Disclosed are an earphone ear-oriented debugging method, apparatus and system, and a wireless earphone. The method comprises: confirming an in-ear state signal indicating that a first earphone and a second earphone are in an in-ear state; sending a plurality of first ear-oriented debugging waves to the second earphone according to the in-ear state signal, wherein the plurality of first ear-oriented debugging waves respectively correspond to a plurality of frequency points for wireless communication in a one-to-one correspondence; receiving a first earphone configuration instruction sent from the second earphone, wherein the first earphone configuration instruction is generated by the second earphone according to the first ear-oriented debugging waves; and configuring a configuration parameter of an antenna matching element of the first earphone according to the first earphone configuration instruction, to optimize a communication state.

An integrated optical transducer for detecting dynamic pressure changes comprises a micro-electro-mechanical system, MEMS, die having a MEMS diaphragm with a first side exposed to the dynamic pressure changes and a second side. The transducer further comprises an application specific integrated circuit, ASIC, die having an evaluation circuit configured to detect a deflection of the MEMS diaphragm, in particular of the second side of the MEMS diaphragm. The MEMS die is arranged with respect to the ASIC die such that a gap with a gap height is formed between the second side of the diaphragm and a first surface of the ASIC die and the MEMS diaphragm, the ASIC die and a suspension structure of the MEMS die delineate a back volume of the integrated optical transducer.

The present disclosure discloses an acoustic output apparatus. The acoustic output apparatus may include at least one acoustic driver, a housing structure, and at least two sound guide holes. The at least one acoustic driver may output sounds having opposite phases from the at least two sound guide holes. The housing structure may be configured to carry the at least one acoustic driver. The housing structure may include a user contact surface to be in contact with a user. When the user wears the acoustic output apparatus, the user contact surface may be in contact with a body of the user. An included angle between a connection line between the at least two sound guide holes and the user contact surface may be in a range of 75°-105°.

An integrated optical transducer for detecting dynamic pressure changes comprises a micro-electro-mechanical system, MEMS, die having a MEMS diaphragm with a first side exposed to the dynamic pressure changes and a second side. The transducer further comprises an application specific integrated circuit, ASIC, die having an evaluation circuit configured to detect a deflection of the MEMS diaphragm, in particular of the second side of the MEMS diaphragm. The MEMS die is arranged with respect to the ASIC die such that a gap with a gap height is formed between the second side of the diaphragm and a first surface of the ASIC die and the MEMS diaphragm, the ASIC die and a suspension structure of the MEMS die delineate a back volume of the integrated optical transducer.

Screen vibration systems are provided that can vibrate theatre screens using acoustical, electromagnetic, or another type of energy while reducing the presence of image artifacts that may otherwise be visible as result of vibrating the screen. In one example of a screen vibration system, the system includes a controller and an electromechanical acoustical actuator with an open baffle. The electromechanical acoustical actuator can be uncoupled from the screen in an operational setup. The controller can provide a signal to the electromechanical acoustical actuator for causing the electromechanical acoustical actuator to output energy to displace air that is (i) in front of the electromechanical acoustical actuator and (ii) between the electromechanical acoustical actuator and the screen. The open baffle can prevent displaced air behind the electromechanical acoustical actuator from affecting the screen.

Screen vibration systems are provided that can vibrate theatre screens using acoustical, electromagnetic, or another type of energy while reducing the presence of image artifacts that may otherwise be visible as result of vibrating the screen. In one example of a screen vibration system, the system includes a controller and an electromechanical acoustical actuator with an open baffle. The electromechanical acoustical actuator can be uncoupled from the screen in an operational setup. The controller can provide a signal to the electromechanical acoustical actuator for causing the electromechanical acoustical actuator to output energy to displace air that is (i) in front of the electromechanical acoustical actuator and (ii) between the electromechanical acoustical actuator and the screen. The open baffle can prevent displaced air behind the electromechanical acoustical actuator from affecting the screen

Screen vibration systems are provided that can vibrate theatre screens while reducing the presence of image artifacts that may otherwise be visible as result of vibrating the screen. In one example of a screen vibration system, the system includes a screen, a permanent magnet mounted to the screen, and a magnetic source positioned with respect to the permanent magnet. The screen is moveable in response to a changing magnetic field from the magnetic source.

Screen vibration systems are provided that can vibrate theatre screens using acoustical, electromagnetic, or another type of energy while reducing the presence of image artifacts that may otherwise be visible as result of vibrating the screen. In one example of a screen vibration system, the system includes a screen, a permanent magnet mounted to the screen, and a magnetic source positioned with respect to the permanent magnet and uncoupled from the screen. The screen is moveable in response to a changing magnetic field from the magnetic source.

Screen vibration systems are provided that can vibrate theatre screens while reducing the presence of image artifacts that may otherwise be visible as result of vibrating the screen. In one example of a screen vibration system, the system includes a screen, a permanent magnet mounted to the screen, and a magnetic source positioned with respect to the permanent magnet. The screen is moveable in response to a changing magnetic field from the magnetic source.

Disclosed are an earphone ear-oriented debugging method, apparatus and system, and a wireless earphone. The method comprises: confirming an in-ear state signal indicating that a first earphone and a second earphone are in an in-ear state; sending a plurality of first ear-oriented debugging waves to the second earphone according to the in-ear state signal, wherein the plurality of first ear-oriented debugging waves respectively correspond to a plurality of frequency points for wireless communication in a one-to-one correspondence; receiving a first earphone configuration instruction sent from the second earphone, wherein the first earphone configuration instruction is generated by the second earphone according to the first ear-oriented debugging waves; and configuring a configuration parameter of an antenna matching element of the first earphone according to the first earphone configuration instruction, to optimize a communication state.