Abstract: Methods for depositing a measured amount of a species in a sealed cavity. In one example, a method for depositing molecules in a sealed cavity includes depositing a selected number of microcapsules in a cavity. Each of the microcapsules contains a predetermined amount of a first fluid. The cavity is sealed after the microcapsules are deposited. After the cavity is sealed the microcapsules are ruptured to release molecules of the first fluid into the cavity.

Abstract: Methods for depositing a measured amount of a species in a sealed cavity. In one example, a method for depositing molecules in a sealed cavity includes depositing a selected number of microcapsules in a cavity. Each of the microcapsules contains a predetermined amount of a first fluid. The cavity is sealed after the microcapsules are deposited. After the cavity is sealed the microcapsules are ruptured to release molecules of the first fluid into the cavity.

Abstract: A method for forming a semiconductor device includes physically attaching a first semiconductor die to front surface of a first substrate. The first die is electrically connected to routings on front surface of the first substrate. The routings are electrically connected with conductive pads on back surface of the first substrate. A second semiconductor die is physically attached to front surface of a second substrate. The die is electrically connected to routings on front surface of second substrate. These routings are electrically connected with conductive pads on front surface of the second substrate. A third semiconductor die is physically attached to the second die. The third die is electrically attached to the second die through a plurality of through substrate vias (TSVs) within the second die. The conductive pads on back surface of first substrate are electrically connected to the conductive pads on front surface of second substrate.

Abstract: A semiconductor device including a first memory die having a first memory type, a second memory die having a second memory type different from the first memory type, and a logic die such as a microprocessor. The first memory die can be electrically connected to the logic die using a first type of electrical connection preferred for the first memory type. The second memory die can be electrically connected to the logic die using a second type of electrical connection different from the first type of electrical connection which is preferred for the second memory type. Other devices can include dies all of the same type, or two or more dies of a first type and two or more dies of a second type different from the first type.

Abstract: A method for forming a semiconductor device includes physically attaching a first semiconductor die to front surface of a first substrate. The first die is electrically connected to routings on front surface of the first substrate. The routings are electrically connected with conductive pads on back surface of the first substrate. A second semiconductor die is physically attached to front surface of a second substrate. The die is electrically connected to routings on front surface of second substrate. These routings are electrically connected with conductive pads on front surface of the second substrate. A third semiconductor die is physically attached to the second die. The third die is electrically attached to the second die through a plurality of through substrate vias (TSVs) within the second die. The conductive pads on back surface of first substrate are electrically connected to the conductive pads on front surface of second substrate.

Abstract: A semiconductor device including a first memory die having a first memory type, a second memory die having a second memory type different from the first memory type, and a logic die such as a microprocessor. The first memory die can be electrically connected to the logic die using a first type of electrical connection preferred for the first memory type. The second memory die can be electrically connected to the logic die using a second type of electrical connection different from the first type of electrical connection which is preferred for the second memory type. Other devices can include dies all of the same type, or two or more dies of a first type and two or more dies of a second type different from the first type.

Abstract: Stacked semiconductor chip package system vertical interconnects and related methods are disclosed. A preferred embodiment of the invention includes a first semiconductor chip with a surface bearing a plurality of first fusible metallic coupling elements. A second semiconductor chip has a plurality of second fusible metallic coupling elements. The first and second fusible metallic coupling elements correspond at the adjoining surfaces of the first and second semiconductor chips when stacked, and are fused to form a gold-tin eutectic alloy fused metallic coupling vertically interconnecting the stacked chips.

Abstract: An insulating sheet-like substrate (601), which has on one surface (601a) a first patterned metal layer (605) with a first (603a) and a second (603b) array of contact pads. The pads of the first array have a first pitch center-to-center, and each pad has a first perimeter. The pads of the second array have a second pitch center-to-center, and each pad has the first perimeter. The substrate has on its other surface (601b) a second patterned metal layer (606) with a third array (607) of contact pads, which has the first pitch center-to-center, and each pad has a third perimeter. Conductive vias (640) between the first and the second metal layers connect contact pads and have a fourth perimeter; the vias are placed in interstitial locations so that the fourth perimeter does not intersect with the first and third perimeters. Vias in interstitial locations can be provided by disposing the first array and the third array so that the first and third perimeters of respective contact pads are concentrically aligned.

Abstract: A semiconductor system (300) has one or more packaged active subsystems (310, 330); each subsystem has a substrate with electrical contact pads and one or more semiconductor chips stacked on top of each other, assembled on the substrate. The system further has a packaged passive subsystem (320) including a substrate with electrical contacts and passive electrical components, such as resistors, capacitors, and indictors. The passive subsystem is stacked with the active subsystems and connected to them by solder bodies.

Abstract: A semiconductor system (200) of one or more semiconductor interposers (201) with a certain dimension (210), conductive vias (212) extending from the first to the second surface, with terminals and attached non-reflow metal studs (215) at the ends of the vias. A semiconducting interposer surface may include discrete electronic components or an integrated circuit. One or more semiconductor chips (202, 203) have a dimension (220, 230) narrower than the interposer dimension, and an active surface with terminals and non-reflow metal studs (224, 234). One chip is flip-attached to the first interposer surface, and another chip to the second interposer surface, so that the interposer dimension projects over the chip dimension. An insulating substrate (204) has terminals and reflow bodies (242) to connect to the studs of the projecting interposer.

Abstract: A system (100), which has an electrically insulating substrate (101) with a thickness, a first and a second surface. Electrically conductive paths (110) extend through the insulating body from the first to the second surface and have exit ports (120) at the end of the conductive paths on the first and the second surface. A cavity (130) extends downwardly from the first surface to a depth less than the thickness; the bottom of the cavity and the first substrate surface have contact pads (141). The substrate further has electrically conductive lines (150) between the first and the second surface and under the cavity, contacting the paths. The system includes a stack of semiconductor chips (160,170) with bond pads; one chip is attached to the bottom of the cavity and one chip is electrically connected to substrate contact pads.