Disclosed herein are force sensors which include a sense die assembly and methods for manufacturing the sense die assembly and the force sensor. The disclosed sense die assembly, force sensor, and methods utilize wafer-level retention to hold an actuation element in a cavity of the sense die.

A microelectromechanical system (MEMS) sensor device includes a package housing having a top member, bottom member, and a spacer coupled the top member to the bottom member, defining a cavity. At least one sensor circuit and a MEMS sensor disposed within the cavity of the package housing. A first opening formed on the package housing a control device embedded within the package housing is electrically coupled to the sensor circuit and is controlled to tune the MEMS sensor from a directional mode to an omni-directional mode.

A force sensor having a noise shielding layer is disclosed. For a first embodiment, a top noise shielding layer is configured on a top surface of a force sensor to screen noise signals which are caused by human body's touch or approaching from top of the force sensor. For a second embodiment, a bottom noise shielding layer is configured on a bottom surface of the force sensor to screen noise signals which are caused by human body's touch or approaching from bottom of the force sensor.

A MEMS chip package is provided with a removable cover to allow non-destructive testing. The MEMS package has a container (with walls and a bottom) and a cover. The cover has a glass pane, and is secured to the MEMS package with an elastomeric gasket mounted between the walls of the MEMS package and the cover. A number of attachment mechanisms secure the cover to the MEMS package.

A multi-device module, comprising: a first substrate, which houses a first MEMS transducer, designed to transduce a first environmental quantity into a first electrical signal, and an integrated circuit, coupled to the first MEMS transducer for receiving the first electrical signal; a second substrate, which houses a second MEMS transducer, designed to transduce a second environmental quantity into a second electrical signal; and a flexible printed circuit, mechanically connected to the first and second substrates and electrically coupled to the integrated circuit and to the second MEMS transducer so that the second electrical signal flows, in use, from the second MEMS transducer to the integrated circuit.

An apparatus and method wherein the method comprises: a deformable substrate; a curved support structure configured to support at least a portion of a resistive sensor wherein the resistive sensor comprises a first electrode, a second electrode and a resistive sensor material provided between the electrodes; at least one support configured to space the curved support structure from the deformable substrate so that when the deformable substrate is deformed the curved support structure is not deformed in the same way; wherein the resistive sensor is positioned on the curved support structure so as to limit deformation of the resistive sensor when the deformable substrate is deformed.

Aspects include a method of manufacturing a flexible electronic structure that includes a metal or doped silicon substrate. Aspects include depositing an adhesive layer on the top side of the structure. Aspects also include depositing a release layer and a glass layer on the top side of the structure. Aspects also include reducing a thickness of the silicon substrate on the bottom side of the structure.

A MEMS device includes a first MEMS sensor associated with a first spatial plane and a second MEMS sensor is associated with a spatial second plane not co-planar with the first spatial plane, wherein the first MEMS sensor is configured to provide a first interrupt and a first data in response to a physical perturbation, wherein the second MEMS sensor is configured to provide a second interrupt and second data in response to the physical perturbation, and a controller configured to receive the first interrupt at a first time and the second interrupt at a second time different from the first time, wherein the controller is configured to determine a latency between the first time and the second time, and wherein the controller is configured to determine motion data in response to the first data, to the second data, and to the latency.

System and method for forming an ALD assembly on a surface of a microelectromechanical system (MEMS) device comprises a substrate having a surface and the ALD assembly is at least partially disposed on the surface of the substrate, wherein the ALD assembly is at least one of hydrophobic and hydrophilic properties. The ALD layer further includes a first ALD and a second ALD. On the surface of the substrate, the first ALD is deposited in a first deposition cycle and the second ALD is deposited in a second deposition cycle. The ALD assembly further comprises a seed layer formed using atomic layer deposition and the ALD layer is at least partially disposed on the seed layer. In one example, the seed layer is formed from alumina (Al.sub.2O.sub.3) and the ALD layer is formed from platinum (Pt). In alternate embodiment, on the seed layer, the first ALD is deposited in a first deposition cycle and the second ALD is deposited in a subsequent deposition cycle. The substrate is formed from silicon dioxide (SiO.sub.2).

A method for operating an electronic device comprising a first and second MEMS device and a semiconductor substrate disposed upon a mounting substrate includes subjecting the first MEMS device and the second MEMS device to physical perturbations, wherein the physical perturbations comprise first physical perturbations associated with the first MEMS device and second physical perturbations associated with the second MEMS device, wherein the first physical perturbations and the second physical perturbations are substantially contemporaneous, determining in a plurality of CMOS circuitry formed within the one or more semiconductor substrates, first physical perturbation data from the first MEMS device in response to the first physical perturbations and second physical perturbation data from the second MEMS device in response to the second physical perturbations, determining output data in response to the first physical perturbation data and to the second physical perturbation data, and outputting the output data.