A headphone control system for use within a headphone includes a temperature sensor for detecting whether the circumference temperature of the headphone is relatively far from the human temperature implying the headphone is no longer worn by the user, and a gravity sensor for detecting whether the headphone is stationary implying that the headphone is not used for enabling a power saving mode, or is moving implying that the headphone is not yet unused for maintaining operation. The detection constantly is applied to the headphone disregarding whether the headphone is in an operation mode or a power saving mode so as to efficiently have the headphone operated in response to currently using or power-saved in response to non-using.

A headset having game, chat and microphone audio signals is provided with a programmable signal processor for individually modifying the audio signals and a memory configured to store a plurality of user-selectable signal-processing parameter settings that determine the manner in which the audio signals will be altered by the signal processor. The parameter settings collectively form a preset, and one or more user-operable controls can select and activate a preset from the plurality of presets stored in memory. The parameters stored in the selected preset can be loaded into the signal processor such that the sound characteristics of the audio paths are modified in accordance with the parameter settings in the selected preset.

A system for improving accuracy of self-detection of a voice includes a first cup element having a forward end configured to contact a human face and a rear end configured to be spaced from a human head on which the human face is located such that the first cup element defines a first void configured to receive a first ear of the human head, the first cup element defining an opening to an environment of the system to provide a pathway for sound waves to travel into the first void. The system further includes a second cup element being a mirror image of the first cup element and defining a second void configured to receive a second ear of the human head.

The present invention relates to a sensor arrangement, to a corresponding method of assembling such a sensor arrangement, and to a sensor system. The sensor arrangement comprises at least one transducer element for monitoring at least one measurand and generating an electrical output signal correlated with the at least one measurand; and a sensor substrate comprising the transducer element. The sensor substrate is mountable on a circuit carrier in a way that a media channel penetrating the circuit carrier allows access of the at least one measurand to the transducer element. The circuit carrier has an electrically conductive solderable first sealing pattern which surrounds the media channel at least partly and which is aligned with a solderable second sealing pattern arranged on the sensor substrate, so that a soldered sealing connection, which at least partly surrounds the media channel, is formed between the first sealing pattern and the second sealing pattern.

Provided is a sound generation device wherein noise can be reduced in accordance with a predetermined frequency band. An elastic member (8) is provided to obtain a sound pressure characteristic having a sub-peak at a predetermined frequency on the lower side than a lowest resonance frequency, and a phase characteristic such that a change rate of phase difference is lowered around the predetermined frequency. When the phase characteristic is calculated by simulation or actually measured in advance and an input signal is controlled such that the generated sound has an opposite phase to the noise, the generated sound can be made less prone to deviate from the opposite phase to the noise even if a time difference is caused between noise sound collection and sound generation at around the predetermined frequency, with the result that the noise can be effectively reduced. In addition, restrictions regarding the equivalent mass and resonance frequency of a diaphragm (3) can be reduced, the flexibility of design can be improved, and the noise can be reduced in accordance with the predetermined frequency band.

The present disclosure provides a glasses. The glasses may include a glasses frame and two speakers. The glasses frame may include a glasses rim and two glasses temples. The two glasses temples may be rotatably connected to the glasses rim, respectively. For each of the two speakers, the speaker may include an earphone core and a core housing. The speaker may be connected to one of the two glasses temples via a hinge component connected thereto. The hinge component may be rotatable to change a position of the speaker relative to the glasses temple. The core housing may include a contact surface. The contact surface may include a gradient structure for causing an uneven distribution of pressure on the contact surface when in contact with a user. The glasses temple connected to the speaker may include at least one of a control circuit or a battery. The at least one of the control circuit or the battery may drive the earphone core of the speaker to vibrate to generate sound. The glasses of the present disclosure may meet various requirements of people when wearing glasses, and a hinge state of the glasses may be switched easily, thereby providing convenience for users.

The present disclosure embodiment may disclose a glasses. The glasses may include a glasses frame and two speakers. The glasses frame may include a glasses rim and two glasses temples. The two glasses temples may be rotatably connected to the glasses rim, respectively. The two speakers may be connected to the two glasses temples via hinge components of the two glasses temples, respectively. The hinge components may be rotatable to change a position of each of the speakers relative to one of the glasses temples. The two speakers may include an earphone core and an earphone housing. The earphone housing may include a housing panel facing a human body and a housing back opposite to the housing panel. At least one of the glasses temples may include a control circuit or a battery. The control circuit or the battery may drive the earphone core to vibrate to generate sound. A vibration of the earphone core may result in vibrations of the housing panel and the housing back. The vibration of the housing panel may have a first phase, and the vibration of the housing back may have a second phase, vibration frequencies of the housing panel and the housing back may be in a range of 2000 Hz to 3000 Hz, and an absolute value of a difference between the first phase and the second phase may be less than 60 degrees. In the present disclosure, a function member may be connected to the glasses through the hinge component to expand use of the glasses.

The present disclosure may relate to a glasses. The glasses may include a glasses frame and two speakers. The glasses frame may include a glasses rim and two glasses temples. The two glasses temples may be rotatably connected to the glasses rim, respectively. The two speakers may include an earphone core. The two speakers may be connected to the two glasses temples via hinge components of the two glasses temples, respectively. Each hinge component may be rotatable to change a position of its connected speaker relative to one of the two glasses temples. The glasses temple may include a control circuit or a battery. The control circuit or the battery may drive the earphone core to vibrate to generate sound. The sound may include at least two resonance peaks.

The present disclosure embodiment may disclose glasses. The glasses may include a glasses frame and two speakers. The glasses frame may include a glasses rim and two glasses temples. The two glasses temples may be rotatably connected to the glasses rim, respectively. The two speakers may include an earphone core, respectively. The two speakers may be connected to the two glasses temples via hinge components of the two glasses temples, respectively. The hinge components may be rotatable to change a position of each of the speakers relative to connected one of the glasses temples to make the speaker abut in front of or behind ears of a user. The glasses temple may include a control circuit or a battery to drive the earphone core to vibrate to generate a sound. The glasses of the present disclosure may satisfy various requirements when a user wears the glasses, and the hinge state may be switched easily, thereby providing convenience for the user.

The present disclosure embodiment may disclose eyeglasses. The eyeglasses may include an eyeglass frame and two speakers. The eyeglass frame may include an eyeglass rim and two eyeglass temples. The two eyeglass temples may be rotatably connected to the eyeglass rim, respectively. The two speakers may include an earphone core. The two speakers may be connected to the two eyeglass temples via hinge components of the two eyeglass temples, respectively. Each hinge components may be rotatable to change a position of its connected speakers relative to one of the two eyeglass temples. The eyeglasses of the present disclosure may satisfy various requirements when a user wears the eyeglasses, and the hinge state may be switched easily, thereby providing convenience for the user.