Multi-chip module

Abstract: A stackable three dimensional leadless multi-chip module (10) is provided whereby each level of semiconductor device (11) is interconnected to another level through reflowing of solder plated wires (22). Each semiconductor device (11) contains a semiconductor die (24) overmolded by a package body (12) on a PCB substrate (14) having a plurality of edge metal conductors (16) that form half-vias (18). The half-vias (18) at the edges of substrate (14) give the substrate a castellated appearance, where the castellations serve as the self-aligning feature during the stacking of the devices (11). Each device (11) is simply stacked on top of each other without any additional layers to give the semiconductor module (10) a lowest possible profile. A plurality of solder plated wires (22) fits into the half-vias (18) and is solder reflowed to the metal conductors (16) to interconnect the semiconductor devices (11). The wires (22) are bent to enable the module (10) to be surface mounted to a PC board.

Abstract: A lead-over-chip single-in-line memory module (LOC SIMM) and method of manufacturing is disclosed that provides for shortened wire bonds and ease of rework for unacceptable semiconductor dice. More specifically, the LOC SIMM of the present invention includes a plurality of slots extending through a circuit board with an equal number of semiconductor dice attached thereto such that the active surfaces of the dice are exposed through the slots. Wire bonds or TAB connections are made from the exposed active surface of the die, through the slot, and to contacts on the top surface of the circuit board. Dice proven unacceptable during burn-in and electrical testing of the module are replaced by known good dice (KGD) by breaking their respective wire bonds, attaching a KGD to the circuit board, and forming new electrical connections between the KGD and the circuit board.

Abstract: A muti-chip module (MCM) assembly has three stacked integrated circuit (IC) layers. The first IC layer is electrically flip-chip connected to a substrate. The back of the second IC layer may be glued to the back of the first IC layer, and the second and third IC layers are electrically flip-chip connected to each other. In one embodiment, the third IC layer is electrically connected to the substrate through a vertical interconnect element for high circuit density. In another, the second IC layer is electrically connected to the substrate using wire bonding for greater post-fabrication customization flexibility. In still another embodiment, the MCM assembly comprises two stacked IC layers where the second IC layer is electrically flip-chip connected to the first IC layer and the second layer is electrically connected to the substrate through a vertical interconnect element. By directly connecting IC layers, higher circuit density, lower trace impedance, and lower cross-talk or electrical noise susceptibility is achieved over that presently offered by most current MCM assemblies. The assembly accommodates different sized IC layers, multiple ICs on each layer, and different technology-based IC layers and ICs within each layer, providing the user with high design flexibility within a single multi-chip assembly.

Abstract: A stacked flip chip assembly that substantially enhances integrated circuit density and reliability in a multi chip module by electrically coupling a first die to a conductive surface of a substrate through a flip chip attachment. The assembly further includes electrically coupling a second die to the first die through the flip chip attachment such that the second die is disposed on the first die and across from the substrate. The assembly also includes a third die electrically coupled to the second die through the flip chip attachment such that the third die is disposed on the second die and across from the second die and the substrate. Further, the second and third dies are electrically coupled to the substrate through the first and second dies by having conductive redistribution traces on sides of the first and second dies to route electrical signals from the second and third dies to the substrate and vice versa.