Abstract: A semiconductor package with stacked chips is proposed, in which a first chip mounted on and electrically connected to a chip carrier is attached with a rigid interposer thereto, while the rigid interposer has a second chip disposed thereon in a manner that the rigid interposer is interposed between the first chip and the second chip. With the use of the rigid interposer, the second chip stacked on the first chip can be positioned in planarly parallel to the chip carrier, allowing bonding wires for electrically connecting the second chip to the chip carrier to be bonded completely. Moreover, the second chip has portions thereof not located right above the first chip to be firmly supported by the rigid interposer, and thus the second chip can be prevented from cracking in the wire bonding process.

Abstract: A ball grid array semiconductor package is provided, wherein at least a predetermined position of a conductive trace on a substrate is formed with a discontinuity, allowing the discontinuity and part of the conductive trace around the discontinuity to be exposed to outside of solder mask applied over the substrate and form a discontinuous pad. The conductive trace having the discontinuous pad is electrically conducted as a solder ball is bonded to the discontinuous pad, and is electrically disconnected when the solder ball is not mounted on the discontinuous pad. As the solder ball is hardly bonded firmly to the discontinuous pad, it can be easily removed from the discontinuous pad to disconnect the conductive trace, and the removed solder ball can be simply mounted back to the discontinuous pad to restore electrical conduction of the conductive trace.

Abstract: A semiconductor device package fabrication method is proposed, which is used for the fabrication of a semiconductor device package of the type having a core-hollowed portion that is typically used to house an optically-sensitive semiconductor device such as an image sensor or an ultraviolet-sensitive EPROM (Electrically-Programmable Read-Only Memory) device. The proposed method is characterized in the use of a support pillar, which is positioned beneath the lead frame when the lead frame is clamped between a top inserted mold and a bottom cavity mold, to help prevent resin flash on the lead frame during the molding of the core-hollowed portion.

Abstract: A semiconductor package having a lead frame formed with a die pad and a plurality of conductive leads, wherein the die pad is formed with a plurality of tabs to impede the resin flow below the die pad such that a downward pressure is produced because the resin flow above the die pad moves at a speed faster than that below the die pad. As a result, the tab is urged against a bottom surface of a mold cavity during a transfer molding process so as to prevent the die pad from being exposed to an encapsulant for encapsulating the die pad and a semiconductor die mounted on the die pad.

Abstract: An improved encapsulation method is proposed for the encapsulation of a substrate-based package assembly, which can help to prevent mold flash over exposed package surfaces after encapsulation process is completed. The proposed encapsulation method is characterized by the forming of a cutaway portion in a solder mask over the substrate along a seam line between the solder mask and the molding tool that would exist between the solder mask and the molding tool when the semi-finished package assembly is fixed in position in the molding tool. During encapsulation process, the cutaway portion defines a constricted flow passage to the injected encapsulation material; and consequently, when the encapsulation material flows into this constricted flow passage, it would more quickly absorb the heat in the molding tool, thereby increasing its viscosity and retarding its flow speed.

Abstract: A semiconductor package and a fabricating method thereof are proposed. The semiconductor package includes a semiconductor chip; a plurality of leads surrounding the chip and formed with a plurality of connecting mechanisms and strengthening structures; and an encapsulant for encapsulating the chip and the leads. The foregoing semiconductor package eliminates the use of a die pad, allowing the thickness of the package to be reduced and a surface of the chip to be exposed to the outside of the encapsulant for improving the heat dissipating efficiency thereof. The leads have the same height as the semiconductor package, allowing upper and lower surfaces of the leads to be exposed to the outside of the encapsulant, which further enhance the dissipation of heat generated by the chip in operation.

Abstract: A purpose of this invention is to totalize, store, and check special sales information concerning special customers or special purchasers, etc. Sales information of registered merchandise is totalized and stored in an area corresponding to a department code of a department file table specified in a product department, by an ordinary registration mode. When special registration process is specified by depressing a department shift key, a value of the product department is changed to a value specified in a department shift table by a special registration mode and the sales information is totalized and stored in an area corresponding to the department code of the department file table specified by the thus changed value. Accordingly, the special sales information can be totalized as ordinary sales information, and can be stored separately from the ordinary sales information.

Abstract: A chip carrier, a semiconductor package and a fabricating method thereof are proposed, in which on one side of the chip carrier finally removed from an engaged surface of a mold in a de-molding process there is formed at least one grounding means corresponding in position to an eject pin of the mold, so as to allow a gear amount of electrical static generated on a surface of the semiconductor package during molding and de-molding to be discharged to the outside, instead of being retained on a semiconductor chip, conductive elements and conductive traces of the semiconductor package. This therefore can prevent electrical leakage and damage to the semiconductor chip from occurrence, and improve the quality and production efficiency for the semiconductor package.

Abstract: Process conditions for which setting operation is being accepted are displayed occupying a large area, by displaying no contents relevant to processing functions irrelevant to the setting of process conditions on screen. In order to improve the visual recognition of displayed contents and the operability of setting keys, an initial display on a liquid crystal display is divided into a left-hand display area for displaying an appearance drawing of the copying machine and a right-hand display area for displaying a drawing representing finishing conditions of a copied document.

Abstract: A reflection-type color liquid crystal display (LCD) device is made up of a reflecting film, a color filter in which a resin black matrix is formed between color patterns, and a liquid crystal layer, which are disposed in this order between a pair of glass substrates. Furthermore, a light transmissive protective film for protecting the reflecting film when electrodepositing is formed on the reflecting film, and on which an electrodepositing transparent conductive layer is formed, and on which the color filter is formed by an electrodeposition method, thereby accurately forming the resin black matrix which is suitable for reflection-type LCD devices on a reflectional function layer provided within a liquid crystal cell.

Abstract: A semiconductor packaging technology is proposed for the fabrication of a chip-on-chip (COC) based multi-chip module (MCM) with molded underfill. The proposed semiconductor packaging technology is characterized by the provision of a side gap of an empirically-predetermined width between the overlying chips mounted through COC technology over an underlying chip to serve as an air vent during molding process. This allows the injected molding material to flow freely into the flip-chip undergaps during molding process. In actual application, the exact width of the side gap is empirically predetermined through molded-underfill simulation experiments to find the optimal value. Based on experimental data, it is found that this side gap width should be equal to or less than 0.3 mm to allow optimal underfill effect. The optimal value for this side gap width may be varied for different package specifications.

Abstract: A stacked multi-chip package structure with on-chip integration of passive component is proposed, which is characterized in the mounting of passive component on a remaining surface area of the underlying semiconductor chip that is unoccupied by the overlying semiconductor chip, so that the overall package construction can be made more compact in size. The proposed package structure comprises: a substrate; a first semiconductor chip mounted over the substrate; a second semiconductor chip mounted over the first semiconductor chip; and at least one passive component mounted beside the second semiconductor chip and over the first semiconductor chip. The first and second semiconductor chips can be mounted by means of adhesive layers or flip chip technology. The passive component can be electrically coupled to the semiconductor chips through the use of wire-bonding technology (WBT) or surface-mount technology (SMT).

Abstract: A delamination-preventing substrate and a semiconductor package with the substrate are provided. A metal layer and a solder mask layer are sequentially laminated on a chip attach area of a substrate, and both formed with corresponding openings for partly exposing the substrate. This allows an adhesive for chip-bonding use to be directly attached to the substrate via the openings, so as to reduce contact area between the adhesive and the metal layer, and to increase bonding between the substrate and a chip mounted on the substrate by means of the adhesive. Direct contact between the adhesive and the substrate also helps reduce stress generated between the chip and substrate, thereby preventing stress-induced delamination. Due to weak adhesion between adhesive and metal materials, reduced contact area between the adhesive and the metal layer would further enhance bonding of the chip to the substrate, thereby assuring quality of fabricated package products.

Abstract: A semiconductor package with a heat-dissipating structure and a method for making the same are proposed. The heat-dissipating structure includes a heat sink and a plurality of solder columns, wherein the solder columns are attached at ends thereof to the heat sink and to a substrate, so as to support the heat sink to be positioned above a semiconductor chip mounted on the substrate. A reflow process performed after the attachment of the heat-dissipating structure to the substrate allows the self-alignment of the solder columns with respect to predetermined positions on the substrate, which helps precisely control the positioning of the heat-dissipating structure fixed on the substrate. Moreover, the solder columns can protect the substrate from being damaged or deformed during a molding process. In addition, the heat-dissipating structure is simple in structure, which simplifies the manufacturing process and reduces the cost.

Abstract: A leadframe-based semiconductor package is proposed for the packaging of a semiconductor device, such as a multi-media card (MMC) chipset. The proposed semiconductor package is characterized by the use of a leadframe, rather than BT substrate or film, as the chip carrier for MMC chipset. The leadframe includes a supporting bar, a chip-supporting structure arranged at a downset position in relation to the supporting bar; and a plurality of leads, each lead including an outer-lead portion and an inner-lead portion; wherein the outer-lead portion is levelly linked to the supporting bar, while the inner-lead portion is arranged beside the chip-supporting structure and linked to the outer-lead portion via an intermediate-lead portion. The leadframe can be either the type having die pad or the type having no die pad.

Abstract: An advanced flip-chip packaging technology is proposed, which is characterized in the forming of a metal dam over the substrate to serve three different utilization purposes. First, the metal dam can help provide a specific fillet width to the underfilled material under the flip chip so as to allow the joint between the flip chip and the substrate to have increased robustness against thermal stress. Second, the metal dam can serve as a mechanical reinforcement to the substrate to prevent package warpage. Third, the metal dam can additionally serve as a heat-dissipation structure to help the heat dissipation from the flip chip. These benefits allow the finished package product to be highly assured in quality and reliability.

Abstract: A disk-cloning method and system is provided for cloning computer data from a source disk to a target disk. This disk-cloning method and system can be utilized, for example, in the computer assembly line to clone a preselected set of software programs to the main hard disk of each computer unit, or as a backup to a hard disk. This disk-cloning method and system is characterized in that the source data are read from the source disk and written onto the target disk in a sector-by-sector manner rather than in a file-by-file manner as the prior art. This feature allows the cloning procedure to be more efficiently carried out than the prior art. Moreover, it allows the disk-cloning procedure to be performed without having to make modifications to the existing FDT (File Directory Table) and FAT (File Allocation Table) on the target disk, thus ensuring the system security of the target disk. This disk-cloning method and system is therefore more reliable and efficient to use than the prior art.

Abstract: A dual-chip integrated circuit package and a method for manufacturing such a dual-chip integrated circuit package are proposed, which can help prevent the occurrence of cracking and delamination in the chips and the occurrence of voids in the encapsulant during the manufacture process. The dual-chip integrated circuit package is constructed on a leadframe having a plurality of first leads and a plurality of second leads and at least a pair of support members between the first and second leads. Further, the dual-chip integrated circuit package includes at least one support member attached to the front side of the first integrated circuit chip for providing a support to the bonding pads on the second integrated circuit chip; the support member being not smaller in dimension than the area where the bonding pads on the second integrated circuit chip are located.

Abstract: A QFN semiconductor package and a fabrication method thereof are proposed, wherein a lead frame having a plurality of leads is adopted, and each lead is formed at its inner end with a protruding portion. A wire bonding region and a bump attach region are respectively defined on opposite surfaces of the protruding portion, and staggered in position. This allows a force applied from a wire bonder to the wire bonding regions not to adversely affect solder bumps implanted on the bump attach regions, so that the solder bumps can be structurally assured without cracking. Moreover, the wire bonding regions spaced apart from the bump attach regions can be prevented from being contaminated by an etching solution used in solder bump implantation, so that wire bonding quality can be well maintained.

Abstract: A structure for fixing a roller on a base is disclosed. The structure includes a sheet-like elastomer having a guiding hole for trapping a shaft of the roller, and two fixing elements respectively disposed at two opposite sides of the base, which is located at two lateral sides of the roller, for receiving two ends of the sheet-like elastomer to provide a deformation of the sheet-like elastomer for providing a suppress power for the roller.