Abstract: A chip scale package (CSP) device includes a CSP having a semiconductor die electrically coupled to a plurality of solder balls. A can having an inside top surface and one or more side walls defines a chamber. The CSP is housed in the chamber and is attached to the inside top surface of the can. A printed circuit board is attached to the solder balls and to the one or more side walls to provide support to the CSP and to the can. The CSP may be a Wafer-Level CSP. The can may be built from a metallic substance or from a non-metallic substance. The can provides stress relief to the CSP during a drop test and during a thermal cycle test.

Abstract: An ultra-thin Quad Flat No-Lead (QFN) semiconductor chip package having a leadframe with lead terminals formed by recesses from both the top and bottom surfaces and substantially aligned contact areas formed on either the top or bottom surfaces. A die is electrically connected to the plurality of lead terminals and a molding compound encapsulates the leadframe and die together so as to form the ultra-thin QFN package. Accordingly, the substantially aligned contact areas are exposed on both the top and bottom surfaces of the package. The present disclosure also provides an ultra-thin Optical Quad Flat No-Lead (OQFN) semiconductor chip package, a stacked semiconductor module comprising at least two QFN semiconductor chip packages, and a method for manufacturing an ultra-thin Quad Flat No-Lead (QFN) semiconductor packages.

Abstract: An ultra-thin Quad Flat No-Lead (QFN) semiconductor chip package having a leadframe with lead terminals formed by recesses from both the top and bottom surfaces and substantially aligned contact areas formed on either the top or bottom surfaces. A die is electrically connected to the plurality of lead terminals and a molding compound encapsulates the leadframe and die together so as to form the ultra-thin QFN package. Accordingly, the substantially aligned contact areas are exposed on both the top and bottom surfaces of the package. The present disclosure also provides an ultra-thin Optical Quad Flat No-Lead (OQFN) semiconductor chip package, a stacked semiconductor module comprising at least two QFN semiconductor chip packages, and a method for manufacturing an ultra-thin Quad Flat No-Lead (QFN) semiconductor packages.

Abstract: A fan-out wafer level package includes a semiconductor die with contact pads positioned on a top surface. A fan-in redistribution layer positioned over the die includes contact pads in electrical communication with the first contact pads of the die. A buffer layer positioned over the fan-in layer includes a plurality of vias, in electrical contact with the contact pads of the fan-in layer. A fan-in redistribution layer is positioned over the buffer layer and includes contact pads on a surface opposite the buffer layer, in electrical communication with the vias. The semiconductor die, fan-in layer, and buffer layer are encapsulated in a molding com-pound layer. Solder contacts, for electrically connecting the semiconductor device to a electronic circuit board, are positioned on contact pads of the fan-out layer. The buffer layer has a substantial thickness, to reduce and distribute shear stresses resulting from thermal mismatch of coefficients of thermal expansion of the semiconductor die and a circuit board.

Abstract: An optical sensor package has a transparent substrate with a redistribution layer formed on a face thereof, which includes a window and a plurality of electrically conductive traces. A semiconductor substrate, including an optical sensor and a plurality of contact terminals on a face thereof, is positioned on the transparent substrate in a face-to-face arrangement, with the optical sensor directly opposite the window, and with each of the contact terminals electrically coupled to a respective one of the electrically conductive terminals. The transparent substrate has larger overall dimensions than the semiconductor substrate, so that one or more edges of the transparent substrate extend beyond the corresponding edges of the semiconductor substrate. A plurality of solder balls are positioned on the face of the transparent substrate, each in electrical contact with a respective one of the electrically conductive terminals.

Abstract: A flip-chip fan-out wafer level package for package-on-package applications includes a semiconductor die with solder bumps on an upper surface in a flip chip configuration. The die is inverted, with an upper surface facing an upper side of a redistribution layer, with the solder bumps in electrical contact with respective chip contact pads of the redistribution layer. The redistribution layer includes conductive traces that place each of the solder bumps in electrical contact with one or both of one of a plurality of upper redistribution contact pads and one of a plurality of lower redistribution contact pads. Each of the plurality of upper redistribution contact pads has an upper solder ball in electrical contact therewith. The die and the upper solder balls are at least partially encapsulated in a layer of mold compound positioned on the upper surface of the redistribution layer, and whose lateral dimensions are defined by the lateral dimensions of the redistribution layer.

Abstract: A polymeric layer encompassing the solder elements of a ball grid array in an electronics package. The polymeric layer reinforces the solder bond at the solder ball-component interface by encasing the elements of the ball grid array in a rigid polymer layer that is adhered to the package structure. Stress applied to the package through the ball grid array is transmitted to the package structure through the polymeric layer, bypassing the solder joint and improving mechanical and electrical circuit reliability. In one embodiment of a method for making the polymeric layer, solder elements bonded to external pads on a structure of the package are submerged in a fluidic form of the polymeric layer. The fluidic form is solidified and then a portion of the resulting polymeric layer is removed to make the solder elements accessible for mounting the package to a printed circuit board or other external circuit.

Abstract: A multi-stack semiconductor dice assembly has enhanced board-level reliability and integrated electrical functionalities over a common package foot-print. The multi-stack semiconductor dice assembly includes a bottom die having a stepped upper surface. The stepped upper surface includes a base region and a stepped region, which is raised relative to the base region. The base region includes a plurality of attachment structures that are sized and shaped to receive electrically conductive balls. An upper die is stacked above the bottom die. The upper die includes a plurality of attachment structures that are sized and shaped to receive electrically conductive balls and are arranged to align with the attachment structures of the bottom die. Electrically conductive balls are attached to the attachment structures of the bottom die and the attachment structures of the upper die.

Abstract: A ball grid array (BGA) package includes a substrate layer having first and second sides. A semiconductor chip is attached to the first side of the substrate layer by a dielectric adhesive layer. A plurality of solder balls are attached to the second side of the substrate layer. The solder balls may be set out by rows and columns. A plurality of wires electrically connect the semiconductor chip to the solder balls. A layer of encapsulating compound is deposited over the semiconductor chip. A step cavity of a selected depth and shape is formed in the layer of encapsulating compound at or near the edge or periphery of the layer of encapsulating compound. The step cavity is separated from the solder balls by the substrate layer but spans over a plurality of selected solder balls.

Abstract: A ball grid array (BGA) package includes a substrate layer having first and second sides. A semiconductor chip is attached to the first side of the substrate layer by a dielectric adhesive layer. A plurality of solder balls are attached to the second side of the substrate layer. The solder balls may be set out by rows and columns. A plurality of wires electrically connect the semiconductor chip to the solder balls. A layer of encapsulating compound is deposited over the semiconductor chip. A step cavity of a selected depth and shape is formed in the layer of encapsulating compound at or near the edge or periphery of the layer of encapsulating compound. The step cavity is separated from the solder balls by the substrate layer but spans over a plurality of selected solder balls.

Abstract: A chip scale package (CSP) device includes a CSP having a semiconductor die electrically coupled to a plurality of solder balls. A can having an inside top surface and one or more side walls defines a chamber. The CSP is housed in the chamber and is attached to the inside top surface of the can. A printed circuit board is attached to the solder balls and to the one or more side walls to provide support to the CSP and to the can. The CSP may be a Wafer-Level CSP. The can may be built from a metallic substance or from a non-metallic substance. The can provides stress relief to the CSP during a drop test and during a thermal cycle test.

Abstract: A thermally enhanced ball grid array package is disclosed. The package includes a base layer element and a flip chip die mounted on the base layer element. The die has a first surface electrically coupled to the base layer element, a second surface opposite to the first surface, and lateral sides. A molding compound encapsulates the base layer element and the lateral sides of the die. A surface is formed of the second surface of the die and an upper surface of the molding compound. A material is disposed on the surface, and a heat spreader is mounted on the material.

Abstract: An ultra-thin Quad Flat No-Lead (QFN) semiconductor chip package having a leadframe with lead terminals formed by recesses from both the top and bottom surfaces and substantially aligned contact areas formed on either the top or bottom surfaces. A die is electrically connected to the plurality of lead terminals and a molding compound encapsulates the leadframe and die together so as to form the ultra-thin QFN package. Accordingly, the substantially aligned contact areas are exposed on both the top and bottom surfaces of the package. The present disclosure also provides an ultra-thin Optical Quad Flat No-Lead (OQFN) semiconductor chip package, a stacked semiconductor module comprising at least two QFN semiconductor chip packages, and a method for manufacturing an ultra-thin Quad Flat No-Lead (QFN) semiconductor packages.

Abstract: An exercise trainer having a first crank arm and a second crank arm respectively connected to a first foot link and a second foot link with foot pedals supported on the foot links, and bearing supports for the foot links removed from the crank arms. A flexible connection connects a ground point, the foot pedals, and the foot links to provide relative movement in a modified ellipse as to the ground point of at least twice the length of each crank arm. A seat is mounted on the trainer having a motor and control for raising and lowering the seat with respect to the foot pedals. The first and second crank arms are connected to a motor for driving the crank arms at a given speed which can supplement a user's effort or provide a load to a user beyond a given speed.

Abstract: A lower body exercise machine has a pair of laterally spaced apart foot members. The foot members are coupled to a frame which supports the exercise machine. First and second guide linkages are pivotally connected to the frame. First and second articulating linkages are pivotally connected to each corresponding guide linkages and to a pair of crank arms. The foot members are pivotally connected to the articulating linkages. The size, shape and connection between the various components and linkages is such that each foot member guides the foot of a user along a preferred anatomical deep stride path simulative of natural running motion.