Abstract: Embodiments included herein are directed towards sensing devices and related methods. Embodiments may include a first gauge positioned on a port of the sensing device. A first resistor of the first gauge may be positioned in a first compression region of the port. A second resistor of the first gauge may also be positioned in the first compression region of the port.

Abstract: Apparatuses that include a junction-isolated semiconductor strain gauge and methods for manufacturing a junction-isolated semiconductor strain gauge are disclosed. In a particular embodiment, an apparatus comprises a silicon chip that includes a silicon substrate and a semiconductor strain gauge. In this embodiment, the semiconductor strain gauge includes a plurality of resistors formed by locally doping the silicon substrate and biasing the silicon substrate such that the resistors of the plurality of resistors are junction-isolated. The silicon chip also includes a field shield layer to isolate an output signal of the semiconductor strain gauge from external electrical fields.

Abstract: A force sensor, flexible sensing element, and method for the force sensor are disclosed. The force sensor uses a flexible sense element with two flexible arms dedicated to measuring strain related to a pitch force and two flexible arms dedicated to measuring strain related to roll force. The use of two channels for each measurement provides a command lane and a monitor lane for strain measurements. Strain gauges are disposed on both the top and the bottom surfaces of each arm, thus providing two completely redundant systems. When a failure is detected in one of the systems, the redundant system can be implemented.

Abstract: A pressure sensor apparatus for strain gauge pressure sensing includes a plurality of strain gauges including a first strain gauge and a second strain gauge. The pressure sensor apparatus also includes a diaphragm coupled between the plurality of strain gauges and an object configured to apply pressure to the diaphragm. The diaphragm has a first portion and a second portion. The first portion has a first thickness between the object and the first strain gauge. The second portion has a second thickness between the object and the second strain gauge. In an uncompressed state, the second thickness is greater than the first thickness.

Abstract: A force sensor, flexible sensing element, and method for the force sensor are disclosed. The force sensor uses a flexible sense element with two flexible arms dedicated to measuring strain related to a pitch force and two flexible arms dedicated to measuring strain related to roll force. The use of two channels for each measurement provides a command lane and a monitor lane for strain measurements. Strain gauges are disposed on both the top and the bottom surfaces of each arm, thus providing two completely redundant systems. When a failure is detected in one of the systems, the redundant system can be implemented.

Abstract: In a particular embodiment, a pressure sensor apparatus for strain gauge pressure sensing is disclosed that includes a plurality of strain gauges comprising a first strain gauge and a second strain gauge. The pressure sensor apparatus also includes a diaphragm coupled between the plurality of strain gauges and an object configured to apply pressure to the diaphragm. The diaphragm has a first portion and a second portion. The first portion has a first thickness between the object and the first strain gauge. The second portion has a second thickness between the object and the second strain gauge. In an uncompressed state, the second thickness is greater than the first thickness.

Abstract: An apparatus senses a pressure of a fluid from a fluid medium. The apparatus has a port body with a peripheral wall surrounding an interior channel. The interior channel extends between a diaphragm on the port body and an opening for receiving the fluid. A strain gauge is disposed on the port body. The strain gauge has two or more resistors connected between input/output pads and ground pads. The resistors are spaced substantially equidistant from the ground pad to reduce mobile ion migration.

Abstract: An apparatus senses a pressure of a fluid from a fluid medium. The apparatus has a port body with a peripheral wall surrounding an interior channel. The interior channel extends between a diaphragm on the port body and an opening for receiving the fluid. A strain gauge is disposed on the port body. The strain gauge has two or more resistors connected between input/output pads and ground pads. The resistors are spaced substantially equidistant from the ground pad to reduce mobile ion migration.

Abstract: Methods and apparatus for a semiconductor strain gauge pressure sensor. An apparatus includes a sense element configured to be exposed to a pressure environment, the sense element including at least one highly doped semiconductor strain gauge, the highly doped semiconductor strain gauge including a five pad single full Wheatstone bridge, an electronics package disposed on a carrier and electrically coupled to the sense element, the carrier disposed on a port that comprises the sense element, a housing disposed about the sense element and electronics package, and a connector joined to the housing and electrically connected to the electronics package, the connector including an external interface.

Abstract: Methods and apparatus for a semiconductor strain gauge pressure sensor. An apparatus includes a sense element configured to be exposed to a pressure environment, the sense element including at least one highly doped semiconductor strain gauge, the highly doped semiconductor strain gauge including a five pad single full Wheatstone bridge, an electronics package disposed on a carrier and electrically coupled to the sense element, the carrier disposed on a port that comprises the sense element, a housing disposed about the sense element and electronics package, and a connector joined to the housing and electrically connected to the electronics package, the connector including an external interface.