Abstract: The present disclosure relates to sensors including pressure sensors. In some cases, the pressure sensor may include a membrane or diaphragm, multiple sense elements connected to one another in a bridge configuration and positioned on the membrane, and an amplifier coupled to an output of the bridge configuration and having an output, where the diaphragm, sense elements and amplifier may be formed on a singled substrate or formed integrally therewith, or both. In one example, the pressure sensor may sense a particular range of pressures applied to the sensor, and/or may include an amplifier that has a selectable gain for amplifying an output of the bridge.

Abstract: Method and system for a wet/wet differential pressure sensor based on microelectronic packaging process. A top cap with a hole can be attached to a topside of a MEMS-configured pressure sense die with a pressure sensing diaphragm in order to allow sensed media to come in contact with the topside of the pressure sensing diaphragm. An optional constraint with a hole for stress relief can be attached to a backside of the pressure sense die. Adhesive and/or elastomeric seals and/or solder can be utilized to seal the pressure sense die allowing sensed media to come in contact with both sides of the pressure sensing diaphragm without coming into contact with wirebonds and other metallized surfaces. The MEMS-configured pressure sense die can also be bonded to a substrate with standard die attach materials. Such microelectronic packaging processes yield a high performance and cost effective solution thereby providing wet-wet pressure sensing capability.

Abstract: The present disclosure relates to sensors including pressure sensors. In some cases, the pressure sensor may include a membrane or diaphragm, multiple sense elements connected to one another in a bridge configuration and positioned on the membrane, and an amplifier coupled to an output of the bridge configuration and having an output, where the diaphragm, sense elements and amplifier may be formed on a singled substrate or formed integrally therewith, or both. In one example, the pressure sensor may sense a particular range of pressures applied to the sensor, and/or may include an amplifier that has a selectable gain for amplifying an output of the bridge.

Abstract: Method and system for a wet/wet differential pressure sensor based on microelectronic packaging process. A top cap with a hole can be attached to a topside of a MEMS-configured pressure sense die with a pressure sensing diaphragm in order to allow sensed media to come in contact with the topside of the pressure sensing diaphragm. An optional constraint with a hole for stress relief can be attached to a backside of the pressure sense die. Adhesive and/or elastomeric seals and/or solder can be utilized to seal the pressure sense die allowing sensed media to come in contact with both sides of the pressure sensing diaphragm without coming into contact with wirebonds and other metallized surfaces. The MEMS-configured pressure sense die can also be bonded to a substrate with standard die attach materials. Such microelectronic packaging processes yield a high performance and cost effective solution thereby providing wet-wet pressure sensing capability.

Abstract: A disposable pressure sensor system includes a disposable sensor assembly having at least one sensing element, carried on a housing or frame, and at least one electrical connector and/or mechanical connector for connecting the sensing element(s) to an external apparatus or device. The mechanical and/or electrical connectors are integrated in the housing or frame so that both the connector(s) and sensing element(s) are packaged in a single part. The assembly can be integrated in or attachable to a fluid carrying module, such as a dialysis cartridge, such that the sensing element(s) can sense the fluid in the module.

Abstract: A pressure sensor system includes a pressure sensing capacitor and an inductor integrated in a substrate. The pressure sensing capacitor includes a conductive diaphragm for detecting a pressure differential and an electrode separated from the diaphragm by a predetermined gap formed in the substrate. The inductor and pressure sensing capacitor form a passive inductive-capacitive (LC) tank circuit. A remote interrogation circuit, inductively coupled to the pressure sensor inductor coil, can be utilized to detect changes in resonant frequency of the LC tank wirelessly. The fully integrated pressure sensor structure is manufactured utilizing layer-by-layer fabrication techniques.

Abstract: A pressure sensor is constructed of a plastic package. The plastic package incorporates in the same material a sensing diaphragm including tensile and compression regions. Deposited on the diaphragm are metal electrodes and a polymer film having piezoresistive properties. The electrodes and/or the polymer film are directly printed onto the plastic package without the use of a mask.

Abstract: A sensor system for dialysis applications includes a plurality of pressure sensors, wherein each pressure sensor can be provided as an LC type sensor, and/or an RLC type sensor. Each sensor among the plurality of pressure sensors can be inductively coupled with a respective antenna among a plurality of antennas for the wireless transmission of pressure data. A dialysis machine is generally connected to the plurality of antennas, wherein the plurality of pressure sensors monitors pressure during operation of the dialysis machine to generate pressure data that is wirelessly transmitted to at least one antenna among the plurality of antennas.