A multi-device module, comprising: a first substrate, which houses a first MEMS transducer, designed to transduce a first environmental quantity into a first electrical signal, and an integrated circuit, coupled to the first MEMS transducer for receiving the first electrical signal; a second substrate, which houses a second MEMS transducer, designed to transduce a second environmental quantity into a second electrical signal; and a flexible printed circuit, mechanically connected to the first and second substrates and electrically coupled to the integrated circuit and to the second MEMS transducer so that the second electrical signal flows, in use, from the second MEMS transducer to the integrated circuit.

A microelectronic assembly can include a substrate having first and second surfaces and an aperture extending therebetween, the substrate having terminals. The assembly can also include a first microelectronic element having a front surface facing the first surface of the substrate, a second microelectronic element having a front surface facing the first microelectronic element and projecting beyond an edge of the first microelectronic element, first and second leads electrically connecting contacts of the respective first and second microelectronic elements to the terminals, and third leads electrically interconnecting the contacts of the first and second microelectronic elements. The contacts of the first microelectronic element can be exposed at the front surface thereof adjacent the edge thereof. The contacts of the second microelectronic element can be disposed in a central region of the front surface thereof. The first, second, and third leads can have portions aligned with the aperture.

The MEMS microphone includes a first circuit board; a second circuit board keeping a distance from the first circuit board; a frame located between the first circuit board and the second circuit board for forming a cavity cooperatively with the first circuit board and the second circuit board, the frame including a plated-through-hole; an ASIC chip located in the cavity; and an MEMS chip having a back cavity. The first circuit board is electrically connected with the second circuit board by the plated-through-hole. The frame includes a conductive layer and an insulating layer, and the conductive layer is located between an inner surface of the frame and the insulating layer.

A substrate structure including a carrier and a substrate is provided. The carrier includes a release layer, a dielectric layer and a metal layer. The dielectric layer is disposed between the release layer and the metal layer. The substrate includes a packaging region and a peripheral region. The peripheral region is connected to the packaging region and surrounds the packaging region. The peripheral region or the packaging region has a plurality of through holes. The substrate is disposed on the carrier. The release layer is located between the substrate and the dielectric layer. The release layer and the dielectric layer are filled in the through hole such that the substrate is separably attached to the carrier.

A process for manufacturing a packaged microelectromechanical device includes: forming a lid having a face and a cavity open on the face; coating the face of the lid and walls of the cavity with a metal layer containing copper; and coating the metal layer with a protective layer.

An imager module for a vehicle camera, the imager module having at least: a lens holder, a lens accommodated in the lens holder, a flexible conductor device having leads, and an image sensor contacted by the leads of the flexible conductor device that has a front side having a sensitive surface; the image sensor being contacted by the leads using flip-chip technology via stud bumps provided at the front side thereof. The lens holder has a plastic part, in particular an injection-molded part, having a tubular region for accommodating the lens and a fastening region having a bottom side; and the flexible conductor device being integrally attached to the bottom side of the fastening region, and a non-conductive adhesive region being formed between the front side of the image sensor and the flexible conductor device around the stud bumps, preferably to produce a tensile stress. An insertion part is preferably received in the plastic body.

A pressure sensor package includes a pressure sensor having a first side attached to a substrate and a second side opposite the first side, the first side having a pressure inlet aligned with an opening in the substrate, the second side having one or more electrical contacts. A logic die attached to an opposite side of the substrate as the pressure sensor is operable to process signals from the pressure sensor. First electrical conductors connect to the one or more electrical contacts of the pressure sensor. Second electrical conductors connect to one or more electrical contacts of the logic die. A mold compound completely encapsulates the second electrical conductors and at least partly encapsulates the logic die and the first electrical conductors. An open passage in the mold compound is aligned with the opening in the substrate so as to define a pressure port of the pressure sensor package.

A system-in-package module with memory includes a non-memory chip, a substrate, and a memory chip. The non-memory chip has a first portion and a second portion. The substrate has a window and the substrate is electrically connected to the second portion of the non-memory chip. The memory chip is placed into the window of the substrate to electrically connect the first portion of the non-memory chip, and there is no direct metal connection between the memory chip and the substrate.

A semiconductor package structure is provided. The semiconductor package structure includes a substrate, a first semiconductor die, and a second semiconductor die. The substrate includes a first substrate partition and a second substrate partition. The first substrate partition has a first wiring structure. The second substrate partition is adjacent to the first substrate partition and has a second wiring structure. The first substrate partition and the second substrate partition are surrounded by a first molding material. The first semiconductor die is disposed over the substrate and electrically coupled to the first wiring structure. The second semiconductor die is disposed over the substrate and electrically coupled to the second wiring structure.

In a flexible printed wiring board (1), a first electrical conduction pattern (4) prepared on the first surface (3a) on which a bare chip (2) is mounted is prepared only inside a mounting region (3c) of the bare chip. Preferably, the first electrical conduction patterns (4) are prepared so as to avoid positions opposite to test electrodes (2b) which the bare chip comprises. Thereby, in the flexible printed wiring board used for mounting the bare chip, occurrence of malfunction resulting from electrical connection with a part other than a bump of the bare chip can be certainly prevented, and reliability of various devices using the bare chip can be improved.