A method for manufacturing a semiconductor device may include the following steps: preparing a first substrate; providing a first conductor, which is configured to electrically connect two elements associated with the first substrate; providing a second conductor on the first substrate, wherein the second conductor is electrically connected to the first conductor; preparing a second substrate; providing a third conductor, which is configured to electrically connect two elements associated with the second substrate; providing a fourth conductor on the second substrate, wherein the fourth conductor is electrically connected to the third conductor; providing a fifth conductor on the fourth conductor; and combining the fifth conductor with the second conductor through eutectic bonding.

Micromachined ultrasonic transducers integrated with complementary metal oxide semiconductor (CMOS) substrates are described, as well as methods of fabricating such devices. Fabrication may involve two separate wafer bonding steps. Wafer bonding may be used to fabricate sealed cavities in a substrate. Wafer bonding may also be used to bond the substrate to another substrate, such as a CMOS wafer. At least the second wafer bonding may be performed at a low temperature.

A sensor chip combining a substrate comprising at least one CMOS circuit, a MEMS substrate and another substrate comprising at least one CMOS circuit in one package that is vertically stacked is disclosed. The package comprises a sensor chip further comprising a first substrate with a first surface and a second surface comprising at least one CMOS circuit; a MEMS substrate with a first surface and a second surface; and a second substrate comprising at least one CMOS circuit. Where the first surface of the first substrate is attached to a packaging substrate and the second surface of the first substrate is attached to the first surface of the MEMS substrate. The second surface of the MEMS substrate is attached to the second substrate. The first substrate, the MEMS substrate, the second substrate and the packaging substrate are mechanically attached and provided with electrical inter-connects.

A micromechanical sensor device includes an evaluation circuit formed in a first substrate, and an MEMS structure which is situated in a cavity delimited by a second substrate and a third substrate, the MEMS structure and the second substrate being situated on top of each other, the MEMS structure being functionally connected to the evaluation circuit via a contact area, the contact area between the MEMS structure and the first substrate being situated essentially centrally on the second substrate and essentially centrally on the first substrate and has an essentially punctiform configuration, proceeding radially from the contact area, a clearance being formed between the first substrate and the second substrate.

Magnet placement is described for integrated circuit packages. In one example, a terminal is applied to a magnet. The magnet is then placed on a top layer of a substrate with solder between the terminal and the top layer, and the solder is reflowed to attach the magnet to the substrate.

A manufacturing method for a micromechanical component. The method includes: providing an ASIC component including first front and rear sides, a strip conductor unit being provided at the first front side; providing a MEMS component including second front and rear sides, a micromechanical functional element situated in a cavity at the second front side; bonding the first front side onto the second front side; back-thinning the first rear side; forming vias starting from the back-thinned first rear side and from a redistribution unit on the first rear side, the vias electrically connecting the strip conductor unit to the redistribution unit; forming electrical contact elements on the redistribution unit; and back-thinning the second rear side. The back-thinning of the first and second rear side taking place so that a thickness of the stack made up of ASIC component and MEMS component is less than 300 micrometers.

A semiconductor device includes a microelectromechanical system (MEMS) die, a lid, and an integrated circuit die. The lid is over the MEMS die and defines a cavity between the lid and the MEMS die. The integrated circuit die is attached to an inner side of the lid. The integrated circuit die is electrically coupled to the MEMS die.

A vacuum sealed MEMS and CMOS package and a process for making the same may include a capping wafer having a surface with a plurality of first cavities, a first device having a first surface with a second plurality of second cavities, a hermetic seal between the first surface of the first device and the surface of the capping wafer, and a second device having a first surface bonded to a second surface of the first device. The second device is a CMOS device with conductive through vias connecting the first device to a second surface of the second device, and conductive bumps on the second surface of the second device. Conductive bumps connect to the conductive through vias and wherein a plurality of conductive bumps connect to the second device. The hermetic seal forms a plurality of micro chambers between the capping wafer and the first device.

Provided herein is a method including bonding a first oxide layer on a handle substrate to a second oxide layer on a complementary metal oxide semiconductor (“CMOS”), wherein the fusion bonding forms a unified oxide layer including a diaphragm overlying a cavity on the CMOS. The handle substrate is removed leaving the unified oxide layer. A piezoelectric film stack is deposited over the unified oxide layer. Vias are formed in the piezoelectric film stack and the unified oxide layer. An electrical contact layer is deposited, wherein the electrical contact layer electrically connects the piezoelectric film stack to an electrode on the CMOS.

A method of detecting defects in a high impedance network of a MEMs microphone sensor interface circuit. The method includes adding a high-voltage reset switch to a high-voltage high impedance network, closing the high-voltage reset switch during a start-up phase of the MEMs microphone sensor interface circuit, simultaneously closing a low-voltage reset switch of a low-voltage high impedance network during the start-up phase, simultaneously opening the high-voltage reset switch and the low-voltage reset switch at the end of the start-up phase, and detecting a defect in the high-voltage high impedance network or the low-voltage high impedance network immediately after opening the high-voltage reset switch and the low-voltage reset switch.