Abstract: A flow sensor assembly is provided and includes a flow conduit configured to impart a disturbance to a flow, multiple sensors disposed at respective sensing locations along the flow conduit. Each sensor is responsive to the disturbance of the flow and generates a corresponding response signal. The flow sensor assembly further includes a processor operably connected to each sensor, the processor being configured to compute a cross-correlation function between the response signals generated by said sensors, and determine a flow rate and a direction for the flow through the conduit based on the computed cross-correlation function. Additional flow sensor assembly arrangements are also disclosed.

Abstract: A catheter die is provided and includes an elongate body having first and second opposing end portions and an end face at the first one of the first and second opposing end portions. The elongate body defines a cavity within the first end portion with an interior facing surface of the cavity disposed to extend alongside at least a portion of the first end face. At least one or more piezoresistive pressure sensors are operably disposed proximate to the cavity.

Abstract: A flexible cable with a substrate divided into at least two sections is disclosed. The first section includes a first electrically conductive track and a first attach pad, while the section includes a second and third electrically conductive tracks, as well as a second attach pad. The first section is disposed on the second section to align the attach pads and connect the first electrically conductive track to the third electrically conductive track. The resulting flexible cable can be used with a low profile electrical device.

Abstract: A catheter die is provided and includes a device layer defining a cavity and including a piezoresistive pressure sensor operably disposed proximate to the cavity and an insulator having an opening and being disposed on an upper surface of the device layer such that a portion of the piezoresistive pressure sensor is exposed through the opening. The catheter die further includes an insulation layer bonded to a lower surface of the device layer and first and second bond pads, the first bond pad being electrically coupled to the portion of the piezoresistive pressure sensor via the opening and the second bond pad being disposed on the insulation layer.

Abstract: A method of attaching a die to a carrier using a temporary attach material is disclosed. The method comprises attaching the temporary attach material between a surface of the die and a surface of the carrier. The temporary attach material attaches the die to the carrier. The method comprises bonding at least one connector to the die and the carrier. The connector includes a first end bonded to the carrier and a second end bonded to the die. The method further comprises encapsulating at least a portion of the die and at least a portion of the at least one connector by an encapsulation material.

Abstract: A gas sensor is disclosed. The gas sensor includes a gas sensing layer, at least one electrode, an adhesion layer, and a response modification layer adjacent to said gas sensing layer and said layer of adhesion. A system having an exhaust system and a gas sensor is also disclosed. A method of fabricating the gas sensor is also disclosed.

Abstract: An antenna and method of making the same is disclosed wherein the antenna includes a seal assembly comprising a seal plate to prevent material used to form a seal around the conductor element from entering into the air gap of the antenna body.

Abstract: A catheter die is provided and includes a device layer defining a cavity and including a piezoresistive pressure sensor operably disposed proximate to the cavity and an insulator having an opening and being disposed on an upper surface of the device layer such that a portion of the piezoresistive pressure sensor is exposed through the opening. The catheter die further includes an insulation layer bonded to a lower surface of the device layer and first and second bond pads, the first bond pad being electrically coupled to the portion of the piezoresistive pressure sensor via the opening and the second bond pad being disposed on the insulation layer.

Abstract: A heater includes at least one heating element having a resistance that varies non-linearly with respect to a temperature of the heating element. The heating element includes a first surface, a second surface opposite the first surface, a third surface extending between the first and second surfaces, and a fourth surface extending between the first and second surfaces, opposite the third surface. The heating element has a height defined between the first and second surfaces, and a width defined between the third and fourth surfaces, and wherein the width is less than the height. The heater also includes at least one electrode coupled to the first surface and configured to generate an electric field across the heating element and cause a current to flow through the heating element.