A method for manufacturing a MEMS device is disclosed. Moreover a MEMS device and a module including a MEMS device are disclosed. An embodiment includes a method for manufacturing MEMS devices includes forming a MEMS stack over a first main surface of a substrate, forming a polymer layer over a second main surface of the substrate and forming a first opening in the polymer layer and the substrate such that the first opening abuts the MEMS stack.

In described examples, a first device on a first surface of a substrate is coupled to a structure arranged on a second surface of the substrate. In at least one example, a first conductor arranged on the first surface is coupled to circuitry of the first device. An elevated portion of the first conductor is supported by disposing an encapsulate and curing the encapsulate. The first conductor is severed by cutting the encapsulate and the first conductor. A second conductor is coupled to the first conductor. The second conductor is coupled to the structure arranged on the second surface of the substrate.

A method for manufacturing a MEMS device is disclosed. Moreover a MEMS device and a module including a MEMS device are disclosed. An embodiment includes a method for manufacturing MEMS devices includes forming a MEMS stack over a first main surface of a substrate, forming a polymer layer over a second main surface of the substrate and forming a first opening in the polymer layer and the substrate such that the first opening abuts the MEMS stack.

The disclosure describes various MEMS microphone modules that have a small footprint and can be integrated, for example, into consumer electronic or other devices in which space is at premium. Wafer-level fabrication techniques for making the modules also are described.

The present disclosure relates to a method for fabricating a micro-electromechanical system (MEMS) device. In the method, a carrier wafer is received. A MEMS wafer, which includes a plurality of die, is bonded to the carrier wafer. A cavity is formed to separate an upper surface of the carrier wafer from a lower surface of a die of the MEMS wafer. A separation trench is formed to laterally surround the die, wherein formation of the cavity and the separation trench leaves a tethering structure suspending the die over the upper surface of the carrier wafer. The die and carrier wafer are translated with respect to one another to break the tethering structure and separate the die from the carrier wafer.

A package includes a support structure having an electrically insulating material, a microelectromechanical system (MEMS) component, a cover structure having an electrically insulating material and mounted on the support structure for at least partially covering the MEMS component, and an electronic component embedded in one of the support structure and the cover structure. At least one of the support structure and the cover structure has or provides an electrically conductive contact structure.

The disclosure describes various MEMS microphone modules that have a small footprint and can be integrated, for example, into consumer electronic or other devices in which space is at premium. Wafer-level fabrication techniques for making the modules also are described.

A method for manufacturing a MEMS device is disclosed. Moreover a MEMS device and a module including a MEMS device are disclosed. An embodiment includes a method for manufacturing MEMS devices includes forming a MEMS stack over a first main surface of a substrate, forming a polymer layer over a second main surface of the substrate and forming a first opening in the polymer layer and the substrate such that the first opening abuts the MEMS stack.

In described examples, a first device on a first surface of a substrate is coupled to a structure arranged on a second surface of the substrate. In at least one example, a first conductor arranged on the first surface is coupled to circuitry of the first device. An elevated portion of the first conductor is supported by disposing an encapsulate and curing the encapsulate. The first conductor is severed by cutting the encapsulate and the first conductor. A second conductor is coupled to the first conductor. The second conductor is coupled to the structure arranged on the second surface of the substrate.

A method for manufacturing a MEMS device is disclosed. Moreover a MEMS device and a module including a MEMS device are disclosed. An embodiment includes a method for manufacturing MEMS devices includes forming a MEMS stack on a first main surface of a substrate, forming a polymer layer on a second main surface of the substrate and forming a first opening in the polymer layer and the substrate such that the first opening abuts the MEMS stack.