A MEMS module includes: a MEMS element provided with a substrate in which a hollow portion is formed, and including a movable portion, which is a part of the substrate, around the hollow portion, the movable portion having a thickness whose shape is changeable by an air pressure difference between an air pressure inside the hollow portion and an air pressure outside the substrate; and an electronic component, to which an output signal of the MEMS element is inputted, formed on the substrate, wherein the electronic component and the MEMS element are spaced apart from each other in a direction perpendicular to a thickness direction of the movable portion.

A MEMS module includes: a MEMS element provided with a substrate in which a hollow portion is formed, and including a movable portion, which is a part of the substrate, around the hollow portion, the movable portion having a thickness whose shape is changeable by an air pressure difference between an air pressure inside the hollow portion and an air pressure outside the substrate; and an electronic component, to which an output signal of the MEMS element is inputted, formed on the substrate, wherein the electronic component and the MEMS element are spaced apart from each other in a direction perpendicular to a thickness direction of the movable portion.

A MEMS module includes: a first MEMS element and a second MEMS element each including a movable portion which is a portion of a substrate including a hollow portion formed therein, the movable portion configured to warp in shape according to an air pressure difference between an internal air pressure inside the hollow portion and an external air pressure outside the hollow portion; and an electronic component configured to calculate a change in external air pressure outside the substrate by using an amount of warpage of the movable portion of at least one of the first MEMS element and the second MEMS element, wherein the amount of warpage of the movable portion according to the external air pressure differs between the first MEMS element and the second MEMS element.

A MEMS module includes: a first MEMS element and a second MEMS element each including a movable portion which is a portion of a substrate including a hollow portion formed therein, the movable portion configured to warp in shape according to an air pressure difference between an internal air pressure inside the hollow portion and an external air pressure outside the hollow portion; and an electronic component configured to calculate a change in external air pressure outside the substrate by using an amount of warpage of the movable portion of at least one of the first MEMS element and the second MEMS element, wherein the amount of warpage of the movable portion according to the external air pressure differs between the first MEMS element and the second MEMS element.

Various embodiments of the present disclosure are directed towards a method for manufacturing an integrated chip, the method comprises forming an interconnect structure over a semiconductor substrate. An upper dielectric layer is formed over the interconnect structure. An outgas layer is formed within the upper dielectric layer. The outgas layer comprises a first material that is amorphous. A microelectromechanical systems (MEMS) substrate is formed over the interconnect structure. The MEMS substrate comprises a moveable structure directly over the outgas layer.

Various embodiments of the present disclosure are directed towards a method for manufacturing an integrated chip, the method comprises forming an interconnect structure over a semiconductor substrate. An upper dielectric layer is formed over the interconnect structure. An outgas layer is formed within the upper dielectric layer. The outgas layer comprises a first material that is amorphous. A microelectromechanical systems (MEMS) substrate is formed over the interconnect structure. The MEMS substrate comprises a moveable structure directly over the outgas layer.

The present disclosure provides a bone-conduction sensor assembly. The bone-conduction sensor assembly includes a housing, a printed circuit board assembly forming a first receiving cavity together with the housing, a diaphragm accommodated in the first receiving cavity, a MEMS die and an ASIC chip mounted on the printed circuit board assembly. The MEMS die electrically connects to the ASIC chip through a bonding wire. A first weight is located on a surface of the diaphragm facing to the printed circuit board assembly. A position of the first weight has an avoiding portion corresponding to the bonding wire.

The present disclosure provides a bone-conduction sensor assembly. The bone-conduction sensor assembly includes a housing, a printed circuit board assembly forming a first receiving cavity together with the housing, a diaphragm accommodated in the first receiving cavity, a MEMS die and an ASIC chip mounted on the printed circuit board assembly. The MEMS die electrically connects to the ASIC chip through a bonding wire. A first weight is located on a surface of the diaphragm facing to the printed circuit board assembly. A position of the first weight has an avoiding portion corresponding to the bonding wire.

A microelectromechanical system (MEMS) transducer includes a substrate and a pair of electrodes supported by the substrate. The pair of electrodes are configured as a bias electrode-sense electrode couple. A moveable electrode of the pair of electrodes is configured for vibrational movement in a first direction during excitation of the moveable electrode. The pair of electrodes are spaced apart from one another by a gap in a second direction perpendicular to the first direction. The moveable electrode includes a cantilevered end, the cantilevered end being warped to exhibit a resting deflection along the first direction.

A microelectromechanical system (MEMS) transducer includes a substrate and a pair of electrodes supported by the substrate. The pair of electrodes are configured as a bias electrode-sense electrode couple. A moveable electrode of the pair of electrodes is configured for vibrational movement in a first direction during excitation of the moveable electrode. The pair of electrodes are spaced apart from one another by a gap in a second direction perpendicular to the first direction. The moveable electrode includes a cantilevered end, the cantilevered end being warped to exhibit a resting deflection along the first direction.