A membrane-based sensor in one embodiment includes a membrane layer including an upper surface and a lower surface, a backside trench defined on one side by the lower surface, a central cavity defined on a first side by the upper surface, a cap layer positioned above the central cavity, and a first spacer extending from the upper surface to the cap layer and integrally formed with the cap layer, the first spacer defining a second side of the central cavity and an inner membrane portion of the membrane layer.

A differential MEMS pressure sensor includes a topping wafer with a top side and a bottom side, a diaphragm wafer having a top side connected to the bottom side of the topping wafer and a bottom side, and a backing wafer having a top side connected to the bottom side of the diaphragm wafer and a bottom side. The topping wafer includes a first cavity formed in the bottom side of the topping wafer. The diaphragm wafer includes a diaphragm, a second cavity formed in the bottom side of the diaphragm wafer underneath the diaphragm, an outer portion surrounding the diaphragm, and a trench formed in the top side of the diaphragm wafer and positioned in the outer portion surrounding the diaphragm.

In an embodiment, a pressure sensor module includes a base electrode surrounding at least a part of a bottom electrode, an anchor arrangement on top of the base electrode including at least two electrically conductive walls that both surround at least the part of the bottom electrode and an electrically conductive layer that covers at least the bottom electrode and the anchor arrangement such that a cavity is formed between the bottom electrode, the anchor arrangement and the electrically conductive layer, wherein, on at least one side of the cavity, a proportionate area of the electrically conductive walls in a cross section extending from a surface of an inner wall of the anchor arrangement facing the cavity to a surface of an outermost wall of the anchor arrangement facing away from the cavity in a plane parallel to a plane of the bottom electrode is equal to or less than 10%.

A pressure sensor includes a lidless structure defining an internal chamber for a sealed environment and presenting an aperture; a chip including a membrane deformable on the basis of external pressure, the chip being mounted outside the lidless structure in correspondence to the aperture so that the membrane closes the sealed environment; and a circuitry configured to provide a pressure measurement information based on the deformation of the membrane.

A membrane, a pressure sensor system and a method for producing the pressure sensor system are disclosed. In an embodiment a pressure sensor system includes a housing, at least one media supply line and a pressure-sensitive element including at least one membrane with a hydrophobic region.

A pressure sensor using an electric field effect, the pressure sensor includes a first electrode extending in a vertical direction and defining a core region, a second electrode disposed to entirely surround the first electrode, a first insulating layer interposed between the first and second electrodes, a ground electrode electrically insulated from the second electrode, the ground electrode being disposed to surround the second electrode and a membrane connected to the ground electrode and positioned to cover the first and second electrodes, and the membrane being provided to generate an electric field in an adjacent region together with the first and second electrodes, and being configured to make the electric field to distort when an object approaches thereto.

An apparatus in the field of optics technology, can include a reflector, a reflector substrate, and an extinction component. The reflector can be mounted on the reflector substrate. The extinction component can be arranged on a front surface of the reflector substrate. The reflector can be configured to reflect incident light signals. The extinction component can be configured to reduce the scattered light produced by the incident light signal on the reflector substrate. An optical scanning device (for example, lidar) having such features may greatly reduce the scattered light inside the lidar, reduce the detection blind area caused by the stray light, and greatly improve the receiving and detecting capabilities of the lidar.

A method of fabricating a capacitive micromechanical electrical system (MEMS) pressure sensor includes the steps of forming a backing wafer, forming a diaphragm wafer that includes a diaphragm configured to deflect from an applied force and a pressure cavity configured to produce on the diaphragm the applied force which is indicative of a system pressure; fusing the diaphragm wafer to the backing wafer thereby forming a base wafer, forming a top wafer, joining the top wafer to the base wafer, thereby forming a detector wafer. The diaphragm defines a first capacitor surface and the top wafer defines a second capacitor surface. A void separates the second capacitor surface from the first capacitor surface by a separation distance which is a capacitor gap. A capacitive MEMS pressure sensor is also disclosed.

A multi-layer sealing film for high seal yield is provided. In some embodiments, a substrate comprises a vent opening extending through the substrate, from an upper side of the substrate to a lower side of the substrate. The upper side of the substrate has a first pressure, and the lower side of the substrate has a second pressure different than the first pressure. The multi-layer sealing film covers and seals the vent opening to prevent the first pressure from equalizing with the second pressure through the vent opening. Further, the multi-layer sealing film comprises a pair of metal layers and a barrier layer sandwiched between metal layers. Also provided is a microelectromechanical systems (MEMS) package comprising the multilayer sealing film, and a method for manufacturing the multi-layer sealing film.

A sensor includes a substrate, an electrode, a deformable membrane, and a compensating structure. The substrate includes a first side and a second side. The first side is opposite to the second side. The substrate comprises a cavity on the first side. The electrode is positioned at a bottom of the cavity on the first side of the substrate. The deformable membrane is positioned on the first side of the substrate. The deformable membrane encloses the cavity and deforms responsive to external stimuli. The compensation structure is connected to outer periphery of the deformable membrane. The compensation structure creates a bending force that is opposite to a bending force of the deformable membrane responsive to temperature changes and thermal coefficient mismatch.