The present disclosure provides a microphone, comprising a shell structure, a vibration pickup assembly, a vibration pickup assembly, wherein the vibration pickup assembly is accommodated in the shell structure and generates vibration in response to an external sound signal transmitted to the shell structure, and at least two acoustoelectric conversion elements configured to respectively receive the vibration of the vibration pickup assembly to generate an electrical signal, wherein the at least two acoustoelectric conversion elements have different frequency responses to the vibration of the vibration pickup assembly.

A transducer includes: a piezoelectric element; and a film body including a film support portion having a hollow portion, and a vibration film connected to the film support portion and displaceable in a film thickness direction, the film body having the piezoelectric element stacked over the vibration film. The piezoelectric element includes: a first stacked body having a first pair of electrodes and a first piezoelectric film sandwiched between the first pair of electrodes; and a second stacked body having a second pair of electrodes and a second piezoelectric film sandwiched between the second pair of electrodes, the second stacked body being separated from the first stacked body.

The embodiments of the present disclosure may disclose a vibration sensor, including: an acoustic transducer and a vibration assembly connected with the acoustic transducer. The vibration assembly may be configured to transmit an external vibration signal to the acoustic transducer to generate an electric signal, the vibration assembly includes one or more groups of vibration diaphragms and mass blocks, and the mass blocks may be physically connected with the vibration diaphragms. The vibration assembly may be configured to make a sensitivity degree of the vibration sensor greater than a sensitivity degree of the acoustic transducer in one or more target frequency bands.

The present disclosure may provide a microphone. The microphone may include: a shell structure and a vibration pickup portion, wherein the vibration pickup portion may generate vibration in response to vibration of the shell structure; the vibration transmission portion may be configured to transmit the vibration generated by the vibration pickup portion; and an acoustic-electric conversion component configured to receive the vibration transmitted by the vibration transmission portion to generate an electrical signal, wherein the vibration transmission portion and at least a portion of vibration pickup portion may form a vacuum cavity, and the acoustic-electric conversion component may be located in the vacuum cavity.

The present disclosure may provide a microphone. The microphone may include: a shell structure and a vibration pickup portion, wherein the vibration pickup portion may generate vibration in response to vibration of the shell structure; the vibration transmission portion may be configured to transmit the vibration generated by the vibration pickup portion; and an acoustic-electric conversion component configured to receive the vibration transmitted by the vibration transmission portion to generate an electrical signal, wherein the vibration transmission portion and at least a portion of vibration pickup portion may form a vacuum cavity, and the acoustic-electric conversion component may be located in the vacuum cavity.

This application discloses example piezoelectric acoustic sensors and methods for manufacturing the piezoelectric acoustic sensor, and belongs to the field of electronic technologies. In one example, the piezoelectric acoustic sensor includes an anchoring unit, a piezoelectric unit, a support unit, and a hollow-out mechanical part. A back cavity is formed in the anchoring unit. The piezoelectric unit is configured to convert a sound signal that enters the back cavity into an electrical signal. The support unit covers the anchoring unit and the piezoelectric unit. The hollow-out mechanical part is connected between the anchoring unit and the piezoelectric unit, and is embedded in the support unit.

This application discloses example piezoelectric acoustic sensors and methods for manufacturing the piezoelectric acoustic sensor, and belongs to the field of electronic technologies. In one example, the piezoelectric acoustic sensor includes an anchoring unit, a piezoelectric unit, a support unit, and a hollow-out mechanical part. A back cavity is formed in the anchoring unit. The piezoelectric unit is configured to convert a sound signal that enters the back cavity into an electrical signal. The support unit covers the anchoring unit and the piezoelectric unit. The hollow-out mechanical part is connected between the anchoring unit and the piezoelectric unit, and is embedded in the support unit.

A digital microphone includes at least one integrator; a state detection and parameter control component directly coupled to an output of the integrator; and a signal processing component coupled to an output of the state detection and parameter control component, wherein a parameter of the signal processing component includes a first value in a first operational mode and a second value in a second operational mode different from the first operational mode.

A piezoelectric microelectromechanical systems (MEMS) microphone is provided comprising a substrate including walls defining a cavity and at least one of the walls defining an anchor region, a piezoelectric film layer supported by the substrate at the anchor region; an electrode disposed over the piezoelectric film layer and adjacent the anchor region and including an edge adjacent the anchor region having two straight portions and a protruding portion between the two straight portions, and the wall of the cavity that defines the anchor region including an indent corresponding in shape to the protruding portion of the electrode. A method of manufacturing such a MEMS microphone is also provided.

A piezoelectric microelectromechanical systems (MEMS) microphone is provided comprising a substrate including walls defining a cavity and at least one of the walls defining an anchor region, a piezoelectric film layer supported by the substrate at the anchor region; an electrode disposed over the piezoelectric film layer and adjacent the anchor region and including an edge adjacent the anchor region having two straight portions and a protruding portion between the two straight portions, and the wall of the cavity that defines the anchor region including an indent corresponding in shape to the protruding portion of the electrode. A method of manufacturing such a MEMS microphone is also provided.