The present disclosure discloses a MEMS microphone including a printed circuit board, a shell assembled with the printed circuit board for forming a receiving space and provided with a sound hole communicating with the receiving space, a MEMS Die with a cavity accommodated in the receiving space and mounted on the shell for covering the sound hole, and an ASIC chip accommodated in the receiving space and mounted on the shell through a substrate. The cavity of the MEMS Die communicates with the sound hole. The MEMS Die electrically connects with the ASIC chip. The ASIC chip electrically connects with the substrate. The substrate electrically connects with the printed circuit board.

A microphone assembly including an acoustic transducer configured to generate an electrical signal responsive to acoustic activity, an integrated circuit electrically coupled to the acoustic transducer and configured to receive the electrical signal from the acoustic transducer and generate an output signal representative of the acoustic activity, a cover, and a substrate. The substrate including a first surface and a second surface to which the cover is coupled. The second surface is disposed at a perimeter of the substrate and the first surface is raised with respect to the second surface. The cover is coupled to the substrate to form a housing in which the transducer and the integrated circuit are disposed.

A microphone assembly including an acoustic transducer configured to generate an electrical signal responsive to acoustic activity, an integrated circuit electrically coupled to the acoustic transducer and configured to receive the electrical signal from the acoustic transducer and generate an output signal representative of the acoustic activity, a cover, and a substrate. The substrate including a first surface and a second surface to which the cover is coupled. The second surface is disposed at a perimeter of the substrate and the first surface is raised with respect to the second surface. The cover is coupled to the substrate to form a housing in which the transducer and the integrated circuit are disposed.

A testing system includes a testing apparatus and a crack noise monitoring device. The testing apparatus includes a testing stage and an element pickup module for pressing a semiconductor element on the testing stage. The crack noise monitoring device includes a database unit, a sound conduction set, a voiceprint generation unit and a processing unit. The database unit has a first voiceprint pattern. The sound conduction set is connected to the voiceprint generation unit and the testing apparatus for transmitting a sound wave from the semiconductor element to the voiceprint generation unit. The voiceprint generation unit receives and converts the sound wave into a second voiceprint pattern. The processing unit is electrically connected to the voiceprint generating unit and the database unit for determining whether the first voiceprint pattern is identical to the second voiceprint pattern.

A microelectromechanical system (MEMS) transducer includes a substrate and a pair of electrodes supported by the substrate. The pair of electrodes are configured as a bias electrode-sense electrode couple. A moveable electrode of the pair of electrodes is configured for vibrational movement in a first direction during excitation of the moveable electrode. The pair of electrodes are spaced apart from one another by a gap in a second direction perpendicular to the first direction. The moveable electrode includes a cantilevered end, the cantilevered end being warped to exhibit a resting deflection along the first direction.

A microelectromechanical system (MEMS) transducer includes a substrate and a pair of electrodes supported by the substrate. The pair of electrodes are configured as a bias electrode-sense electrode couple. A moveable electrode of the pair of electrodes is configured for vibrational movement in a first direction during excitation of the moveable electrode. The pair of electrodes are spaced apart from one another by a gap in a second direction perpendicular to the first direction. The moveable electrode includes a cantilevered end, the cantilevered end being warped to exhibit a resting deflection along the first direction.

A digital stethoscope includes a stethoscope housing defining a housing edge. The digital stethoscope also includes a surface region secured to the stethoscope housing at the housing edge, and a number of microphones. The digital stethoscope also includes a processing device disposed within the stethoscope housing and in communication with the microphones. The processing device receives the digital audio data from the microphones.

A digital stethoscope includes a stethoscope housing defining a housing edge. The digital stethoscope also includes a surface region secured to the stethoscope housing at the housing edge, and a number of microphones. The digital stethoscope also includes a processing device disposed within the stethoscope housing and in communication with the microphones. The processing device receives the digital audio data from the microphones.

A MEMS microphone includes a diaphragm disposed in a first direction, and an electrode structure disposed in the first direction and configured to surround the diaphragm and to be spaced apart from the diaphragm. The electrode structure includes electrodes spaced apart from each other in a second direction perpendicular to the first direction.

A MEMS microphone includes a diaphragm disposed in a first direction, and an electrode structure disposed in the first direction and configured to surround the diaphragm and to be spaced apart from the diaphragm. The electrode structure includes electrodes spaced apart from each other in a second direction perpendicular to the first direction.