Abstract: A method for fabricating a semiconductor component with through interconnects can include the steps of providing a semiconductor substrate with substrate contacts, and forming openings from a backside of the substrate aligned with the substrate contacts. The method can also include the steps of providing an interposer substrate (or alternately a second semiconductor substrate), forming projections on the interposer substrate (or on the second semiconductor substrate), and forming conductive vias in the projections. The method can also include the steps of placing the projections in physical contact with the openings, and placing the conductive vias in electrical contact with the substrate contacts. The method can also include the steps of bonding the conductive vias to the substrate contacts, and forming terminal contacts on the interposer substrate (or alternately on one of the semiconductor substrates) in electrical communication with the conductive vias.

Abstract: A semiconductor component includes a semiconductor substrate having a substrate contact, and a through wire interconnect (TWI) bonded to the substrate contact. The through wire interconnect (TWI) includes a via through the substrate contact and the substrate, a wire in the via bonded to the substrate contact, and a contact on the wire. A stacked semiconductor component includes the semiconductor substrate, and a second semiconductor substrate stacked on the substrate and bonded to a through wire interconnect on the substrate. A method for fabricating a semiconductor component with a through wire interconnect includes the steps of providing a semiconductor substrate with a substrate contact, forming a via through the substrate contact and part way through the substrate, placing the wire in the via, bonding the wire to the substrate contact, and then thinning the substrate from a second side to expose a contact on the wire.

Abstract: An inventive method in an integrated circuit (IC) manufacturing process for using data regarding repair procedures conducted on ICs at probe to determine whether any further repairs will be conducted later in the manufacturing process includes storing the data in association with a fuse ID of each of the ICs. The ID codes of the ICs are automatically read, for example, at an opens/shorts test during the manufacturing process. The data stored in association with the ID codes of the ICs is then accessed, and additional repair procedures the ICs may undergo are selected in accordance with the accessed data. Thus, for example, the accessed data may indicate that an IC is unrepairable, so the IC can proceed directly to a scrap bin without having to be queried to determine whether it is repairable, as is necessary in traditional IC manufacturing processes.

Abstract: Microelectronic imager assemblies comprising a workpiece including a substrate and a plurality of imaging dies on and/or in the substrate. The substrate includes a front side and a back side, and the imaging dies comprise imaging sensors at the front side of the substrate and external contacts operatively coupled to the image sensors. The microelectronic imager assembly further comprises optics supports superimposed relative to the imaging dies. The optics supports can be directly on the substrate or on a cover over the substrate. Individual optics supports can have (a) an opening aligned with one of the image sensors, and (b) a bearing element at a reference distance from the image sensor. The microelectronic imager assembly can further include optical devices mounted or otherwise carried by the optics supports.

Abstract: A semiconductor component includes a semiconductor substrate having a substrate contact on a circuit side thereof in electrical communication with an integrated circuit, and a through interconnect in physical and electrical contact with the substrate contact configured to provide a signal path to a back side of the semiconductor substrate. The through interconnect includes an opening in the semiconductor substrate aligned with the substrate contact, and a projection on an interposer substrate (or alternately on a second semiconductor substrate) configured for mating physical engagement with the opening in the semiconductor substrate. The projection can also include a conductive via configured for electrical contact with a backside of the substrate contact and with a terminal contact for the component.

Abstract: Microlenses for directing radiation toward a sensor of an imaging device include a plurality of mutually adhered layers of cured optically transmissive material. Systems include at least one microprocessor and a substrate including an array of microlenses formed thereon in electrical communication with the at least one microprocessor. At least one microlens in the array includes a plurality of mutually adhered layers of cured optically transmissive material.

Abstract: A reusable burn-in/test fixture for testing unsingulated dice on a semiconductor wafer consisting of two halves. The first half of the test fixture is a wafer cavity plate for receiving the wafer, and the second half establishes electrical communication between the wafer and electrical testing equipment. A rigid substrate has conductors thereon which establish electrical contact with the wafer. The test fixture need not be opened until the burn-in and electrical testing are completed. After burn-in stress and electrical testing, it is possible to establish interconnection between the single die or separate and package dice into discrete parts, arrays or clusters, either as singulated parts or as arrays.

Abstract: Microelectronic imager assemblies comprising a workpiece including a substrate and a plurality of imaging dies on and/or in the substrate. The substrate includes a front side and a back side, and the imaging dies comprise imaging sensors at the front side of the substrate and external contacts operatively coupled to the image sensors. The microelectronic imager assembly further comprises optics supports superimposed relative to the imaging dies. The optics supports can be directly on the substrate or on a cover over the substrate. Individual optics supports can have (a) an opening aligned with one of the image sensors, and (b) a bearing element at a reference distance from the image sensor. The microelectronic imager assembly can further include optical devices mounted or otherwise carried by the optics supports.

Abstract: A semiconductor component includes a carrier and multiple semiconductor substrates stacked and interconnected on the carrier. The carrier includes conductive members bonded to corresponding conductive openings on the semiconductor substrates. The component can also include terminal contacts on the carrier in electrical communication with the conductive members, and an outer member for protecting the semiconductor substrates. A method for fabricating the component includes the steps of providing the carrier with the conductive members, and providing the semiconductor substrates with the conductive openings. The method also includes the step of aligning and placing the conductive openings on the conductive members, and then bonding the conductive members to the conductive openings.

Abstract: A semiconductor component includes a base die and a secondary die stacked on and bonded to the base die. The base die includes conductive vias which form an internal signal transmission system for the component, and allow the circuit side of the secondary die to be bonded to the back side of the base die. The component also includes an array of terminal contacts on the circuit side of the base die in electrical communication with the conductive vias. The component can also include an encapsulant on the back side of the base die, which substantially encapsulates the secondary die, and a polymer layer on the circuit side of the base die which functions as a protective layer, a rigidifying member and a stencil for forming the terminal contacts. A method for fabricating the component includes the step of bonding singulated secondary dice to base dice on a base wafer, or bonding a secondary wafer to the base wafer, or bonding singulated secondary dice to singulated base dice.

Abstract: Microlenses for directing radiation toward a sensor of an imaging device include a plurality of mutually adhered layers of cured optically transmissive material. Systems include at least one microprocessor and a substrate including an array of microlenses formed thereon in electrical communication with the at least one microprocessor. At least one microlens in the array includes a plurality of mutually adhered layers of cured optically transmissive material.

Abstract: A compliant contact pin assembly and a contactor card system are provided. The compliant contact pin assembly includes a contact pin formed from a portion of a substrate with the contact pin compliantly held suspended within the substrate by a compliant coupling structure. The suspension within the substrate results in a compliant deflection orthogonal to the plane of the substrate. The contact pin assembly is formed by generally thinning the substrate around the contact pin location and then specifically thinning the substrate immediately around the contact pin location for forming a void. The contact pin is compliantly coupled, in one embodiment by compliant coupling material, and in another embodiment by compliantly flexible portions of the substrate.

Abstract: A semiconductor component includes a thinned semiconductor die having protective polymer layers on up to six surfaces. The component also includes contact bumps on the die embedded in a circuit side polymer layer, and terminal contacts on the contact bumps in a dense area array. A method for fabricating the component includes the steps of providing a substrate containing multiple dice, forming trenches on the substrate proximate to peripheral edges of the dice, and depositing a polymer material into the trenches. In addition, the method includes the steps of planarizing the back side of the substrate to contact the polymer filled trenches, and cutting through the polymer trenches to singulate the components from the substrate. Prior to the singulating step the components can be tested and burned-in while they remain on the substrate.

Abstract: A semiconductor component includes back side pin contacts fabricated using a circuit side fabrication method. The component also includes a thinned semiconductor die having a pattern of die contacts, and conductive members formed by filled openings in the die contacts and the die. In addition, the pin contacts are formed by terminal portions of the conductive members. The fabrication method includes the steps of forming the openings and the conductive members, and then thinning and etching the die to form the pin contacts. An alternate embodiment female component includes female conductive members configured to physically and electrically engage pin contacts on a mating component of a stacked assembly.

Abstract: Semiconductor devices including through-wafer interconnects are disclosed. According to an embodiment of the present invention, a semiconductor device may comprise a substrate having a first surface and a second, opposing surface, and a through-wafer interconnect extending into the first surface of the substrate. The through-wafer interconnect may include an electrically conductive material extending from the first surface of the substrate to the second, opposing surface of the substrate. The through-wafer interconnect may also include a first dielectric material disposed between the electrically conductive material and the substrate and extending from the second, opposing surface of the substrate to the first portion of the conductive material.

Abstract: A method for fabricating a semiconductor component includes the steps of providing a substrate having a contact on a circuit side thereof, forming an opening from a backside of the substrate to the contact, forming a conductive via in the opening in electrical contact with a surface of the contact, and forming a second contact on the back side in electrical communication with the conductive via. The method can also include the steps of thinning the substrate from the backside, forming insulating layers on the circuit side and the backside, and forming a conductor and terminal contact on the circuit side in electrical communication with the conductive via. A semiconductor component includes the contact on the circuit side, the conductive via in electrical contact with the contact, and the second contact on the backside in electrical communication with the conductive via. The semiconductor component can also include the insulating layers, the conductor and the terminal contact.

Abstract: A conductive element is formed on a substrate by forming an organometallic layer on at least a portion of a surface of the substrate, heating a portion of the organometallic layer, and removing an unheated portion of the organometallic layer. In other methods, a flowable, uncured conductive material may be deposited on a surface of the substrate, the flowable, uncured conductive material may be selectively cured over at least a portion of the surface of the substrate, and a portion of the cured conductive material may be removed. A conductive via is formed by forming a hole at least partially through a thickness of a substrate, depositing an organometallic material within at least a portion of the hole, and selectively heating at least a portion of the organometallic material.

Abstract: A semiconductor component includes a thinned semiconductor die having protective polymer layers on up to six surfaces. The component also includes contact bumps on the die embedded in a circuit side polymer layer, and terminal contacts on the contact bumps in a dense area array. A method for fabricating the component includes the steps of providing a substrate containing multiple dice, forming trenches on the substrate proximate to peripheral edges of the dice, and depositing a polymer material into the trenches. In addition, the method includes the steps of planarizing the back side of the substrate to contact the polymer filled trenches, and cutting through the polymer trenches to simulate the components from the substrate. Prior to the simulating step the components can be tested and burned-in while they remain on the substrate.

Abstract: A system includes a semiconductor component having a base die and a secondary die flip chip mounted to the base die. The base die includes a set of stacking contacts for flip chip mounting the secondary die to the base die, and a set of interconnect contacts configured as an internal signal transmission system, and a physical structure for supporting a terminal contact system of the package component. The component also includes an encapsulant on the base die encapsulating the interconnect contacts, an underfill layer between the dice, and terminal contacts configured for flip chip mounting the package component to a supporting substrate.

Abstract: Methods for forming conductive vias or through-wafer interconnects in semiconductor substrates and resulting through-wafer interconnect structures are disclosed. In one embodiment of the present invention, a method of forming a through-wafer interconnect structure includes the acts of forming an aperture in a first surface of a substrate, depositing a first insulative or dielectric layer on an inner surface of the aperture, depositing an electrically conductive layer over the first dielectric layer, depositing a second insulative or dielectric layer on the inner surface of the aperture over the electrically conductive material, and exposing a portion of the electrically conductive layer through the second, opposing surface of the substrate. Semiconductor devices including through-wafer interconnects produced with the methods of the instant invention are also described.