Abstract: A process for laser forming a blind via in at least one layer of a circuit substrate having a plurality of capture pads of varying geometry can include, for at least one blind via to be formed in at least one layer of a circuit substrate, evaluating a capture pad geometry value (such as area and/or volume) within a predetermined distance from a drilling location with respect to a blind via geometry value (such as area and/or volume) to be formed at the drilling location. The process can include setting at least one laser operating parameter based on the evaluation in order to obtain a desired capture pad appearance after blind via formation. The process can include imaging a capture pad area defined as an area within a predetermined distance from a blind via drilling location in at least one layer of a circuit substrate, quantifying at least one appearance value for the imaged capture pad area, and determining an acceptability of the imaged capture pad areas based on the quantified appearance value.

Abstract: Protection of a solder ball joint is disclosed in which the solder ball joint is located below the surface level of the encapsulating buffer layer. The buffering layer is etched to expose one or more electrode posts, each of which may be made up of a single column or multiple columns. A top layer resulting either from a top conductive cap or a plating layer around the electrode posts also lies below the buffer layer. When the solder ball is placed onto the posts, the solder/ball joint is protected in a position below the surface of the buffer layer, while still maintaining an electrical connection between the various solder balls and their associated or capping/plating material, electrode posts, wiring layers, and circuit layers. Therefore, the entire ball joint is protected from direct stress.

Abstract: A method of forming a metal semiconductor alloy that includes forming an intermixed metal semiconductor region to a first depth of a semiconductor substrate without thermal diffusion. The intermixed metal semiconductor region is annealed to form a textured metal semiconductor alloy. A second metal layer is formed on the textured metal semiconductor alloy. The second metal layer on the textured metal semiconductor alloy is then annealed to form a metal semiconductor alloy contact, in which metal elements from the second metal layer are diffused through the textured metal semiconductor alloy to provide a templated metal semiconductor alloy. The templated metal semiconductor alloy includes a grain size that is greater than 2× for the metal semiconductor alloy, which has a thickness ranging from 15 nm to 50 nm.

Abstract: A gate electrode is provided for controlling a current flowing through a semiconductor layer. A gate insulating film electrically insulates the semiconductor layer and the gate electrode from each other. A conductor portion is provided on the semiconductor layer, and electrically connected with the semiconductor layer. An interlayer insulating film is provided on the gate electrode such that the conductor portion is electrically insulated from the gate electrode. A buffer insulating film covers a partial region on the conductor portion and the interlayer insulating film, and is made of an insulator. An electrode layer has a wiring portion located on a region from which the conductor portion is exposed, and a pad portion located on the buffer insulating film. Thereby, damage to an IGBT caused when a wire is connected to the pad portion can be suppressed. Further, larger electric power can be handled, while preventing occurrence of breakage due to current concentration.

Abstract: The semiconductor device includes a process monitoring pattern and an input/output (I/O) pad array area, the process monitoring pattern including a lower layer having a peripheral area surrounding a first internal area, the first internal area exposed by an internal open area, an external structure on the peripheral area of the lower layer, and a first dam disposed in the peripheral area spaced apart from the external structure by an external open area, the first dam defining the first internal area. The peripheral area overlaps the input/output (I/O) pad array area of the semiconductor device.

Abstract: Disclosed is a semiconductor device wherein the adhesion of resin to a substrate is improved at a low cost. A semiconductor element and one or two substrates opposing one or both of the surfaces of the semiconductor element are sealed by a resin, a resin bonding coat which is formed by spraying a metal powder by a cold spray method is formed on one or both of the substrates, and recess portions which are widened from a film surface in a depth direction are formed on the resin bonding coat.

Abstract: Embodiments in accordance with the present invention relate to flip-chip packages for semiconductor devices, which feature a die sandwiched between metal layers. One metal layer comprises portions of the lead frame configured to be in electrical and thermal communication with various pads on a first surface of the die (e.g. IC pads or MOSFET gate or source pads) through a solder ball contact. The other metal layer is configured to be in at least thermal communication with the opposite side of the die. Embodiments of packages in accordance with the present invention exhibit superior heat dissipation qualities, while avoiding the expense of wire bonding. Embodiments of the present invention are particularly suited for packaging of power devices.

Abstract: An integrated circuit (IC) has an under-bump metal (UBM) pad disposed between a solder bump and a semiconductor portion of the IC. A UBM layer is disposed between the solder bump and the semiconductor portion and includes the UBM pad and a UBM field. The UBM pad has a contact perimeter formed with the solder bump. The UBM pad extends beyond the contact perimeter a sufficient distance to block alpha particles emitted from the surface of the solder bump from causing an upset event in the semiconductor portion. The UBM field is separated from each UBM pad by a gap extending from the UBM pad to the UBM field so as to electrically isolate the UBM field from the UBM pad.

Abstract: A semiconductor device includes a semiconductor die and a plurality of lead-free solder bumps disposed on a surface of the semiconductor die. A substrate includes a plurality of metal layers and a plurality of dielectric layers. One of the metal layers includes a plurality of contact pads corresponding to the plurality of lead-free solder bumps, and one of the dielectric layers is an exterior dielectric layer having a plurality of respective openings for the contact pad. A plurality of respective copper posts is disposed on the contact pads. The respective copper post for each contact pad extends from the contact pad through the respective opening for the contact pad. The semiconductor die is mounted on the substrate with connections between the plurality of lead-free solder bumps and the plurality of copper posts.

Abstract: A semiconductor device has a substrate and first conductive pads formed over the substrate. An interconnect surface area of the first conductive pads is expanded by forming a plurality of recesses into the first conductive pads. The recesses can be an arrangement of concentric rings, arrangement of circular recesses, or arrangement of parallel linear trenches. Alternatively, the interconnect surface area of the first conductive pads is expanded by forming a second conductive pad over the first conductive pad. A semiconductor die has a plurality of interconnect structures formed over a surface of the semiconductor die. The semiconductor die is mounted to the substrate with the interconnect structures contacting the expanded interconnect surface area of the first conductive pads to increase bonding strength of the interconnect structure to the first conductive pads. A mold underfill material is deposited between the semiconductor die and substrate.

Abstract: A compliant monopolar micro device transfer head array and method of forming a compliant monopolar micro device transfer array from an SOI substrate are described. In an embodiment, the micro device transfer head array including a base substrate and a patterned silicon layer over the base substrate. The patterned silicon layer may include a silicon interconnect and an array of silicon electrodes electrically connected with the silicon interconnect. Each silicon electrode includes a mesa structure protruding above the silicon interconnect, and each silicon electrode is deflectable into a cavity between the base substrate and the silicon electrode. A dielectric layer covers a top surface of each mesa structure.

Abstract: Embodiments of the present disclosure provide an apparatus including a semiconductor die having a plurality of integrated circuit devices, a pad structure electrically coupled to at least one integrated circuit device of the plurality of integrated circuit devices via an interconnect layer, an electrically insulative layer disposed on the interconnect layer, a first shielding structure disposed in the electrically insulative layer and electrically coupled to the pad structure, an under-ball metallization (UBM) structure electrically coupled to the first shielding structure, and a solder bump electrically coupled to the UBM structure, the solder bump comprising a solder bump material capable of emitting alpha particles, wherein the first shielding structure is positioned between the solder bump and the plurality of integrated circuit devices to shield the plurality of integrated circuit devices from the alpha particles. Other embodiments may be described and/or claimed.

Abstract: A semiconductor device includes a semiconductor chip having a plurality of electrode pads, and a rewiring pattern having a plurality of interconnects connected to the electrode pads and extending over insulation film. The semiconductor device includes a plurality of columnar electrodes each having a main body section and a protrusion section, and a sealing section having a top face having a height the same as the top faces of the protrusion sections. The semiconductor device includes solder balls formed on the protrusion sections and has a plurality of trenches in the sealing section. Each trench has a depth which reaches the boundary between the main body and protrusion of the electrode. The side faces of the protrusion section are exposed by the trenches. Each solder ball is electrically connected to the top and side faces of the protrusion section of each electrode.

Abstract: Disclosed is a thin film transistor panel, comprising a substrate, an insulation layer and transparent conducting material. The insulation layer comprises projections at the back side not facing the substrate. A space between two adjacent projections is 1 ?m-10 ?m; the transparent conducting material is formed on the top surface and the lateral surface of the projections of the insulation layer. Otherwise, the transparent conducting material is formed on the top surface and the plane surface around the bottom of the projections or formed on the top surface, the lateral surface and the plane surface around the bottom of the projections. The present invention also discloses a manufacturing method of the thin film transistor panel.

Abstract: A semiconductor device and method is disclosed. In one embodiment, the method includes placing a first semiconductor over an electrically conductive carrier. The first semiconductor is covered with a molding compound. A through hole is formed in the molding compound. A first material is deposited in the through hole.

Abstract: A lead frame having improved connectivity with a molded portion and a method of manufacturing the lead frame are provided. The lead frame includes a die pad on which a semiconductor chip is to be disposed; at least one lead portion arranged to be connected to the semiconductor chip; and at least one plating layer formed on at least one of the at least one lead portion and the die pad, wherein a top surface of the at least one plating layer has an uneven portion having a first average surface roughness.

Abstract: A semiconductor device having an improved whisker resistance in an exterior plating film is disclosed. The semiconductor device includes a tab with a semiconductor chip fixed thereto, plural inner leads, plural outer leads formed integrally with the inner leads, a plurality of wires for coupling electrode pads of the semiconductor chip and the inner leads with each other, and a sealing body for sealing the semiconductor chip. The outer leads project from the sealing body and an exterior plating film, which is a lead-free plating film, is formed on a surface of each of the outer leads.

Abstract: The invention relates to a method for connecting two joining surfaces, particularly in the field of semiconductors, wherein at least one joining surface is produced by depositing a layer comprising 20 to 40% gold and 80 to 60% silver onto a substrate and selectively removing the silver from the deposited layer in order to produce a nanoporous gold layer as a joining surface. The joining surface with the nanoporous gold layer and an additional joining surface are disposed one above the other and pressed together.

Abstract: An object including at least one graphic element, including at least one layer including at least one metal and etched according to a pattern of the graphic element, a first face of the layer being positioned opposite a face of at least one at least partly transparent substrate, a second face, opposite to the first face, of the layer being covered with at least one passivation layer fixed to at least one face of at least one support by wafer bonding and forming with the support a monolithic structure, and the layer including at least at the second face, at least one area including the metal and at least one semiconductor.

Abstract: Systems and methods are disclosed that enable forming semiconductor chip connections. In one embodiment, the semiconductor chip includes a body having a polyhedron shape with a pair of opposing sides; and a solder member extending along a side that extends between the pair of opposing sides of the polyhedron shape.

Abstract: A semiconductor device 100 has such a structure that a semiconductor chip 110 is flip-chip mounted on a wiring board 120. The wiring board 120 has a multilayer structure in which a plurality of wiring layers and a plurality of insulating layers are arranged, and has a structure in which insulating layers of a first layer 122, a second layer 124, a third layer 126 and a fourth layer 128 are provided. The first layer 122 has a first insulating layer 121 and a second insulating layer 123. A protruded portion 132 which is protruded in a radial direction (a circumferential direction) from an outer periphery at one surface side of a first electrode pad 130 is formed on a whole periphery over a boundary surface between the first insulating layer 121 and the second insulating layer 123.

Abstract: A minute electrode, a photoelectric conversion device including the minute electrode, and manufacturing methods thereof are provided. A plurality of parallel groove portions and a region sandwiched between the groove portions are formed in a substrate, and a conductive resin is supplied to the groove portions and the region and is fixed, whereby the groove portions are filled with the conductive resin and the region is covered with the conductive resin. The supplied conductive resin is not expanded outward, and the electrode with a designed width can be formed. Part of the electrode is formed over the region sandwiched between the groove portions, thus, the area of a cross section in the short axis direction can be large, and a low resistance in the long axis direction can be obtained.

Abstract: Disclosed herein is a lead pin for a package substrate including a connection pin, and a head part including a flange part formed at one end of the connection pin and having one surface bonded to the connection pin and a flat part formed at the other surface of the flange part and having at least one groove formed along an outer circumference thereof. According to the present invention, the grooves are formed along the outer circumference of the flat part of the head part of the lead pin to increase a bonding area, thereby making it possible to increase bonding strength of the lead pin.

Abstract: An electronic component includes: an active surface; a plurality of external connection terminals included in the active surface; a bump electrode disposed to the active surface, the bump electrode including: an internal resin formed on the active surface as a core; and a conductive film on a surface of the internal resin, the internal resin being formed in a nearly half-cylindrical shape having a transverse section of one of a nearly semicircular shape, a nearly semielliptical shape, and a nearly trapezoidal shape and extending orthogonal to the transverse section, the transverse section being orthogonal to the active surface; and a global wiring line disposed on the active surface and connecting between the plurality of external connection terminals, and at least one of the external connection terminals being electrically connected to the conductive film.

Abstract: A semiconductor device includes: a sensor including a sensor structure on a first side of the sensor and a periphery element surrounding the sensor structure; and a cap covering the sensor structure and having a second side bonded to the first side of the sensor. The cap includes a first wiring layer on the second side of the cap. The first wiring layer steps over the periphery element. The sensor further includes a sensor side connection portion, and the cap further includes a cap side connection portion. The sensor side connection portion is bonded to the cap side connection portion. At least one of the sensor side connection portion and the cap side connection portion provides an eutectic alloy so that the sensor side connection portion and the cap side connection portion are bonded to each other.

Abstract: Relay substrate (1) connecting between at least a first circuit board and a second circuit board, including housing (10) having recess (10a) provided in the outer circumference and hole (22) provided in the inner circumference; plural connecting terminal electrodes (12a, 12c) connecting between the top and bottom surfaces of housing (10); shield electrode (11) provided in recess (10a); and ground electrode (13) provided on a part of the top and bottom surfaces of housing (10).

Abstract: Methods for localized thinning of wafers used in semiconductor devices and the structures formed from such methods are described. The methods thin localized areas of the backside of the semiconductor wafer to form recesses with a bi-directional channel design that is repeated within the wafer (or die) so that no straight channel line crosses the wafer (or die). The bi-directional pattern design keeps the channels from being aligned with the crystal orientation of the wafer. The recesses are then filled by a solder ball drop process by dropping proper size solder balls into the recesses and then annealing the wafer to reflow the solder balls and flatten them out. The reflow process begins to fill in the recesses from the bottom up, thereby avoiding void formation and the resulting air traps in the reflowed solder material. Other embodiments are also described.

Abstract: A method for manufacturing a semiconductor device includes: (a) forming a stress relaxation layer on a first surface having an electrode of a semiconductor substrate; (b) forming a wiring line so as to cover the electrode and the stress relaxation layer after step (a); (c) forming a solder resist layer on the wiring line after step (b); and (d) forming a protective layer on a second surface opposite to the first surface of the semiconductor substrate after step (c).

Abstract: A die structure includes a die and a metallization layer disposed over the front side of the die. The metallization layer includes copper. At least a part of the metallization layer has a rough surface profile. The part with the rough surface profile includes a wire bonding region, to which a wire bonding structure is to be bonded.

Abstract: A method of manufacturing a solar cell having a texture on a surface of a silicon substrate includes first forming a porous layer on the surface of the silicon substrate by dipping the silicon substrate into a mixed aqueous solution of oxidizing reagent containing metal ions and hydrofluoric acid. Second, a texture is formed by etching the surface of the silicon substrate after the porous layer is formed, by dipping the silicon substrate into a mixed acid mainly containing hydrofluoric acid and nitric acid.

Abstract: An improved manufacturing method of a semiconductor device is provided. The method includes preparing a semiconductor substrate having an integrated circuit together with connection pads. The method also includes forming a dielectric film on the semiconductor substrate. The method also includes forming connection wires having a predetermined pattern on the dielectric film such that the connection wires are electrically connected to the connection pads. The method also includes forming a surface resin layer to partially cover the connection wire. The method also includes forming a metal film over the exposed connection wires. The method also includes forming a display unit having through holes to present identification information in a region corresponding to the center area of the semiconductor substrate on the surface resin layer. The forming of the metal film and the forming of display unit are carried out simultaneously.

Abstract: A semiconductor structure having: an electrically and thermally conductive layer disposed on one surface of the semiconductor structure; an electrically and thermally conductive heat sink; a electrically and thermally conductive carrier layer; a plurality of electrically and thermally nano-tubes, a first portion of the plurality of nano-tubes having proximal ends disposed on a first surface of the carrier layer and a second portion of the plurality of nano-tubes having proximal ends disposed on an opposite surface of the carrier layer; and a plurality of electrically and thermally conductive heat conductive tips disposed on distal ends of the plurality of nano-tubes, the plurality of heat conductive tips on the first portion of the plurality of nano-tubes being attached to the conductive layer, the plurality of heat conductive tips on the second portion of the plurality of nano-tubes being attached to the heat sink.

Abstract: A semiconductor device includes: a sensor including a sensor structure on a first side of the sensor and a periphery element surrounding the sensor structure; and a cap covering the sensor structure and having a second side bonded to the first side of the sensor. The cap includes a first wiring layer on the second side of the cap. The first wiring layer steps over the periphery element. The sensor further includes a sensor side connection portion, and the cap further includes a cap side connection portion. The sensor side connection portion is bonded to the cap side connection portion. At least one of the sensor side connection portion and the cap side connection portion provides an eutectic alloy so that the sensor side connection portion and the cap side connection portion are bonded to each other.

Abstract: The present invention provides a method for making an electrode. Firstly, a conducting substrate is provided. Secondly, a plurality of nano-sized structures is formed on the conducting substrate by a nano-imprinting method. Thirdly, a coating is formed on the nano-sized structures. The nano-sized structures are configured for increasing specific surface area of the electrode.

Abstract: An interconnect structure of an integrated circuit and manufacturing method therefore are provided, relating to an interconnect structure of flexible packaging. The interconnect structure includes a first and a second conductive pads. A plurality of tiny and conductive first pillars is respectively formed on the first and second pads. With different densities and thicknesses of the first and second pillars, a contact strength can be generated when the pillars interconnecting with each other, such that the pillars are connected closely. Furthermore, the interconnect structure can also be used to connect with fibers made of conductive materials. Moreover, the higher the density of the pillars, the stronger the contact strength. And, electronic substrates and active or passive electronic elements can be stuck on the other side of each pad. Therefore, the interconnect structure can maintain flexibility and have high reliability without being enhanced by any thermosetting polymer.

Abstract: A method and structure are provided to enable wire bond connections over active and/or passive devices and/or low-k dielectrics, formed on an Integrated Circuit die. A semiconductor substrate having active and/or passive devices is provided, with interconnect metallization formed over the active and/or passive devices. A passivation layer formed over the interconnect metallization is provided, wherein openings are formed in the passivation layer to an upper metal layer of the interconnect metallization. Compliant metal bond pads are formed over the passivation layer, wherein the compliant metal bond pads are connected through the openings to the upper metal layer, and wherein the compliant metal bond pads are formed substantially over the active and/or passive devices. The compliant metal bond pads may be formed of a composite metal structure.

Abstract: A method for electrically connecting an integrated circuit to a via in a substrate is disclosed. The method can include deforming a ball over the via to form a bump and attaching a bond wire to the bump. The method also can include attaching the bond wire to the integrated circuit, such as by forming an end of the bond wire into a second ball and deforming the second ball over the integrated circuit. Alternatively, the method can include forming an end of the bond wire into a ball and deforming the ball over the via. Embodiments of a disclosed integrated circuit and substrate assembly can include, for example, a bump aligned with at least a portion of a via in a substrate and a bond wire attached to the integrated circuit and the bump. Other embodiments can include a via with a top metal cap and an upper plating.

Abstract: In a double-sided electrode package, a sealing resin layer is formed so as to fill peripheries of surface-side terminals formed on a package substrate. Since the side surfaces of the surface-side terminals have plural protruded rims, adhesion with the sealing resin layer is improved by an anchor effect. At a sealing step, since supplied liquid resin is naturally flowed to form the sealing resin layer, a “mold step” and a “grinding step” may be omitted, and thus the sealing step may be simplified more greatly than a case where the resin sealing is carried out by a transfer molding method.

Abstract: A disclosed wiring substrate includes an insulating layer, a recess formed on a surface of the insulating layer, and an alignment mark formed inside of the recess, wherein a face of the alignment mark is roughened, recessed from the surface of the insulating layer, and exposed from the recess.

Abstract: An electrical connection between two chips includes an IC pad on a first chip, an IC pad on a second chip, a first barrier metal over the IC pad of the first chip, a second barrier metal over the IC pad of the second chip, a malleable electrically conductive metal, different from the barrier metals, trapped between the first barrier metal and the second barrier metal, the first barrier metal, the malleable conductive metal and the second barrier metal forming a complete electrically conductive path between the IC pad of the first chip and the IC pad of the second chip.

Abstract: A semiconductor device 100 has such a structure that a semiconductor chip 110 is flip-chip mounted on a wiring board 120. The wiring board 120 has a multilayer structure in which a plurality of wiring layers and a plurality of insulating layers are arranged, and has a structure in which insulating layers of a first layer 122, a second layer 124, a third layer 126 and a fourth layer 128 are provided. The first layer 122 has a first insulating layer 121 and a second insulating layer 123. A protruded portion 132 which is protruded in a radial direction (a circumferential direction) from an outer periphery at one surface side of a first electrode pad 130 is formed on a whole periphery over a boundary surface between the first insulating layer 121 and the second insulating layer 123.

Abstract: In a non-leaded type semiconductor device, a tab, tab suspension leads, and other leads are exposed to one surface of a seal member. A semiconductor element is positioned within the seal member and fixed to a surface of the tab with an adhesive. The tab is formed larger than the semiconductor element so that outer peripheral edges of the tab are positioned outside outer peripheral edges of the semiconductor element. A groove is formed in the tab surface portion positioned between the area to which the semiconductor element is fixed and wire connection areas to which the wires are connected, the groove being formed so as to surround the semiconductor element fixing area, thereby preventing peeling-off between the tab to which the semiconductor element is fixed and the resin which constitutes the package.

Abstract: An inclined surface having an inclination angle ? is formed in an edge portion which forms an opening portion of an inter-layer insulating film, thereby reducing a stress by the inclined surface.

Abstract: A semiconductor device includes a semiconductor element including a semiconductor substrate having an element region, a laminated film formed on the semiconductor substrate and including a low dielectric constant insulating film, and a laser-machined groove provided to cut at least the low dielectric constant insulating film. The semiconductor element is connected to a wiring substrate via a bump electrode. An underfill material is filled between the semiconductor element and the wiring substrate. The fillet length Y (mm) of the underfill material satisfies a condition of Y>?0.233X+3.5 (where X>0, and Y>0) with respect to the width X (?m) of the laser-machined groove.

Abstract: A semiconductor chip (1) has a metal coating structure (2) which has on an active upper side (3) of the semiconductor chip (1) at least one lower metal layer (8) with copper or copper alloy, on which a central metal layer (9) with nickel is arranged. The metal coating structure (2) is terminated by an upper metal layer (10) of palladium and/or a precious metal. The central metal layer (9) with nickel and/or nickel phosphide has a rough interface (11) with respect to the plastic package molding compound surrounding the metal coating structure (2).

Abstract: A via connecting the front surface of a semiconductor substrate to its rear surface, this via having a rough lateral surface.

Abstract: An object including at least one graphic element, including at least one layer including at least one metal and etched according to a pattern of the graphic element, a first face of the layer being positioned opposite a face of at least one at least partly transparent substrate, a second face, opposite to the first face, of the layer being covered with at least one passivation layer fixed to at least one face of at least one support by wafer bonding and forming with the support a monolithic structure, and the layer including at least at the second face, at least one area including the metal and at least one semiconductor.

Abstract: A nanometer-scale post structure and a method for forming the same are disclosed. More particularly, a post structure, a light emitting device using the structure, and a method for forming the same, which is capable of forming a nanometer-scale post structure having a repetitive pattern by using an etching process, are disclosed. The method includes forming unit patterns on a substrate by use of a first material, growing a wet-etchable second material on the substrate formed with the unit patterns, and wet etching the substrate having the grown second material.

Abstract: A single-chip module (SCM) and a multi-chip module (MCM) that includes at least two instances of the SCM are described. The SCM includes a pad disposed on a substrate. This pad has a top surface that includes a pattern of features. A given feature in the pattern of features has a height that extends above a minimum thickness of the pad, thereby increasing a capacitance associated with the pad relative to a configuration in which the top surface is planar. Furthermore, pads disposed on the two instances of the SCM in the MCM may each have a corresponding pattern of features that increases the capacitive coupling between the pads relative to a configuration in which the top surfaces of either or both of the pads are planar. Note that the pads may be aligned such that features in the patterns of features on these pads are interdigited with each other.

Abstract: A bonding pad structure in a semiconductor device includes a contact pad connected to an interconnect, a bonding pad overlying the contact pad with an intervention of an insulating film and exposed from an opening of a passivation film, and an annular contact disposed between the contact pad and the bonding pad for electric connection therebetween. The annular contact encircles the opening as viewed normal to the substrate surface.