A method produces a device adapted to be implanted into the human body for purposes such as neural stimulation, sensing or the like. The method includes: providing a stretchable layer or membrane of an insulating material; forming on the layer or membrane at least one stretchable conductive path; depositing at least one small bolus of a soft and conductive paste or material onto pre-defined areas or portions of the at least one conductive path, and inserting a first end portion of a conductive element 71 into the at least one bolus of soft conductive paste or material. A second end portion of the conductive element opposite to the first end portion is not inserted into the at least one bolus.

A transient electronic device utilizes a glass-based interposer that is treated using ion-exchange processing to increase its fragility, and includes a trigger device operably mounted on a surface thereof. An integrated circuit (IC) die is then bonded to the interposer, and the interposer is mounted to a package structure where it serves, under normal operating conditions, to operably connect the IC die to the package I/O pins/balls. During a transient event (e.g., when unauthorized tampering is detected), a trigger signal is transmitted to the trigger device, causing the trigger device to generate an initial fracture force that is applied onto the glass-based interposer substrate. The interposer is configured such that the initial fracture force propagates through the glass-based interposer substrate with sufficient energy to both entirely powderize the interposer, and to transfer to the IC die, whereby the IC die also powderizes (i.e., visually disappears).

The present invention relates to an improved electronic circuit, as well as an improved substrate with electronic circuits, with an identification pattern. The invention makes it possible to make them identifiable and amongst other things to retrace the circuit(s) in this way through the production process. Furthermore, the invention relates to an improved production method for circuits and substrates according to the invention.

A semiconductor device and a method of making the same are provided. A first die and a second die are placed over a carrier substrate. A first molding material is formed adjacent to the first die and the second die. A first redistribution layer is formed overlying the first molding material. A through via is formed over the first redistribution layer. A package component is on the first redistribution layer next to the copper pillar. The package component includes a second redistribution layer. The package component is positioned so that it overlies both the first die and the second die in part. A second molding material is formed adjacent to the package component and the first copper pillar. A third redistribution layer is formed overlying the second molding material. The second redistribution layer is placed on a substrate and bonded to the substrate.

A semiconductor structure includes a packaged semiconductor device having at least one device, a conductive pillar, an encapsulant over the at least one device and surrounding the conductive pillar, wherein the conductive pillar extends from a first major surface to a second major surface of the encapsulant, and is exposed at the second major surface and the at least one device is exposed at the first major surface. The packaged device also includes a conductive shield layer on the second major surface of the encapsulant and on minor surfaces of the encapsulant and an isolation region at the second major surface of the encapsulant between the encapsulant and the conductive pillar such that the conductive shield layer is electrically isolated from the conductive pillar. The semiconductor structure also includes a radio-frequency connection structure over and in electrical contact with the conductive pillar at the second major surface of the encapsulant.

Electrical interconnect technology for a package substrate is disclosed. A substrate can include a first conductive element at least partially disposed in a first routing layer, and a second conductive element at least partially disposed in a second routing layer. The first and second routing layers are adjacent routing layers. The substrate can also include a third conductive element having first and second portions disposed in the first routing layer, and an intermediate third portion disposed in a “sub-interconnect layer” between the first and second routing layers.

A method includes forming one or more vias in a first layer, forming one or more vias in at least a second layer different than the first layer, aligning at least a first via in the first layer with at least a second via in the second layer, and bonding the first layer to the second layer by filling the first via and the second via with solder material using injection molded soldering.

A method for manufacturing a circuit redistribution structure includes the following steps. A first dielectric is formed on a carrier. Conductive blind vias are formed in the first dielectric. A first circuit redistribution layer is formed on the first dielectric. A second dielectric is formed on the first dielectric. First and second holes are formed on the second dielectric. A trench is formed in the second dielectric to divide the second dielectric into first and second portions. A first portion of the first circuit redistribution layer and the first hole are disposed in the first portion of the second dielectric, and a second portion of the first circuit redistribution layer and the second hole are disposed in the second portion of the second dielectric. Conductive blind vias are formed in the first and second holes, and a second circuit redistribution layer is formed on the second dielectric.

Methods of forming a microelectronic packaging structure and associated structures formed thereby are described. Those methods may include forming a cavity in a plating material to hold a die, attaching the die in the cavity, forming a dielectric material adjacent the die, forming vias in the dielectric material adjacent the die, forming PoP lands in the vias, forming interconnects in the vias, and then removing the plating material to expose the PoP lands and die, wherein the die is disposed above the PoP lands.

This invention provides a multi-pin semiconductor device as a low-cost flip-chip BGA. In the flip-chip BGA, a plurality of signal bonding electrodes in a peripheral area of the upper surface of a multilayer wiring substrate are separated into inner and outer ones and a plurality of signal through holes coupled to a plurality of signal wirings drawn inside are located between a plurality of rows of signal bonding electrodes and a central region where a plurality of bonding electrodes for core power supply are located so that the chip pad pitch can be decreased and the cost of the BGA can be reduced without an increase in the number of layers in the multilayer wiring substrate.