed on the upper surface of a resin which seals the LSI chip connected to the multilayer wiring. The wiring traces are connected to terminal wiring traces connected to the multilayer wiring on the front face of the package substrate and to front-face bump electrodes for external connection on the upper surface of the resin. On the back face side of the package substrate, back-face bump electrodes for external connection are formed and connected to the multilayer wiring.

Abstract: A kind of microphone package structure includes at least of a substrate, a sound processing unit, an upper cap and other devices. There would be at least one trench set on the substrate, and a separation gap between the trench and the bonding pad of the substrate is maintained. After connective paste is smeared on the surface of the substrate, the trench would be assembled with other devices. This kind of package structure could prevent a short circuit being caused by the overflowing of the connective paste.

Abstract: A cooling device is provided for liquid cooling a power semiconductor device. The device includes a coolant diverter for guiding liquid coolant to the power semiconductor device. The coolant diverter has a first plate for dividing the coolant diverter into a first cavity and a second cavity. The second cavity positioned adjacent the power semiconductor device. The first plate further includes an opening to fluidly couple the first cavity with the second cavity such that the liquid coolant flows into the first cavity, through the opening in the first plate, and into the second cavity to cool the power semiconductor device. The first cavity has a cross-sectional area that generally decreases in a downstream direction, and the second cavity has a cross-sectional area that generally increases in the downstream direction.

Abstract: A semiconductor package is disclosed. The package includes a leadframe having drain, source and gate leads, and a semiconductor die coupled to the leadframe, the semiconductor die having a plurality of metallized source contacts. A bridged source plate interconnection has a bridge portion, valley portions disposed on either side of the bridge portion, plane portions disposed on either side of the valley portions and the bridge portion, and a connection portion depending from one of the plane portions, the bridged source plate interconnection connecting the source lead with the plurality of metallized source contacts. The bridge portion is disposed in a plane above the plane of the valley portions while the plane portions are disposed in a plane intermediate the plane of the bridge portion and the plane of the valley portions.

Abstract: Embodiments of the invention relate to semiconductor packages in which electrical power is delivered to die-side components removably installed in sockets formed between a package stiffener and an electrical conductor. To this purpose, the package stiffener and the electrical conductor may be electrically coupled to the power and ground terminals of the semiconductor package.

Abstract: Disclosed herein are intermediate and solder bump structures. In one embodiment, a structure comprises a primary solder column comprising primary solder material and configured to electrically contact a bonding pad on a semiconductor substrate. The structure also comprises at least one secondary solder column comprising secondary solder material in electrical contact with the primary solder column, the at least one secondary column having a height and volume less than a height and volume of the primary solder column. In such structures, the primary solder column is further configured to form a primary solder bump comprising the primary solder material and at least a portion of the secondary solder material through cohesion from the at least one secondary solder column when the intermediate structure undergoes a reflow process.

Abstract: A semiconductor package with a substrate ID code and its manufacturing method are revealed. A circuit and a solder mask are formed on the bottom surface of a substrate where the solder mask covers most of the circuit and a circuit-free zone of the substrate. A chip is disposed on the top surface of the substrate. A substrate ID code consisting of a plurality of laser marks is inscribed in the solder mask or in a portion of an encapsulant on the bottom surface away from the circuit to show the substrate lot number on the bottom surface. Therefore, quality control and failure tracking and management can easily be implemented by tracking the substrate ID code from the semiconductor package without changing the appearance of the semiconductor package. Furthermore, the substrate ID code can be implemented by the existing laser imprinting machines for semiconductor packaging processes and be formed at the same time of formation of a product code.

Abstract: A semiconductor package provides an IC chip on at least one package substrate and including signal bond pads, ground bond pads and power bond pads. The package substrate includes signal contact pads, ground contact pads and power contact pads which are respectively coupled to signal bond pads, ground bond pads and power bond pads formed on the IC chip. The contact pads are coupled to the associated bond pads by a bonding wire. The bonding wires that connect the power and ground pads have a thickness that is greater than the thickness of the bonding wires that couple the signal pads. The various bond pads on the IC chip may be staggered to provide for enhanced compactness and integration. The package substrates may be a plurality of stacked package substrates.