Abstract: A semiconductor device includes a leadframe, a semiconductor chip, a packaging compound. The leadframe has a pad with straps. Leads on the leadframe include first and second portions. The pad, the straps, and the leads have a mechanically rough surface. The semiconductor chip is attached to the pad and wire bonded to the first lead portions. A packaging compound encapsulates the chip, the pad, the straps, the bonding wires and the first lead portions. The second lead portions are left un-encapsulated. The strap ends are exposed on the surface of the package. At least one of the straps includes a portion adjacent to the exposed end. This portion having a mechanically smooth surface transitioning by a step into the rough surface of the remainder of the strap.

Abstract: A semiconductor device includes: leads (5) in each of which a cutout (5a) is formed; a die pad (11); a power element (1) held on the die pad (11); and a package (6) made of a resin material, and configured to encapsulate inner end portions of the leads (5), and the die pad (11) including the power element (1). The cutout (5a) is located in a region of each of the leads (5) including a portion of the lead (5) located at a boundary between the lead (5) and the package (6), and is filled with a resin material.

Abstract: A metal leadframe strip (500) for semiconductor devices is described. The leadframe strip has a plurality of sites (510) for assembling semiconductor chips. The sites alternate with zones (520) for connecting the leadframe to molding compound runners. The sites (510) have mechanically rough and optically matte surfaces (511, 512). The zones (520) have at least portions with mechanically flattened and optically shiny metal surfaces (521, 522). The flattened surface portions transition into the rough surface portions by a step.

Abstract: A lead frame including rails, section bars, and lead frame cells. The rails are respectively arranged at edges of the lead frame extending in a first direction. The section bars extend between the rails in a second direction and are orthogonal to the rails. The lead frame cells are aligned along the section bars. At least one of the section bars includes a rib extending in the second direction and formed through a half blanking process.

Abstract: A method of fabricating a chip package structure includes the steps of providing a lead frame having a die pad, plural leads and at least one structure enhancement element. A chip is then disposed on the die pad and plural bonding wires are formed to electrically connect the chip to the leads. Then, an upper encapsulant and a first lower encapsulant are formed on an upper surface and a lower surface of the lead frame, respectively. The first lower encapsulant has plural concaves to expose the structure enhancement element. Finally, the structure enhancement element is etched with use of the first lower encapsulant as an etching mask until the die pad and one of the leads connected by the structure enhancement element, or two of the adjacent leads connected thereby are electrically insulated.

Abstract: A method of fabricating a chip package is provided. A thin metal plate having a first protrusion part, a second protrusion part and a plurality of third protrusion parts are provided. A chip is disposed on the thin metal plate, and a plurality of bonding wires for electrically connecting the chip to the second protrusion part and the second protrusion part to the third protrusion parts is formed. An upper encapsulant and a lower encapsulant are formed on the upper surface and the lower surface of the thin metal plate respectively. The lower encapsulant has a plurality of recesses for exposing a portion of the thin metal plate at locations where the first protrusion part, the second protrusion part and the third protrusion parts are connected to one another. Finally, the thin metal plate is etched by using the lower encapsulant as an etching mask.

Abstract: Embodiments of the present invention provide leadframes including a die paddle including one or more apertures defined therein, and electronic packages employing the same and having a microelectronic device mounted on the die paddle over one or more of the apertures. Other embodiments may be described and claimed.

Abstract: In one embodiment, a semiconductor package is formed to include a leadframe that includes a plurality of die attach areas for attaching a semiconductor die to the leadframe. The leadframe is positioned to overlie another leadframe that forms some of the external terminals or leads of the package.

Abstract: A packaged electronic device (20) includes a die pad (30), leads (32) arranged around the die pad (30), and a die (24) attached to an upper surface (34) of the die pad (30) and electrically connected to the leads (32). A packaging material (28) encapsulates the die pad (30), the die (24), and the leads (32). The die pad (30) includes indentations (42) formed in the upper surface (34) along a sidewall (38) of the die pad (30). The die pad (30) further includes indentations (44) formed in a lower surface (36) of the die pad (30) along the sidewall. The packaging material (28) fills the indentations (42, 44) thereby promoting adhesion between the die pad (30) and the packaging material (28) so that the die pad (30) and packaging material (28) cannot readily delaminate.

Abstract: An electronic component includes a lead frame, a semiconductor chip and an encapsulating body. The lead frame includes a heat spreader area, a plurality of conductive lead fingers, at least one non-conductive tie bar, and a metal joint. The metal joint connects the at least one non-conductive tie bar to the heat spreader area. The semiconductor chip is provided on a die pad located on the heat spreader area. The encapsulating body covers at least part of the semiconductor chip, at least part of the at least one non-conductive tie bar and part of the lead frame.

Abstract: The present invention relates to a stress-free lead frame (1) for a semiconductor. The stress-free lead frame (1) is provided with a stress-relief means (15) and an interlocking means (16) at the outer periphery. The stress-relief means (15) is capable of accommodating expansion and compression while the interlocking means (16) take care of shock and vibration during handling to thereby eliminate delamination of the lead frame (10).

Abstract: A leadframe-based semiconductor package and a leadframe for the package are revealed. The semiconductor package primarily includes parts of the leadframe including one or more first leads, one or more second leads, and a supporting bar disposed between the first leads and the second leads and further includes a chip attached to the first leads, the second leads and the supporting bar, a plurality of bonding wires and an encapsulant. The supporting bar has an extended portion projecting from the first bonding finger and the second bonding finger and connected to a non-lead side of the encapsulant wherein the extended portion has an arched bend to absorb the pulling stresses and to block stress transmission. Cracks caused by delamination of the supporting bar will not be created during trimming the supporting bar along the non-lead side of the encapsulant. Moisture penetration along the cracks of the supporting bar to the die-bonding plane under the chip is desirably prevented.

Abstract: Provided is a thin semiconductor package comprising a semiconductor chip and a lead frame, the lead frame including a paddle portion configured for mounting the semiconductor chip in a manner that exposes bonding pads within an aperture formed in a center portion of the lead frame and a peripheral terminal pad portion for establishing external contacts. A plurality of bonding wires are used to establish electrical connection between a lower surface of the paddle part and corresponding bonding pads with intermediate leads providing connection to the terminal pad portions. The semiconductor chip, lead frame and bonding wires may then be encapsulated to form a thin semiconductor package having a thickness substantially equal to that of the terminal pad portions. The thin semiconductor packages may, in turn, be used to form multi-chip stack packages using known good semiconductor chips to form a high-density compound semiconductor packages.

Abstract: A lead frame structure comprises a side rail, a first paddle, a second paddle, a plurality of leads, and an downset anchor bar. The first paddle is connected to the side rail via at least one first tie bar, and the second paddle is connected to the side rail via at least one-second tie bar. The first paddle and the second paddle separated from each other are used to define an area to support a chip. These leads set on the side rail expends toward to the chip supporting area. One end of the downset anchor bar is connected to the side rail, and the other end of the downset anchor bar has a protrusion portion which is between the first paddle and the second paddle and is downset from the side rail.

Abstract: The specification describes a plastic overmolded package for high power devices that has a very low lead count, typically fewer than eight, and in a preferred embodiment, only two. The leads occupy essentially the same linear space as the multiple leads in a conventional package and thus have a wide-blade configuration. To improve mechanical integrity, the leads in the package are provided with retention slots to add back the equivalent of the plastic joints in the spaces that were eliminated due to the wide-blade design. The retention slots extend in the width dimension of the leads.

Abstract: A semiconductor device with its package size close to its chip size has a stress absorbing layer, allows a patterned flexible substrate to be omitted, and allows a plurality of components to be fabricated simultaneously. There is a step of forming electrodes (12) on a wafer (10); a step of providing a resin layer (14) as a stress relieving layer on the wafer (10), avoiding the electrodes (12); a step of forming a chromium layer (16) as wiring from electrodes (12) over the resin layer (14); a step of forming solder balls as external electrodes on the chromium layer (16) over the resin layer (14); and a step of cutting the wafer (10) into individual semiconductor chips; in the steps of forming the chromium layer (16) and solder balls, metal thin film fabrication technology is used during the wafer process.

Abstract: A light emitting device has a cup portion with a bottom surface opening, and one electrode of a light emitting element is connected to the cup portion. The other electrode of the light emitting element is connected to a lead set up from an inner space to outside the cup portion using the opening of the cup portion. Each electrode and lead of the light emitting device can be electrically connected without bonding wires. This prevents shadows or light unevenness from reflecting the shape of the bonding wire, thereby enhancing light-emission efficiency. As an alternative to setting up the lead from inside to the outside of the cup portion, the lead existing outside the cup portion and the other electrode are electrically connected via the bonding wire through the cup portion's opening. Thus, light outputted outside of the light emitting device is not intercepted by the bonding wire.

Abstract: The present invention provides a flexible substrate for a package of a die which has an active surface and a plurality of first bond pads arranged in a form of a row and formed on the active surface. The flexible substrate includes a flexible insulating film and a plurality of first leads formed on the flexible insulating film. Each of the first leads corresponds to one of the first bond pads and has a respective first body portion, a respective first bond portion and a respective first extension portion. For each of the first leads, the width of the first bond portion is larger than those of the first body portion and the first extension portion.

Abstract: A method (300) for fabricating a lead frame (100), comprising forming a plurality of external leads (122) in a lead frame material (108), plating a metal (222) on all surfaces of the lead frame material (108), and subsequently forming a plurality of internal leads (124) in the lead frame material (108). The lead frame material (108) may comprise of a portion of a contiguous metal sheeting (204) rolled upon a first coil (202), wherein the contiguous metal sheeting (204) is fed into an external lead stamping apparatus (206), thus forming the external leads (122), and rolled onto a second coil (215). The portion is fed into a plating apparatus and plated with the metal (222), and rolled onto a third coil (218) prior to forming the plurality of internal leads (124). The third coil (218) can be unrolled into an internal lead stamping apparatus (226), thus forming the internal leads (124) of a lead frame (100).

Abstract: A semiconductor device which permits reduction in the number of pins and in size thereof is provided.

Abstract: The present invention relates to a stress-free lead frame (1) for a semiconductor. The stress-free lead frame (1) is provided with a stress-relief means (15) and an interlocking means (16) at the outer periphery. The stress-relief means (15) is capable of accommodating expansion and compression while the interlocking means (16) take care of shock and vibration during handling to thereby eliminate delamination of the lead frame (10).

Abstract: A chip-mounted film package includes a base film, an effective film package defined on the base film by a cutting line, a driving chip mounted on the effective film package, a plurality of input pads arranged on an input area of the effective film package and connected to the driving chip, and a plurality of output pads arranged on an output area of the effective film package and connected to the driving chip, wherein the output area includes at least one extended portion that protrudes from a side of the effective film package in a horizontal direction of the base film.

Abstract: An integrated circuit chip is provided, which includes a bond pad structure. The bond pad structure includes a bond pad, a first metal plate, and a second metal plate. The first metal plate is located under the bond pad. The first metal plate has a first outer profile area. The second metal plate is located under the first metal plate. A cumulative top view outer profile area of the first metal plate and the second metal plate is larger than the first outer profile area of the first metal plate. The second metal plate may have a second outer profile area that is substantially equal to or larger than the first outer profile area. A first vertical axis may extend through a centroid of the first metal plate, and a centroid of the second metal plate may be laterally offset relative to the first vertical axis.

Abstract: A method (300) for fabricating a lead frame (100), comprising forming a plurality of external leads (122) in a lead frame material (108), plating a metal (222) on all surfaces of the lead frame material (108), and subsequently forming a plurality of internal leads (124) in the lead frame material (108). The lead frame material (108) may comprise of a portion of a contiguous metal sheeting (204) rolled upon a first coil (202), wherein the contiguous metal sheeting (204) is fed into an external lead stamping apparatus (206), thus forming the external leads (122), and rolled onto a second coil (215). The portion is fed into a plating apparatus and plated with the metal (222), and rolled onto a third coil (218) prior to forming the plurality of internal leads (124). The third coil (218) can be unrolled into an internal lead stamping apparatus (226), thus forming the internal leads (124) of a lead frame (100).

Abstract: A semiconductor package having improved adhesiveness between the chip paddle and the package body and having improved ground-bonding of the chip paddle. A plurality of through-holes are formed in the chip paddle for increasing the bonding strength of encapsulation material in the package body. A plurality of tabs are formed in the chip paddle may also be used alone or in conjunction with the through-holes to further increase the bonding strength of the encapsulation material in the package body. The tabs provide additional area for the bonding site to ground wires from the semiconductor chip by increasing the length of the chip paddle.