Abstract: A semiconductor device includes: an interlayer insulation film; a lower interconnection layer; an upper interconnection layer; and a via hole extending through the interlayer insulation film to establish electric connection between the lower and upper interconnections; wherein a plurality of interconnection lines is provided in the lower interconnection layer, and a contact region is formed for contact with the via hole by partially joining at least two interconnection lines, and a void exists in a first region of the interlayer insulation film located between adjacent interconnection lines, and no void exists in a second region of the interlayer insulation film located between a contacting portion of the via hole in the contact region and an interconnection line adjacent to the contact region, whereby reliably preventing any contact between a via hole and a void formed in an interlayer insulation film even when the via hole is greatly displaced.

Abstract: High voltage-resistant semiconductor devices adapted to control threshold voltage by utilizing threshold voltage variation caused by plasma damage resulting from the formation of multilayer wiring, and a manufacturing method thereof. Exemplary high voltage-resistant semiconductor devices include a plurality of MOS transistors having gate insulating films not less than about 350 ? in thickness on a silicon substrate, and the MOS transistors have different area ratios between gate electrode-gate insulating film contact areas and total opening areas of contacts formed on the gate electrodes.

Abstract: Provided are a semiconductor package in which bonding pads of a semiconductor chip are electrically connected to interconnection portions by wire-bonding, and a method of manufacturing the semiconductor package. The semiconductor package includes: a substrate; an interconnection portion that is disposed on the substrate and comprises conductive patterns having a first thickness and conductive patterns having a second thickness that is smaller than the first thickness; at least one semiconductor chip that is mounted on the substrate and comprises a plurality of bonding pads; and a plurality of wires electrically connecting the conductive patterns and the bonding pads.

Abstract: A semiconductor device includes: an isolation region formed in a semiconductor substrate; an active region surrounded by the isolation region; and a first gate electrode formed on the isolation region and the active region and including a first region on the isolation region. The first region has a pattern width in a gate length direction larger than a pattern width of the first gate electrode on the active region. The first region includes a part having a film thickness different from a film thickness of the first gate electrode on the active region.

Abstract: A semiconductor integrated circuit device includes: a semiconductor substrate, on which diffusion layers are formed; and multilayered wirings stacked above the semiconductor substrate to be connected to the diffusion layers via contact plugs, wherein a first wring and a second wiring formed thereabove are connected to the diffusion layers via first contact plug(s) and second contact plugs, respectively, and the number of the second contact plugs arrayed in parallel is set to be greater than that of the first contact plug(s).

Abstract: There is provided a semiconductor device including: a metal wiring line formed on a semiconductor substrate; an inside chamfer provided only at the inside of a bend in the metal wiring line, widening the wiring line width at the inside of the bend; and a protection film covering the metal wiring line.

Abstract: Structures including a refractory metal collar at a copper wire and dielectric layer liner-less interface, and a related method, are disclosed. In one embodiment, a structure includes a copper wire having a liner-less interface with a dielectric layer thereabove; a via extending upwardly from the copper wire through the dielectric layer; and a refractory metal collar extending from a side of the via and partially along the liner-less interface. Refractory metal collar prevents electromigration induced slit voiding by improving the interface around the via, and prevents void nucleation from occurring near the via. Also, the refractory metal collar provides electrical redundancy in the presence of voids around the via and dielectric layer liner-less interface.

Abstract: In one aspect of the invention, a method of attaching a semiconductor die to a microarray leadframe is described. The method comprises stamping an adhesive onto discrete areas of the microarray leadframe using a multi-pronged stamp tool. The adhesive is applied to the leadframe as a series of dots, each dot corresponding to an associated prong of the stamping tool. In some embodiments the adhesive used to attach the semiconductor die to a leadframe is a black epoxy based adhesive material. In an apparatus aspect of the invention, lead traces in a microarray leadframe are arranged to have tails that extend beyond their associated contact posts on the side of the contact post that is opposite a wire bonding region such that such lead traces extends on two opposing sides of their associated contact posts. The tails do not attach to other structures within the lead frame (such as a die attach structure).

Abstract: Methods of isolating spaces formed between features in an array during a pitch reduction process and semiconductor device structures having the same. In one embodiment, ends of the features are wider than middle regions of the features. During the pitch reduction process, spacer sidewalls formed between adjacent ends of the features come into substantial contact with one another, isolating the spaces between the features. In another embodiment, the features have a single width and an additional feature is located near ends of the features. Spacer sidewalls formed between adjacent features and the additional feature come into substantial contact with one another, isolating the spaces between the features.

Abstract: A stacked multilayer structure according to an embodiment of the present invention comprises: a stacked layer part including a plurality of conducting layers and a plurality of insulating layers, said plurality of insulating layers being stacked alternately with each layer of said plurality of conducting layers, one of said plurality of insulating layers being a topmost layer among said plurality of conducting layers and said plurality of insulating layers; and a plurality of contacts, each contact of said plurality of contacts being formed from said topmost layer and each contact of said plurality of contacts being in contact with a respective conducting layer of said plurality of conducting layers, a side surface of each of said plurality of contacts being insulated from said plurality of conducting layers via an insulating film.

Abstract: Disclosed is a power supply line in which a voltage drop generated in a resistance component of a metal line which delivers a power voltage is minimized so that the level of the power supply voltage delivered to a semiconductor chip becomes constant in the entire area of the semiconductor chip. The semiconductor chip includes: at least two power supply pads to which a power voltage applied from an external unit of the semiconductor chip is supplied; power supply main metal lines connected to each of the power supply pads; power supply branch metal lines extended from each of the power supply main metal lines to deliver a power voltage to a circuit in the semiconductor chip; and at least an electrostatic discharge (ESD) improvement dummy pad, wherein the ESD improvement dummy pad is electrically connected to the corresponding power supply main metal line and the corresponding power supply branch metal line to minimize a voltage drop.

Abstract: A semiconductor package 100 is constructed of a semiconductor chip 110, a sealing resin 106 for sealing this semiconductor chip 110, and wiring 105 formed inside the sealing resin 106. And, the wiring 105 is constructed of pattern wiring 105b connected to the semiconductor chip 110 and also formed so as to be exposed to a lower surface 106b of the sealing resin 106, and a post part 105a formed so as to extend in a thickness direction of the sealing resin 106, the post part in which one end is connected to the pattern wiring 105b and also the other end is formed so as to be exposed to an upper surface 106a of the sealing resin 106.

Abstract: Particular embodiments of the present invention provide a leadframe suitable for use in packaging IC dice that enables stress reduction in and around the die, die attach material, die attach pad and mold interfaces. More particularly, various leadframes are described that include recesses in selected regions of the top surface of the die attach pad.

Abstract: Embodiments of the present invention relate to the use of stamping to form features on a lead frame of a semiconductor device package. In one embodiment, portions of the lead frame such as pins are moved out of the horizontal plane of a diepad by stamping. In certain embodiments, indentations or a complex cross-sectional profile, such as chamfered, may be imparted to portions of the pins and/or diepad by stamping. The complexity offered by such a stamped cross-sectional profile serves to enhance mechanical interlocking of the lead frame within the plastic molding of the package body. Other techniques such as selective electroplating and/or formation of a brown oxide guard band to limit spreading of adhesive material during die attach, may be employed alone or in combination to facilitate fabrication of a package having such stamped features.

Abstract: A semiconductor device comprises a wiring layer. The wiring layer is provided by forming a sidewall film having a closed-loop along a sidewall of a hard mask, etching off the hard mask to leave the sidewall film, and then etching a target material to be etched with a mask of the sidewall film. The wiring layer includes a folded wiring section formed along an end of the hard mask, and a parallel section composed of two parallel wires continued from the folded wiring section. The wiring layer has a closed-loop cut made in a portion except for the folded wiring section and the parallel section. The folded wiring section and the parallel section are used as a contact region for connection to another wire.

Abstract: While a semiconductor device is provided with a plurality of element electrodes 5 formed on a semiconductor element 4 and a plurality of lead terminal electrodes 6 formed on a lead frame, the semiconductor device is equipped with a coupling conductor which electrically connects at least one electrode among the above-described element electrodes 5 to at least one electrode among the above-described lead terminal electrodes 6; the above-described coupling conductor is manufactured by a first conductor 1 and a second conductor 2, the major components of which are metals; the first conductor 1 has been electrically connected to the second conductor 2; and the element electrodes 5 and the lead terminal electrodes 6 have been electrically connected to the second conductor 2 respectively.

Abstract: In a film substrate (FB) including a film base material (1) and conductor wiring (23) that is formed on the film base material (1), the conductor wiring (23) is arranged such that the conductor wiring thickness of an external connection portion on the film substrate to which another panel or substrate is connected is thicker than the conductor wiring thickness of conductor wiring portions (bent portions) (25) at other positions.

Abstract: A method and apparatus for partially strapping two polysilicon lines, each having a first end and second end, uses a metal line having a plurality of spaced apart metal segments with each metal segment partially strapping a different portion of a polysilicon line. The metal segments are arranged from the first end to the second end with the signals propagating from the second end to the first end. Where two metal segments are used, the segments have lengths of x = 2 ? ? L 7 and L-X where L is the length between the first end and the second end. Where three segments are used, the segments have lengths of X=0.25 L, Y=0.48 L, and Z=0.27 L.

Abstract: An integrated circuit and method for fabrication includes first and second structures, each including a set of sub-lithographic lines, and contact landing segments connected to at least one of the sub-lithographic lines at an end portion. The first and second structures are nested such that the sub-lithographic lines are disposed in a parallel manner within a width, and the contact landing segments of the first structure are disposed on an opposite side of a length of the sub-lithographic lines relative to the contact landing segments of the second structure. The contact landing segments for the first and second structures are included within the width dimension, wherein the width includes a dimension four times a minimum feature size achievable by lithography.

Abstract: A semiconductor device including: a semiconductor substrate including an electrode; a resin protrusion formed on the semiconductor substrate; and an interconnect electrically connected to the electrode and formed to extend over the resin protrusion. The interconnect includes a first portion formed on a top surface of the resin protrusion and a second portion formed on a side of a lower portion of the resin protrusion. The second portion has a width smaller than a width of the first portion.

Abstract: Semiconductor die packages and methods of making them are disclosed. An exemplary package comprises a leadframe having a source lead and a gate lead, and a semiconductor die coupled to the source and gate leads at a first surface of the leadframe. The source lead has a protruding region at a second surface of the leadframe. A molding material is disposed around the semiconductor die, the gate lead, and the source lead such that a surface of the die and a surface of the protruding region are left exposed by the molding material. An exemplary method comprises obtaining the semiconductor die and leadframe, and forming a molding material around at least a portion of the leadframe and die such that a surface of the protruding region is exposed through the molding material.

Abstract: A pad (20) is electrically connected to a first I/O cell (14) while also physically overlying active circuitry of a second I/O cell (16). Note that although the pad (20) overlies the second I/O cell (16), the pad (20) is not electrically connected to the I/O cell (16). Such a pattern may be replicated in any desired manner so that the I/O cells (e.g. 300-310) may have a finer pitch than the corresponding pads (320-324 and 330-335). In addition, the size of the pads may be increased (e.g. pad 131 may be bigger than pad 130) while the width “c” of the I/O cells (132-135) does not have to be increased. Such a pattern (e.g. 500) may be arranged so that the area required in one or more dimensions may be minimized.

Abstract: Semiconductor structures are disclosed including a substrate comprising a semiconductor material and having opposed first and second surfaces, and at least one conductive via extending from the first surface to the second surface. The conductive vias can extend at angles relative to the first surface, such as acute angles or 90°. The conductive vias can include segments that extend at different angles. Methods of forming conductive vias in semiconductor structures are provided. In the methods, a thermal gradient is applied in combination with an electric field to form conductive vias.

Abstract: A power semiconductor device and a method for its production. The power semiconductor device has at least one power semiconductor chip, which has on its top side and on its back side large-area electrodes. The electrodes are electrically in connection with external contacts by means of connecting elements, the power semiconductor chip and the connecting elements being embedded in a plastic package. This plastic package has a number of layers of plastic, which are pressed one on top of the other and have plane-parallel upper sides. The connecting elements are arranged on at least one of the plane-parallel upper sides, between the layers of plastic pressed one on top of the other, as a patterned metal layer and are electrically in connection with the external contacts by means of contact vias through at least one of the layers of plastic.

Abstract: A wiring board includes a film base, a plurality of conductive wirings aligned on the film base, and protrusion electrodes formed of a plated metal in the vicinity of end portions of the conductive wirings, respectively. An outer surface at both side portions of the protrusion electrodes in cross section in a width direction of the conductive wirings defines a curve, and the protrusion electrodes in cross section in a longitudinal direction of the conductive wirings define a rectangular shape. The conductive wirings include a first conductive wiring having a wiring width of W1 and a second conductive wiring having a wiring width of W2 larger than W1, and the protrusion electrode on the first conductive wiring and the protrusion electrode on the second conductive wiring have a substantially same height.

Abstract: Method of fabricating thin-film transistors in which contact with connecting electrodes becomes reliable. When contact holes are formed, the bottom insulating layer is subjected to a wet etching process, thus producing undercuttings inside the contact holes. In order to remove the undercuttings, a light etching process is carried out to widen the contact holes. Thus, tapering section are obtained, and the covering of connection wiring is improved.

Abstract: An improved interconnect structure and method of making such a device. The improved interconnect electrically connects two otherwise separate areas on a semiconductor wafer. The interconnect preferably uses a copper conductor disposed within a trench and via structure formed in a low-k hybrid dielectric layer using a dual damascene process. Each contact region is served by a plurality of vias, each in communication with the trench conductor portion. The entry from the trench to the via is rounded for at least one and preferably all of the via structures.

Abstract: Example embodiments are directed to a method of forming a semiconductor structure and a semiconductor structure including a semiconductor unit including a protrusion on a front side of the semiconductor unit and a recess on a backside of the semiconductor unit.

Abstract: Embodiments relate to a semiconductor device and a method for manufacturing the same. Embodiments may include forming a lower porous oxide layer on a semiconductor substrate having a conductive layer, forming a pyrolytic polymer layer on the lower porous oxide layer, forming an upper porous oxide layer on the pyrolytic polymer layer, forming a via hole by sequentially etching the upper porous oxide layer, the pyrolytic polymer layer, and the lower porous oxide layer, forming a trench having a width larger than a width of the via hole by sequentially etching the upper porous oxide layer and the pyrolytic polymer layer in such a manner that the trench is connected with the via hole, forming metal interconnections by filling the via hole and the trench with a metal thin film, and forming a vacuum between the upper and lower porous oxide layers by removing the pyrolytic polymer layer.

Abstract: In manufacturing a semiconductor integrated circuit device, an interconnect trench and a contact hole are formed in an interlayer insulating film formed over a first-level interconnect on a semiconductor substrate, a barrier film is formed inside of the trench and contact hole so that its film thickness increases from the center of the bottom of the hole toward the sidewalls all around the bottom of the contact hole, a copper film is formed over the barrier film, and a second-level interconnect and a connector portion (plug) are formed by polishing by CMP. In this way, the geometrically shortest pathway of an electrical current flowing from the second-level interconnect toward the first-level interconnect through a connector portion (plug) does not coincide with a thin barrier film portion which has the lowest electrical resistance, so that the current pathway can be dispersed and a concentration of electrons does not occur readily.

Abstract: A spacer is adjacent to a conductive line. Vias that do not completely land on the conductive line land on the spacer and do not punch through into a volume below the spacer.

Abstract: A circuit device including a multilayer wiring structure having an improved heat radiation performance, and a manufacturing method thereof is provided. A circuit device of the invention includes a first wiring layer and a second wiring layer laminated while interposing a first insulating layer. The first wiring layer is connected to the second wiring layer in a desired position through a connecting portion formed so as to penetrate the first insulating layer. The connecting portion includes a first connecting portion protruding in a thickness direction from the first wiring layer, and a second connecting portion protruding in the thickness direction from the second wiring layer. The first connecting portion and the second connecting portion contact each other at an intermediate portion in the thickness direction of the insulating layer.

Abstract: A semiconductor chip includes flip chip contacts that are arranged on contact surfaces of an active top side of the semiconductor chip. The contact surfaces are surrounded by a passivation layer that covers the active top side while leaving exposed the contact surfaces. The passivation layer includes thickened portions that surround the contact surfaces. The semiconductor chip formed with thickened portions around the contact surfaces is protected from delamination during packaging of the semiconductor chip to form a semiconductor device.

Abstract: General purpose methods for the fabrication of integrated circuits from flexible membranes formed of very thin low stress dielectric materials, such as silicon dioxide or silicon nitride, and semiconductor layers. Semiconductor devices are formed in a semiconductor layer of the membrane. The semiconductor membrane layer is initially formed from a substrate of standard thickness, and all but a thin surface layer of the substrate is then etched or polished away. In another version, the flexible membrane is used as support and electrical interconnect for conventional integrated circuit die bonded thereto, with the interconnect formed in multiple layers in the membrane. Multiple die can be connected to one such membrane, which is then packaged as a multi-chip module. Other applications are based on (circuit) membrane processing for bipolar and MOSFET transistor fabrication, low impedance conductor interconnecting fabrication, flat panel displays, maskless (direct write) lithography, and 3D IC fabrication.

Abstract: An integrated clock and power distribution network in a semiconductor device includes assigning a first tile to a location on a placement grid corresponding to a top metal layer. An orientation is assigned to the first tile relative to the top metal layer placement grid. The first tile is placed on a representation corresponding to the top metal layer in accordance with the assignments. A second tile is assigned to a location on a placement grid corresponding to a top-1 metal layer. The orientation is assigned to the second tile relative to the top-1 metal layer placement grid. The second tile is placed on a representation corresponding to the top-1 metal layer in accordance with the assignments. The first and second tile are arranged as a full-dense-mesh distribution structure. The first tile includes an integrated clock and power distribution structure. The second tile includes a low impedance underpass structure.

Abstract: A first wire having sidewalls of an integrated circuit is tapered from the proximal end to the distal end to reduce width from the first width to the second width. A second wire, spaced apart from the first wire, the second wire has sidewalls. The first wire and the second wire are each horizontally disposed along side each other forming a part of a sidewall capacitor between facing sidewalls. The sidewall capacitor capacitance is progressively reduced responsive to the first wire taper.

Abstract: A semiconductor device and method of fabricating the same reduce the likelihood of the occurrence of electrical defects. The device includes a first interlayer insulating film on a semiconductor substrate; a contact pad spacer on the first interlayer insulating film; and a contact pad in the first interlayer insulating film and the contact pad spacer. The cross-sectional area of an upper portion of the contact pad in the contact pad spacer in a direction horizontal to the substrate is equal to or less than a cross-sectional area of an intermediate portion at an interface between the contact pad spacer and the first interlayer insulating film in a direction horizontal to the substrate.

Abstract: A circuit device includes a semiconductor substrate on which a circuit element is formed, an electrode formed on a surface of the semiconductor substrate, an insulating layer formed on the electrode, a second wiring layer formed on the insulating layer, and a conductive bump which penetrates the insulating layer and electrically connects the electrode and the second wiring layer. The conductive bump is such that the size of crystal grains in a direction parallel with the surface of the semiconductor substrate is larger than the size of crystal grains in a conduction direction of the electrode and the wiring layer.

Abstract: A semiconductor package, includes: element substrate having first surface, including: functional element on first surface, and extracting electrode on first surface and configured to output a signal of functional element, extracting electrode being disposed around functional element; rim substrate shaped into a frame, and configured to have first junction with element substrate to surround functional element, rim substrate including: first through hole through rim substrate, and connecting electrode which is: formed by packing first through hole with first conductor material, configured to seal signal extracting aperture of extracting electrode, and configured to electrically connect signal extracting aperture with takeout electrode; and cover substrate configured to have second junction with rim substrate to block aperture of rim substrate, cover substrate including: second through hole through cover substrate, and takeout electrode which is: formed by packing second through hole with second conductor materi

Abstract: This invention is directed to offer a semiconductor device having a structure capable of relaxing a mechanical stress applied to a bonding pad. A third interlayer insulation film having via holes is formed on a second interlayer insulation film to cover a third wiring layer. A third conductive layer is formed in the via hole. The third interlayer insulation film is composed of an array of a plurality of hexagonal column-shaped interlayer insulation films. And the via hole and the third conductive layer are formed to surround each hexagonal column-shaped interlayer insulation film. A fourth wiring layer connected with the third wiring layer through the third conductive layer is formed. The fourth wiring layer makes an uppermost wiring layer in an embodiment of this invention and serves as the bonding pad.

Abstract: When a nickel (Ni) layer is formed on an electrode pad made of aluminum-silicon (Al—Si) by an electroless plating method, prior to the precipitation of zinc (Zn) which becomes a catalyst, copper (Cu) is formed in the form of discontinuous spots or islands on the surface of the electrode pad, thereby providing a copper (Cu) thin layer.

Abstract: A pad for soldering a contact of a surface mounted component is provided herein. The pad includes a central portion and a plurality of separate extending portions extending from the central portion. All of the plurality of separate extending portions includes a free end and a connected end connected to the central portion. A width of the free end is larger than a width of the connected end. A circuit board and an electronic device are also provided.

Abstract: A semiconductor device includes a semiconductor substrate having an integrated circuit, a first insulating film formed on the semiconductor substrate, at least one power source internal wiring line formed on the first insulating film, and a second insulating film formed on the first insulating film and on the internal wiring line and having a plurality of openings exposing parts of the internal wiring line. At least one wiring line is formed on an upper side of the second insulating film to correspond to the internal wiring line and electrically connected to the internal wiring line via the plurality of openings of the second insulating film. The wiring line has at least one external electrode pad portion whose number is smaller than the number of openings in the second insulating film.

Abstract: An integrated circuit connection is describe that includes a first, securing member and a second, connection member. The first member, in an embodiment, is a spike that has a portion of its body fixed in a layer of an integrated circuit structure and extends outwardly from the integrated circuit structure. The second material is adapted to form a mechanical connection to a further electrical device. The second material (e.g., solder), is held by the first member to the integrated circuit structure. The first member increases the strength of the connection and assists in controlling the collapse of second member to form the mechanical connection to another circuit. The connection is formed by coating the integrated circuit structure with a patterned resist and etching the layer beneath the resist. A first member material (e.g., metal) is deposited. The resist is removed. The collapsible material is fixed to the first member.

Abstract: A silicon substrate has a protective film formed on each side. A semiconductor surface opening not smaller than a given region is formed by removing the protective film. A through-hole having an inner size smaller than the given region is formed in the opening by laser machining. Thereafter, the inner size of the through-hole is increased by anisotropic etching, and the etching is ended when the inner size of the through-hole reaches the given size. In this way, a through-hole of a given size can be formed without allowing reversely tapered crystal planes to appear from a surface of the substrate toward the inside of the through-hole.

Abstract: A semiconductor device having a GaAsFET and input and output matching circuits connected to the FET is provided. In the semiconductor device, a line, including a wire connection portion connected to the input or output matching circuit and a lead connection portion connected to an input or output lead which is connected to an external circuit, is formed in such a manner that a line width at the wire connection portion is wider than that at the lead connection portion. With the semiconductor device, the number of wires connecting the input or output matching circuits with the wire connection portion can be increased.

Abstract: Disclosed are a metal line of a semiconductor device and a method of manufacturing the same. In one embodiment, the metal line includes a first interlayer dielectric layer pattern formed on a lower interconnection structure and having a via hole that exposes a lower interconnection of the lower interconnection structure, a first barrier pattern selectively covering a sidewall of the via hole and the lower interconnection, a second interlayer dielectric layer pattern on the first interlayer dielectric layer pattern and having a trench that exposes the via hole, a second barrier pattern covering an inner wall of the trench and the first barrier pattern, a seed pattern formed on the second barrier pattern, and a copper line formed on the seed pattern.

Abstract: Methods of isolating spaces formed between features in an array during a pitch reduction process and semiconductor device structures having the same. In one embodiment, ends of the features are wider than middle regions of the features. During the pitch reduction process, spacer sidewalls formed between adjacent ends of the features come into substantial contact with one another, isolating the spaces between the features. In another embodiment, the features have a single width and an additional feature is located near ends of the features. Spacer sidewalls formed between adjacent features and the additional feature come into substantial contact with one another, isolating the spaces between the features.

Abstract: An example disclosed semiconductor device includes a semiconductor substrate, a lower interlayer insulating layer formed on the substrate, a lower wire formed on the lower interlayer insulating layer, and an upper interlayer insulating layer which is formed on the lower interlayer insulating layer and has a via hole to expose the lower wire. The lower wire includes a metal layer pattern and a conductive layer pattern, and the metal layer pattern has a protruding portion and the conductive layer pattern is formed on the upper part of the protruding portion of the metal layer pattern and has a hole to expose the protruding portion.

Abstract: A semiconductor device in which a semiconductor chip, a lead frame and metal wires for electrically connecting the lead frame are sealed with sealing resin. The lead frame has a plurality of lead terminal portions, a supporting portion for supporting the semiconductor chip, and hanging lead portions supporting the supporting portion. Each of the lead terminal portions adjacent to the hanging lead portion is a chamfered lead terminal portion having, at its head, a chamfered portion formed substantially in parallel with the hanging lead portion so as to avoid interference with the hanging lead portion.