Abstract: Methods and structures that may be implemented in one example to co-integrate processes for thin-film encapsulation and formation of microelectronic devices and microelectromechanical systems (MEMS) such as sensors and actuators. For example, structures having varying characteristics may be fabricated using the same basic process flow by selecting among different process options or modules for use with the basic process flow in order to create the desired structure/s. Various process flow sequences as well as a variety of device design structures may be advantageously enabled by the various disclosed process flow sequences.

Abstract: Membrane transducer structures and thin-film encapsulation methods for manufacturing the same are provided. In one example, the thin film encapsulation methods may be implemented to co-integrate processes for thin-film encapsulation and formation of microelectronic devices and microelectromechanical systems (MEMS) that include the membrane transducers.

Abstract: Trapped sacrificial structures and thin-film encapsulation methods that may be implemented to manufacture trapped sacrificial structures such as relative humidity sensor structures, and spacer structures that protect adjacent semiconductor structures extending above a semiconductor die substrate from being contacted by a molding tool or other semiconductor processing tool in an area of a die substrate adjacent the spacer structures.

Abstract: Membrane transducer structures and thin-film encapsulation methods for manufacturing the same are provided. In one example, the thin film encapsulation methods may be implemented to co-integrate processes for thin-film encapsulation and formation of microelectronic devices and microelectromechanical systems (MEMS) that include the membrane transducers.

Abstract: Membrane transducer structures and thin-film encapsulation methods for manufacturing the same are provided. In one example, the thin film encapsulation methods may be implemented to co-integrate processes for thin-film encapsulation and formation of microelectronic devices and microelectromechanical systems (MEMS) that include the membrane transducers.

Abstract: A microelectromechanical system (MEMS) device includes a temperature compensating structure including a first beam suspended from a substrate and a second beam suspended from the substrate. The first beam is formed from a first material having a first Young's modulus temperature coefficient. The second beam is formed from a second material having a second Young's modulus temperature coefficient. The body may include a routing spring suspended from the substrate. The routing spring may be coupled to the first beam and the second beam. The routing spring may be formed from the second material. The first beam and the second beam may have lower spring compliance than the routing spring. The MEMS device may be a resonator and the temperature compensating structure may have dimensions and a location such that the temperature compensation structure modifies a temperature coefficient of frequency of the resonator independent of a mode shape of the resonator.

Abstract: Methods and structures that may be implemented in one example to co-integrate processes for thin-film encapsulation and formation of microelectronic devices and microelectromechanical systems (MEMS) such as sensors and actuators. For example, structures having varying characteristics may be fabricated using the same basic process flow by selecting among different process options or modules for use with the basic process flow in order to create the desired structure/s. Various process flow sequences as well as a variety of device design structures may be advantageously enabled by the various disclosed process flow sequences.

Abstract: Trapped sacrificial structures and thin-film encapsulation methods that may be implemented to manufacture trapped sacrificial structures such as relative humidity sensor structures, and spacer structures that protect adjacent semiconductor structures extending above a semiconductor die substrate from being contacted by a molding tool or other semiconductor processing tool in an area of a die substrate adjacent the spacer structures.

Abstract: Methods and structures that may be implemented in one example to co-integrate processes for thin-film encapsulation and formation of microelectronic devices and microelectromechanical systems (MEMS) such as sensors and actuators. For example, structures having varying characteristics may be fabricated using the same basic process flow by selecting among different process options or modules for use with the basic process flow in order to create the desired structure/s. Various process flow sequences as well as a variety of device design structures may be advantageously enabled by the various disclosed process flow sequences.

Abstract: Methods of forming MEMS resonators containing a first structural material and a second structural material to tailor the resonator's temperature coefficient of frequency (TCF). The first structural material has a different Young's modulus temperature coefficient than the second structural material. In one embodiment, the first structural material may be formed on substrate and patterned, and the second structural material may be formed over the first structural material and planarized to expose the first structural material. A resonator may be patterned that contains both the first and second structural materials.

Abstract: Trapped sacrificial structures and thin-film encapsulation methods that may be implemented to manufacture trapped sacrificial structures such as relative humidity sensor structures, and spacer structures that protect adjacent semiconductor structures extending above a semiconductor die substrate from being contacted by a molding tool or other semiconductor processing tool in an area of a die substrate adjacent the spacer structures.

Abstract: A technique decouples a MEMS device from sources of strain by forming a MEMS structure with suspended electrodes that are mechanically anchored in a manner that reduces or eliminates transfer of strain from the substrate into the structure, or transfers strain to electrodes and body so that a transducer is strain-tolerant. The technique includes using an electrically insulating material embedded in a conductive structural material for mechanical coupling and electrical isolation.

Abstract: An apparatus is formed on a substrate including at least one semiconductor device. The apparatus includes a microelectromechanical system (MEMS) device comprising at least one of a portion of a first structural layer and a portion of a second structural layer formed above the first structural layer. The second structural layer has a thickness substantially greater than a thickness of the first structural layer. In at least one embodiment, the MEMS device includes a first portion of the second structural layer and a second portion of the second structural layer. In at least one embodiment, the MEMS device further comprises a gap between the first portion of the second structural layer and the second portion of the second structural layer. In at least one embodiment, the gap has a width at least one order of magnitude less than the thickness of the second structural layer.

Abstract: Membrane transducer structures and thin-film encapsulation methods for manufacturing the same are provided. In one example, the thin film encapsulation methods may be implemented to co-integrate processes for thin-film encapsulation and formation of microelectronic devices and microelectromechanical systems (MEMS) that include the membrane transducers.

Abstract: Trapped sacrificial structures and thin-film encapsulation methods that may be implemented to manufacture trapped sacrificial structures such as relative humidity sensor structures, and spacer structures that protect adjacent semiconductor structures extending above a semiconductor die substrate from being contacted by a molding tool or other semiconductor processing tool in an area of a die substrate adjacent the spacer structures.

Abstract: Methods and structures that may be implemented in one example to co-integrate processes for thin-film encapsulation and formation of microelectronic devices and microelectromechanical systems (MEMS) such as sensors and actuators. For example, structures having varying characteristics may be fabricated using the same basic process flow by selecting among different process options or modules for use with the basic process flow in order to create the desired structure/s. Various process flow sequences as well as a variety of device design structures may be advantageously enabled by the various disclosed process flow sequences.

Abstract: A technique decouples a MEMS device from sources of strain by forming a MEMS structure with suspended electrodes that are mechanically anchored in a manner that reduces or eliminates transfer of strain from the substrate into the structure, or transfers strain to electrodes and body so that a transducer is strain-tolerant. The technique includes using an electrically insulating material embedded in a conductive structural material for mechanical coupling and electrical isolation. An apparatus includes a MEMS device including a first electrode and a second electrode, and a body suspended from a substrate of the MEMS device. The body and the first electrode form a first electrostatic transducer. The body and the second electrode form a second electrostatic transducer. The apparatus includes a suspended passive element mechanically coupled to the body and electrically isolated from the body.

Abstract: MEMS resonators containing a first material and a second material to tailor the resonator's temperature coefficient of frequency (TCF). The first material has a different Young's modulus temperature coefficient than the second material. In one embodiment, the first material has a negative Young's modulus temperature coefficient and the second material has a positive Young's modulus temperature coefficient. In one such embodiment, the first material is a semiconductor and the second material is a dielectric. In a further embodiment, the quantity and location of the second material in the resonator is tailored to meet the resonator TCF specifications for a particular application. In an embodiment, the second material is isolated to a region of the resonator proximate to a point of maximum stress within the resonator. In a particular embodiment, the resonator includes a first material with a trench containing the second material.

Abstract: A technique for forming an encapsulated microelectromechanical system (MEMS) device includes forming an integrated circuit using a substrate, forming a barrier using the substrate, and forming a MEMS device using the substrate. The method includes encapsulating the MEMS device in a cavity. The barrier is disposed between the integrated circuit and the cavity and inhibits the integrated circuit from outgassing into the cavity. The barrier may be substantially impermeable to gas migration from the integrated circuit.

Abstract: A method of operating a system including a MEMS device of an integrated circuit die includes generating an indicator of a device parameter of the MEMS device in a first mode of operating the system using a monitor structure formed using a MEMS structural layer of the integrated circuit die. The method includes generating, using a CMOS device of the integrated circuit die, a signal indicative of the device parameter and based on the indicator. The device parameter may be a geometric dimension of the MEMS device. The method may include, in a second mode of operating the system, compensating for a difference between a value of the signal and a target value of the signal. The method may include re-generating the indicator after exposing the MEMS device to stress and generating a second signal indicating a change in the device parameter.