A pressure sensor which detects variation in pressure, the pressure sensor including a cantilever which bends according to a pressure difference between the inside and the outside of a cavity in a sensor main body, and a first gap, a second gap, and a third gap which are formed on a proximal end portion of the cantilever. The first to third gaps electrically partition the proximal end portion of the cantilever into a first support portion, a second support portion, a first displacement detection portion, and a second displacement portion in a second direction orthogonal to a first direction in which the proximal end portion and a distal end portion of the cantilever are connected to each other in plan view. The first and second displacement detection portions detect displacement according to the bending of the cantilever between the first and second support portion.

A pressure sensor includes a sensor main body having a cavity, a cantilever having a lever main body and lever support-portion, which is bent according to a pressure difference between the cavity and sensor outside main body, and a displacement detection unit detects cantilever displacement based on resistance variation in resistance values of the main body-resistance portion formed in the lever main body and lever-resistance portion formed in the lever support-portion. A division groove is formed in the lever support; the division divides the lever-resistance portion into a first resistance portion electrically connected to a detection-electrode in series and second resistance portion closer to other adjacent lever support-portion than the first resistance portion. The first resistance portion of the lever support-portion electrically connected to the detection-electrode via a parallel path of a first path passing through the main body-resistance portion and second path passing through the second resistance portion.

Based on respective signals from the combustion pressure sensor and a crank angle sensor, heat generation amount data in which a heat generation amount and a crank angle are related to each other is generated, and an estimated heat generation amount is calculated based on a fuel amount in the combustion cycle. When a final value of a heat generation amount in the combustion cycle is smaller than the estimated heat generation amount, the combustion state parameter is calculated based on the heat generation amount data to a crank angle corresponding to the final value of the heat generation amount. When the final value of the heat generation amount is equal to or larger than the estimated heat generation amount, the combustion state parameter is calculated based on the heat generation amount data to a crank angle at which the heat generation amount reaches the estimated heat generation amount.

A method of determining fluid pressure inside a conduit. The method includes positioning a conduit in a surgical system. The conduit having an external surface, and the surgical system having a pair of sensors. The conduit is positioned in the surgical system such that the external surface of the conduit applies a force on the pair of sensors when the conduit expands. The method includes a step of generating one or more electrical signals with the pair of sensors. The one or more electrical signals corresponding to the force on the pair of sensors. The method includes a step of determining the fluid pressure inside the conduit by converting the one or more electrical signals into a fluid pressure value through a controller.

A smart container comprises a container body and a base. The container body comprises a sensing circuit, and the sensing circuit is configured to detect a pressure changing value and a temperature changing value both corresponding to a touch operation performed on the opening of the container body. The base disposed underneath the container body, wherein the base comprises a measuring circuit and a processing unit. The measuring circuit configured to measure a weight of contents accommodated in the container body. And the processing unit is configured to determine whether or not the touch operation is performed, configured to calculate a weight changing value according to the weight, and configured to determine a drinking capacity of a user and whether or not the user has drank the contents.

A high-sensitivity sensor containing cracks is provided. The high-sensitivity sensor is obtained by forming microcracks on a conductive thin film, which is formed on top of a support, wherein the microcracks form a micro joining structure in which the microcracks are electrically changed, short-circuited or open, thereby converting external stimuli into electric signals by generating a change in a resistance value. The high-sensitivity sensor can be useful in a displacement sensor, a pressure sensor, a vibration sensor, artificial skin, a voice recognition system, and the like.

A thermal conductivity gauge measures gas pressure within a chamber. A sensor wire and a resistor form a circuit coupled between a power input and ground, where the sensor wire extends into the chamber and connects to the resistor via a terminal. A controller adjusts the power input, as a function of a voltage at the terminal and a voltage at the power input, to bring the sensor wire to a target temperature. Based on the adjusted power input, the controller can determine a measure of the gas pressure within the chamber.

A pressure sensor includes a housing that includes an interior surface and an axially symmetric liner disposed along the interior surface of the housing, where the liner includes an interior surface and an exterior surface. The pressure sensor further includes a sensing member that includes an interior surface and an exterior surface, where the interior surface of the sensing member is adjacent to the exterior surface of the liner, and the sensing member is configured to expand with the liner. The pressure sensor further includes a strain gauge affixed to the exterior surface of the sensing member.

Integrated pipe pressure and temperature sensors and related methods are disclosed herein. An example apparatus includes a housing including an opening to provide a fluid flow path. The fluid flow path is to be coaxially aligned with a fluid flow path of a pipe when the housing is coupled to the pipe. The example apparatus includes a sensor disposed in the housing. The sensor includes an electrically conductive deformable material.

Integrated pipe pressure and temperature sensors and related methods are disclosed herein. An example apparatus includes a housing including an opening to provide a fluid flow path. The fluid flow path is to be coaxially aligned with a fluid flow path of a pipe when the housing is coupled to the pipe. The example apparatus includes a sensor disposed in the housing. The sensor includes an electrically conductive deformable material.