A MEMS microphone includes a substrate having a cavity, a diaphragm disposed above the substrate to correspond to the cavity, and a back plate disposed above the diaphragm. The diaphragm has a plurality of grooves for adjusting an elastic strength of the diaphragm.

An electroacoustic transducer includes a framework, a voice membrane, a voice coil, a flexible circuit board, an auxiliary diaphragm, and a first gasket. An edge of the voice membrane is fastened to a top surface of the framework. The voice coil is located on an inner side of the framework, and one end of the voice coil is fastened to the voice membrane. A first fastening part of the flexible circuit board is fastened to a bottom surface of the framework, and a second fastening part of the flexible circuit board is fastened to the voice coil. The auxiliary diaphragm is located on one side of the flexible circuit board. The first gasket is located between the first fastening part of the flexible circuit board and the first fastening part of the auxiliary diaphragm.

An electroacoustic transducer includes a framework, a voice membrane, a voice coil, a flexible circuit board, an auxiliary diaphragm, and a first gasket. An edge of the voice membrane is fastened to a top surface of the framework. The voice coil is located on an inner side of the framework, and one end of the voice coil is fastened to the voice membrane. A first fastening part of the flexible circuit board is fastened to a bottom surface of the framework, and a second fastening part of the flexible circuit board is fastened to the voice coil. The auxiliary diaphragm is located on one side of the flexible circuit board. The first gasket is located between the first fastening part of the flexible circuit board and the first fastening part of the auxiliary diaphragm.

The present invention provides a MEMS microphone, including a substrate and a capacitive structure. The capacitive structure includes a back plate and a vibration diaphragm. The vibration diaphragm includes a main body and a plurality of supporting structures for supporting the main body. Each supporting structure includes a supporting beam and two spring structures. Each spring structure includes at least two beam arms extending along the extension direction of the peripheral edge of the main body, and the beam arm closest to the main body is spaced apart from the main body. The sensitivity of the MEMS microphone in the present invention is higher.

The present invention provides a MEMS microphone, including a substrate and a capacitive structure. The capacitive structure includes a back plate and a vibration diaphragm. The vibration diaphragm includes a main body and a plurality of supporting structures for supporting the main body. Each supporting structure includes a supporting beam and two spring structures. Each spring structure includes at least two beam arms extending along the extension direction of the peripheral edge of the main body, and the beam arm closest to the main body is spaced apart from the main body. The sensitivity of the MEMS microphone in the present invention is higher.

An electromagnetic transducer includes a yoke, a first magnet, a second magnet, and a spacer. The yoke is disposed along a vertical axis. The first magnet is magnetically coupled to the yoke and has a polarization in a first orientation with respect to the vertical axis. The second magnet is magnetically coupled to the yoke and has a polarization in the first orientation with respect to the vertical axis. The spacer is disposed between the first magnet and the second magnet and is extended along the vertical axis.

An electromagnetic transducer includes a yoke, a first magnet, a second magnet, and a spacer. The yoke is disposed along a vertical axis. The first magnet is magnetically coupled to the yoke and has a polarization in a first orientation with respect to the vertical axis. The second magnet is magnetically coupled to the yoke and has a polarization in the first orientation with respect to the vertical axis. The spacer is disposed between the first magnet and the second magnet and is extended along the vertical axis.

A voice-controlled electronic device that includes a device housing having a longitudinal axis bisecting opposing top and bottom surfaces and a side surface extending between the top and bottom surfaces. The device can further include one or more microphones disposed within the device housing and distributed radially around the longitudinal axis; a processor configured to execute computer instructions stored in a computer-readable memory for interacting with a user and processing voice commands received by the one or more microphones and first transducer and second transducers configured to generate sound waves within different frequency ranges.

A voice-controlled electronic device that includes a device housing having a longitudinal axis bisecting opposing top and bottom surfaces and a side surface extending between the top and bottom surfaces. The device can further include one or more microphones disposed within the device housing and distributed radially around the longitudinal axis; a processor configured to execute computer instructions stored in a computer-readable memory for interacting with a user and processing voice commands received by the one or more microphones and first transducer and second transducers configured to generate sound waves within different frequency ranges.

A MEMS vibration sensor includes a piezoelectric membrane including a segmented electrode affixed to a holder; and an inertial mass affixed to the piezoelectric membrane, wherein the segmented electrode includes four segmentation zones, wherein, in an X-direction, a signal from a first segmentation zone is equal to a signal from a third segmentation zone, a signal from a second segmentation zone is equal to a signal from a fourth segmentation zone, and the signal from the first segmentation zone and the signal from the second segmentation zone have opposite signs, and wherein, in a Y-direction, a signal from the first segmentation zone is equal to the signal from the second segmentation zone, the signal from the third segmentation zone is equal to the signal from the fourth segmentation zone, and the signal from first segmentation zone and the signal from the third segmentation zone have opposite signs.