A speaker and an electronic device using the speaker are disclosed. The speaker includes a frame with a receiving cavity, and a vibration system and a magnetic circuit system that are contained in the receiving cavity. The vibration system includes a diaphragm assembly and a voice coil. The voice coil includes a coil body and a lead wire extending from the coil body. The diaphragm assembly includes a main body and an avoiding part formed by bending from the main body and in a direction far away from the voice coil. The coil body is bonded with the main body and forms an avoiding space together with the avoiding part. The lead wire passes through the avoiding space to electrically connect with an external power supply. The speaker and the electronic device can have a miniaturized overall size and a better reliability.

A loudspeaker device includes first and second diaphragms arranged co-axially in an opposed relation to each other and having a rear volume in-between, each diaphragm having a plurality of motors operatively coupled thereto, and a frame having first and second ends, and first and second rims provided at the first and second ends, respectively. The motors of the first and second diaphragms are arranged in the same plane, and the motors are provided on the frame around the periphery of the first and second diaphragms.

A loudspeaker having a frame, a diaphragm, a support element for the diaphragm, and a magnetic circuit that includes a yoke, a core and a magnet. The yoke and the core form an air gap. An upper portion of a coil is connected to the diaphragm and a lower portion of the coil is in the air gap. The diaphragm includes inner, outer and intermediate annular portions. The inner annular portion includes an arch-shaped first central section and a first inner edge connected to the support element and a first outer edge. The outer annular portion includes an arch-shaped second central section, a second inner edge and a second outer edge connected to the frame. The intermediate annular portion includes a dome-shaped section with downwardly-facing concavity and from which a funnel-shaped section extends. The funnel-shaped section converges towards the support element and is connected to the first outer edge.

A method of making an acoustic sensor (e.g., for use in a piezoelectric MEMS microphone) includes forming or providing a mold having one or more grooves in a top surface of the mold that extend in a direction of the length of the mold to a distal end of the mold. The method also includes forming or depositing a structure having one or more piezoelectric layers over the top surface of the mold to define a beam, the distal portion of the beam having a corrugated section including one or more grooves that correspond to the grooves of the mold. The method also includes forming a gap in the structure to define two beams separated by the gap, and releasing the structure from the mold to form one or more cantilever beams that increases an acoustic resistance of the gap between sensors.

The present invention discloses a loudspeaker, and a manufacturing method and a sound production method therefor. The loudspeaker includes a vibrating diaphragm, a frame, a magnetic loop system, a voice coil, a suspension edge, a connecting member and a limiting part, wherein the magnetic loop system is arranged on the frame. A lower end of the voice coil is coupled to the magnetic loop system. A suspension edge outer side and a suspension edge inner side of the suspension edge extend and are respectively connected to the frame and the vibrating diaphragm, so as to allow the suspension edge to be maintained between the frame and the vibrating diaphragm. The connecting member is configured to connect to the vibrating diaphragm and the voice coil. A limiting outer side and a limiting inner side of the limiting part extend and are respectively connected to the frame and the connecting member, so as to allow the limiting part to be maintained between the frame and the connecting member.

An attenuator is disclosed that enables a microphone's relatively undistorted pick up of a voice that is generated in close proximity to the microphone. This attenuator is a key component of a groundbreaking assistive device or handset/headset that empowers individuals with speech impairments to effectively communicate and reintegrate into society. By leveraging advanced acoustic hardware, intelligent voice algorithms, and a comprehensive image-or-vocabulary-to-impaired-voice database, the handset/headset facilitates understanding the user's impaired speech by harvesting understood terminology and outputting the same in a communicative context. Thus, the handset/headset enables seamless public interaction, independence, and improved quality of life to the user with speech impediments and ensures equal participation and inclusion in everyday verbal interactions.

A speaker includes a diaphragm assembly and a magnetic circuit assembly. The diaphragm assembly includes at least two voice coils. The magnetic circuit assembly includes first magnets and a second magnet. A plurality of first magnets are disposed around the second magnet. A vent groove is disposed between two adjacent first magnets. The voice coil is disposed between the second magnet and the first magnet. The speaker includes at least two magnetic circuit assemblies. The magnetic circuit assembly is disposed corresponding to the voice coil. Two adjacent magnetic circuit assemblies share a same first magnet.

Disclosed is a dual-cone loudspeaker, including: a frame; a cone assembly arranged on the frame and including a central cone and an outer cone; a central drive mechanism for driving the central cone to vibrate; and a plurality of outer driving mechanisms for driving the outer cone to vibrate. The outer driving mechanisms are arranged around the central drive mechanism. The central drive mechanism includes a central voice coil connected to the central cone, and a central magnetic driving system for driving the central voice coil. Each of the plurality of outer driving mechanisms comprises an outer voice coil connected to the outer cone, an outer damper sleeved on the outer voice coil, and an outer magnetic driving system for driving the outer voice coil.

The present disclosure relates to a loudspeaker transducer comprising a diaphragm (112), a frame (120), an inner suspensions element (118) and an outer suspension element (110). The diaphragm (112) comprises a portion turning inwards (102) towards the frame (120). The outer suspension element (110) is located closer than the inner suspension element (118) to the main opening of the frame through which the loudspeaker transducer radiates sound. The inner suspension element (118) is connected to the frame (120) and the inward turning portion (102). The inner suspension element (118) is connected to the inward turning portion (102) at an outer end (203) of the diaphragm.

This application relate to the field of electronic device technologies, and in particular, to a loudspeaker and an electronic device. Embodiments of this application are provided to resolve a technical problem of insufficient sensitivity of a loudspeaker caused by a small electromagnetic driving force that drives a voice coil to vibrate. According to a loudspeaker and an electronic device in embodiments of this application, a yoke includes a bottom part and a sleeve located on the side of the bottom part. An annular magnet is sleeved on the outer side of the sleeve. A voice coil is sleeved on the sleeve and located between the magnet and the sleeve. A damper is located in a region enclosed by the sleeve. An outer edge of the damper is connected to the voice coil, and a middle part of the damper is connected to the yoke.