A method for fabricating a MEMS device includes depositing and patterning a first sacrificial layer onto a silicon substrate, the first sacrificial layer being partially removed leaving a first remaining oxide. Further, the method includes depositing a conductive structure layer onto the silicon substrate, the conductive structure layer making physical contact with at least a portion of the silicon substrate. Further, a second sacrificial layer is formed on top of the conductive structure layer. Patterning and etching of the silicon substrate is performed stopping at the second sacrificial layer. Additionally, the MEMS substrate is bonded to a CMOS wafer, the CMOS wafer having formed thereupon a metal layer. An electrical connection is formed between the MEMS substrate and the metal layer.

A highly reliable micromachine, display element, or the like is provided. As a micromachine or a transistor including the micromachine, a transistor including an oxide semiconductor in a semiconductor layer where a channel is formed is used. For example, a transistor including an oxide semiconductor is used as at least one transistor in one or a plurality of transistors driving a micromachine.

A method for integrating complementary metal-oxide-semiconductor (CMOS) devices with a microelectromechanical systems (MEMS) device using a flat surface above a sacrificial layer is provided. In some embodiments, a back-end-of-line (BEOL) interconnect structure is formed covering a semiconductor substrate, where the BEOL interconnect structure comprises a first dielectric region. A sacrificial layer is formed over the first dielectric region, and a second dielectric region is formed covering the sacrificial layer and the first dielectric region. A planarization is performed into an upper surface of the second dielectric region to planarize the upper surface. A MEMS structure is formed on the planar upper surface of the second dielectric region. A cavity etch is performed into the sacrificial layer, through the MEMS structure, to remove the sacrificial layer and to form a cavity in place of the sacrificial layer. An integrated circuit (IC) resulting from the method is also provided.

To implement a single-chip ultrasonic imaging solution, on-chip signal processing may be employed in the receive signal path to reduce data bandwidth and a high-speed serial data module may be used to move data for all received channels off-chip as digital data stream. The digitization of received signals on-chip allows advanced digital signal processing to be performed on-chip, and thus permits the full integration of an entire ultrasonic imaging system on a single semiconductor substrate. Various novel waveform generation techniques, transducer configuration and biasing methodologies, etc., are likewise disclosed. HIFU methods may additionally or alternatively be employed as a component of the “ultrasound-on-a-chip” solution disclosed herein.

Implementations of absolute pressure sensor devices may include a microelectromechanical system (MEMS) absolute pressure sensor coupled over a controller die. The MEMS absolute pressure sensor may be mechanically coupled to the controller die and may also be configured to electrically couple with the controller die. A perimeter of the controller die may be one of the same size and larger than a perimeter of the MEMS absolute pressure sensor. The controller die may be configured to electrically couple with a module through an electrical connector.

In one embodiment, a ruggedized wafer level microelectromechanical (“MEMS”) force sensor includes a base and a cap. The MEMS force sensor includes a flexible membrane and a sensing element. The sensing element is electrically connected to integrated complementary metal-oxide-semiconductor (“CMOS”) circuitry provided on the same substrate as the sensing element. The CMOS circuitry can be configured to amplify, digitize, calibrate, store, and/or communicate force values through electrical terminals to external circuitry.

According to one embodiment, a strain and pressure sensing device includes a semiconductor circuit unit and a sensing unit. The semiconductor circuit unit includes a semiconductor substrate and a transistor. The transistor is provided on a semiconductor substrate. The sensing unit is provided on the semiconductor circuit unit, and has space and non-space portions. The non-space portion is juxtaposed with the space portion. The sensing unit further includes a movable beam, a strain sensing element unit, and first and second buried interconnects. The movable beam has fixed and movable portions, and includes first and second interconnect layers. The fixed portion is fixed to the non-space portion. The movable portion is separated from the transistor and extends from the fixed portion into the space portion. The strain sensing element unit is fixed to the movable portion. The first and second buried interconnects are provided in the non-space portion.

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 device comprises a silicon-on-insulator (SOI) substrate having first and second silicon layers with an insulator layer interposed between them. A structural layer, having a first conductivity type, is formed on the first silicon layer. A well region, having a second conductivity type opposite from the first conductivity type, is formed in the structural layer, and resistors are diffused in the well region. A metallization structure is formed over the well region and the resistors. A first cavity extends through the metallization structure overlying the well region and a second cavity extends through the second silicon layer, with the second cavity stopping at one of the first silicon layer and the insulator layer. The well region interposed between the first and second cavities defines a diaphragm of a pressure sensor. An integrated circuit and the pressure sensor can be fabricated concurrently on the SOI substrate using a CMOS fabrication process.

Embodiments of the present disclosure are directed toward through-silicon via (TSV)-based devices and associated techniques and configurations. In one embodiment, an apparatus includes a die having active circuitry disposed on a first side of the die and a second side disposed opposite to the first side, a bulk semiconductor material disposed between the first side and the second side of the die and a device including one or more of a capacitor, resistor or resonator disposed in the bulk semiconductor material, the capacitor, resistor or resonator including one or more TSV structures that extend through the bulk semiconductor material, an electrically insulative material disposed in the one or more TSV structures and an electrode material or resistor material in contact with the electrically insulative material within the one or more TSV structures.