150 results about "Microphonism" patented technology

An active noise cancellation system includes a series of features for more effective cancellation, greater reliability, and improved stability. A particular feature adapted for headset systems includes locating a residual microphone radially offset from the center of a sound generator to detect a signal more similar to that incident upon the eardrum of the user. In addition, an open back headset design includes perforations on the side of the headset instead of the back, so that the perforations are less susceptible to inadvertent blockage. The system also includes a mechanism for detecting changes in the acoustic characteristics of the environment that may be caused, for example, by pressure exerted upon the earpieces, and that may destabilize the cancellation system. The system automatically responds to such changes, for example, by reducing the gain or the frequency response of the system to preserve stability. The system further includes other methods for detecting imminent instability and compensating, such as detecting the onset of signals within enhancement frequencies characteristic of the onset of instability, and adjusting the gain or frequency response of the system or suppressing the enhanced signals. The system further includes a mechanism for conserving battery life by turning the system off when sound levels are low, or adjusting the power supply to the system to correspond to the current power requirements of the system.

A flood control device and system which controls conductive fluid(s) in a conductive fluid supply line and or path, using the conductivity of said fluid(s). The conductive fluid system comprises; a conductive fluid supply line, in-line conductive fluid shut-off valve, in-line conductive fluid detector, conductive fluid sensor(s) (attached in or to conductive fluid dependent appliances), a D.C. powered central processing unit, and control panel. The conductive fluid flows through said conductive fluid line, said in-line conductive fluid shut-off valve, intern reaching said in-line conductive fluid detector which detects the flow of conductive fluid, thereby sending data to said central processing unit. When said central processing unit receives said data, said central processing unit delays for a predetermined amount of time (example 3 seconds) waiting to receive data from one or more of said conductive fluid sensor(s). If said central processing unit doesn't receive said data from said conductive fluid sensor(s) within said predetermined, said central processing unit will automatically send data to said in-line conductive fluid shut-off valve, to close, therefore terminating the forward flow of conductive fluid(s). System also includes audible signal(s) to signal an alarm condition, timing mode(s) for water conservation and monitoring in-line conductive fluid shut-off valve movements, a phone notifier for notifying user of said termination of conduct fluid due to a conductive fluid leak detection, and for (user-set) excessive water usage, means for communicating with said central processing unit by way of telephonic communication (to close or re-open said in-line conductive fluid shut-off valve), a battery back up system, and means of operating by way of manual means.

An earphone adapted to fit within a human ear that generates sound via the propagation of one or more diaphragms aligned to fit the structure and shape of the earphone. The earphone allows ambient sound to pass through the device in order to be heard by the user. The earphone includes a variety of sensors adapted to characterize the surrounding acoustic environment and actively negate undesired sounds by generating a cancelling signal specific to the undesired sound or sounds. The earphone allows users to select particular sounds to cancel or to negate all of the surrounding noise. The earphone itself can be used to characterize repetitive environmental sounds that are predictable by the system. Additionally, the earphone can be used in conjunction with a buffering device in communication with a source of non-repetitive, unpredictable sounds in order to characterize and negate those sounds.

An electronic card comprises a thin, flexible substrate having electrical circuitry embedded therein. An activation device is disposed in the substrate and is configured to complete a circuit in response to a stimulus, such as light or sound. An output device is disposed in the substrate and is configured to produce an output, such as music or vibration, wherein the output device is activated upon the completion of the circuit by the activation device. A cavity is formed in an outer surface of the substrate and has electrical contacts at an inner portion thereof in electrical communication with the electrical circuitry. The cavity further comprises retaining means for replaceably retaining a battery in the cavity to enable the battery to provide power to the electrical circuitry, the activation device, and the output device. The retaining means allows a battery to be removed from the cavity and replaced with another battery.

An active stethoscope or other sound detection device, including a diaphragm, at least one floating mass mounted to the diaphragm (at at least one coupling point of the diaphragm), and an acoustic transducer mounted to the floating mass. Preferably, each floating mass is configured and mounted so that as each floating mass and each coupling point of the diaphragm move in sympathy with acoustic waves (to be detected) that impinge on the diaphragm, the acoustic transducer rides with and is stabilized by the floating mass to which it is mounted and the diaphragm is stabilized by each floating mass. The acoustic transducer can be of any of many different types. For example, it can be a microphone, or an optical, capacitive, or inductive transducer. The diaphragm can have an isolating portion which absorbs acoustic surface wave energy incident thereon, or otherwise prevents or reduces transmission of acoustic surface waves through the isolating portion between regions of the diaphragm.

Acoustic volume indicators comprise a resonator, a frequency detector, and an indicator. The resonator can be an impactor or a vibration generator. The detector responds to vibration signals provided from the tank wall, which signals will show a significant increase in amplitude at the resonant frequency of the tank and its contents. The detector can be an accelerometer designed to record the received signal. The recorded signal is converted/analyzed by the frequency detector, and is compared to a known preprogrammed specific frequency vs. volume characteristic of the tank. Various audible and/or visual output or indicator devices can be used to indicate whether the liquid volume measurements within or outside of a predetermined volume range based on the known tank characteristics.

A drumhead tone control device employs an annular configuration of polyester film tightly adhered to the periphery of a drumhead membrane. The annular configuration of the tone control device includes radial and/or circumferential relief. The relieved tone control device disrupts transmission of vibrations reflected from the drumhead membrane/drum shell interface. Disruption of reflected vibrations improves the overall tonal quality of the drumhead while use of a tightly adhered polyester sheet close to the periphery of the drumhead playing surface minimizes undesirable alteration of the attack characteristics and fundamental tone of the drumhead.

Anti-counterfeit and anti-theft buttons include at least a body embedded with a RFID system containing one or plural RFID chips. Each RFID chip may be of a single or double or multiple frequencies. If the single frequency is used, it may be a high frequency (HF) or an ultrahigh frequency (UHF). If the double frequencies are used, they may be any composition of HF and UHF. If the multiple frequencies are used, they may be a single HF and plural UHF, or plural HF and single UHF. The RFID chip is jointed with an antenna that may be of a single or multiple circuits and should have an extended antenna. All antennas can enhance effects of receiving signals. When two of these buttons fitted together are illegally separated, a system host may operate to give out warning signals or sound, achieving counterfeit and theft prevention.

A theft protection device for photovoltaic solar panels is provided. The device includes of at least one cable which is made to pass through the solar panels. The cable can be fibre optic or electrical, and a light beam or an electrical current, respectively, is made to circulate through the cable. At the ends of the cable, an electrical control circuit is connected, capable of detecting a cut in the cable caused by the interruption of the light beam in the fibre or a voltage drop at the ends of the electrical cable. Cutting of the cable for theft of the solar panels is detected by the control circuit which activates an alarm, acoustic and/or visual, which can belong to the device or be remote.

An electro-acoustic product stabilizing device includes: a sound device; an angle adjustment element, coupled pivotally to one side of the sound device; a hard fixation portion, configured on one side of the angle adjustment element; and a flexible support element, in connection with the angle adjustment element. Whereby, when the electro-acoustic product of the present invention is a headset or hearing aid, it is attached and fixed in a user's ear through the characteristic of the flexible support element being capable of adaptable shape change to be fixed to the use's inner ear bones; and then, the attachment of the flexible support element to the ear to be more comfortable through the angle adjustment element in combination with the sound device. In addition, the strengthening fixation of the hard fixation portion to the sound device increases the combination stability of the sound device with the ear.

In a conventional hard material insulator, reproduced sound can be tuned with use of characteristics of the material; however, various types of acoustic materials have specific high frequency characteristics, and thus their acoustic effects lack versatility, require compatible audio devices, and change with environment, musical genre, etc. To address this, a wind-bell member (resonant member) is arranged in parallel with a main propagation path of vibration transferred from an audio device to an insulator. Accordingly, a vibration system of a wind-bell having a tone determined by many factors such as a fundamental tone, harmonic tones, lingering sound, and fluctuation assists (enhances) high frequency vibration propagated from the audio device. As a result, due to the above assist action that is different in principle from a conventional type, acoustic characteristics such as a sense of localization, resolution, and a sense of transparency and scale a sound image can be dramatically improved.

The invention discloses a device and a method for detecting the airtightness of a bottle cap based on sound signal processing. The method comprises three parts, namely generation, extraction and analytical processing of a sound signal, wherein an electromagnetic excitation device excites the bottle cap to generate the sound signal and consists of an electromagnet and a control circuit; and the extraction of the sound signal is realized by a sound sensor, namely a microphone. A digital signal processing (DSP) circuit comprises a sound pickup module, a signal amplification module, an analog filtering module, a signal threshold value detection module, a voltage conversion module and the like. The device and the method have good detection effect; and the detection accuracy rate of a product in experiments reaches 99 percent.

The invention discloses an MEMS (Micro Electronic Mechanical System) capacitive microphone without a back polar plate and a manufacture method thereof. The MEMS capacitive microphone comprises a substrate, a back cavity, a first polar plate of a capacitor, a second polar plate of the capacitor, a vibration diaphragm and leads, wherein the back cavity is positioned on the substrate; the vibration diaphragm is arranged on the substrate and is used for detecting acoustical vibration and converting the acoustical vibration into displacement; the first polar plate is arranged on the substrate; the second polar plate is arranged on the vibration diaphragm and is provided with bulges which are used for preventing the first polar plate and the second polar plate from being mutually sucked; and the leads are used for leading out the first polar plate and the second polar plate so as to form electric connection.