A sensor device includes a printed circuit board (PCB) substrate having a top surface, a bottom surface, a slot between the top and bottom surfaces, and two holes through the top surface and reaching into the slot. The sensor device further includes a sensor chip mounted on the top surface of the PCB substrate and above one of the two holes. The sensor device further includes a molding compound covering the sensor chip and sidewall surfaces and the top surface of the PCB substrate.

A pressure sensor package includes a package lead frame including a molding plastic layer with a top surface and a plurality of lead frame units mounted in the molding plastic layer, a sidewall disposed on the top surface of the molding plastic layer and surrounding a receiving chamber, a pressure sensor module mounted on the top surface of the molding plastic layer and disposed in the receiving chamber, and a packaging silicone mounted in the receiving chamber to encapsulate the pressure sensor module.

Disclosed are pressure sensors including a die and an application-specific integrated circuit (ASIC) mounted on a top surface of a substrate. The pressure sensor can define an inner volume and a bottom opening configured to abut the substrate. The die and ASIC are mounted on the top surface of the substrate within the inner volume. The substrate defines a first aperture therethrough and the die defines a second aperture therethrough in a direction along an axis perpendicular to the substrate, the first aperture and the second aperture being aligned. Metallic barrier(s) disposed on a bottom surface of the substrate, circumferentially about the first aperture, can be at least partially coated with solder mask to reduce or prevent flow of unwanted materials past the metallic barriers and through the first aperture. The substrate can include electrical connection pads on the bottom surface configured to be in communication with a daughter board.

A pressure sensor includes a MEMS pressure transducer with a pressure sensing diaphragm and sensor elements, an isolator diaphragm spaced apart from the pressure sensing diaphragm, and a ceramic header body. The ceramic header body has an electrical conductor and transducer aperture with the MEMS pressure transducer supported therein. The isolator diaphragm is coupled to the to the MEMS pressure transducer by a fluid and is sealably fixed to the ceramic body. The ceramic header body bounds the fluid and the electrical conductor electrically connects the MEMS pressure transducer with the external environment. Differential pressure sensors and methods of making pressure sensors are also described.

A method for producing a micromechanical pressure sensor. The method includes: providing a MEMS wafer having a silicon substrate and a first cavity developed therein underneath a sensor diaphragm; providing a second wafer; bonding the MEMS wafer to the second wafer; and exposing a sensor core from the rear side; a second cavity being formed in the process between the sensor core and the surface of the silicon substrate, and the second cavity being developed with the aid of an etching process which is carried out using etching parameters that are modified in a defined manner.

A method of monitoring microelectromechanical system (MEMS) pressure sensors arranged on a carrier includes: generating a first measurement value by a first MEMS pressure sensor arranged on the carrier; generating a second measurement value by a second MEMS pressure sensor arranged on the carrier; and determining, by an integrated circuit, whether the first measurement value of the first MEMS pressure sensor corresponds to the second measurement value of the second MEMS pressure sensor in accordance with a predefined criterion, wherein the integrated circuit is arranged on the carrier and is coupled to the first MEMS pressure sensor and the second MEMS pressure sensor.

A pressure measuring arrangement is proposed. The pressure measuring arrangement includes a first MEMS pressure sensor arranged on a carrier, and also a second MEMS pressure sensor arranged on the carrier. Furthermore, the pressure measuring arrangement includes an integrated circuit arranged on the carrier, the integrated circuit being coupled to the first MEMS pressure sensor and the second MEMS pressure sensor.

A sensor has a sensor body with a first face and a second face opposite to one another, and a circuit arrangement supported by the sensor body that includes a first electrical circuit pattern on the first face, a second electrical circuit pattern on the second face, connection means, which electrically connect the first circuit pattern to the second circuit pattern and has at least one through hole that extends axially between the two faces of the sensor body. A plurality of terminals are electrically connected to the first circuit pattern and/or the second circuit pattern. The at least one through hole is preferably closed at the second face of the sensor body via a closing member (30) having pre-formed body with a closing portion having a diameter, greater than a diameter, of the opening of the through hole at the second face of the sensor body.

A method of manufacturing a sensor device (100) comprises providing (200) a package (102) having a first die-receiving subframe volume (104) separated from a second die-receiving subframe volume (106) by a partition wall (116). An elongate sensor element (120) is disposed (202) within the package (102) so as to bridge the first and second subframe volumes (104, 106) and to overlie the partition wall (116). The elongate sensor element (120) resides substantially in the first subframe volume (104) and partially in the second subframe volume (106). The elongate sensor element (120) is electrically connected within the second subframe volume (106).

A pressure sensor includes a MEMS pressure transducer with a pressure sensing diaphragm and sensor elements, an isolator diaphragm spaced apart from the pressure sensing diaphragm, and a ceramic header body. The ceramic header body has an electrical conductor and transducer aperture with the MEMS pressure transducer supported therein. The isolator diaphragm is coupled to the to the MEMS pressure transducer by a fluid and is sealably fixed to the ceramic body. The ceramic header body bounds the fluid and the electrical conductor electrically connects the MEMS pressure transducer with the external environment. Differential pressure sensors and methods of making pressure sensors are also described.