The present invention provides an improved optical electro acoustic transducer for use in any acoustic string instrument, such as guitars, violins, string bass, cello, etc. The transducer uses grates to modulate the tight generated by a tight generating device.
An acoustic guitar, one example of an acoustic string instrument, is a guitar that uses only an acoustic sound board. The guitar has a cavity, air in this cavity resonating with the vibration modes of the string and at low frequencies, the volume of the sound generated increases or decreases depending on whether the air in the cavity is moving in phase or out of phase with the strings. The resonance interactions attenuate or amplify the sound at different frequencies, boosting or damping various harmonic tones.
No amplification actually occurs in this process, in the sense that no energy is externally added to increase the loudness of the sound (as would be the case with an electronic amplifier). AB the energy is provided by the plucking of the string, tire function of the entire acoustic system being to maximize intensity of sound.
An acoustic guitar can be amplified by using various types of pickups or microphones. The most common type of pickups used for acoustic guitar amplification are piezo and magnetic pickups. Piezo pickups are generally mounted under the bride saddle of the acoustic guitar and can be plugged into a mixer or amplifier. Magnetic pickups are generally mounted in the sound hole of the acoustic guitar and are very similar to those found in electric guitars. An acoustic guitar with pickups for electrical amplification is known as an acoustic-electric guitar. Hew types of pickups have been introduced to try to amplify the full sound of these instruments, such as systems that include an internal microphone along with the body sensors or under the saddle pickups.
Most stringed instruments produce their sound through the application of energy to the strings, which sets them into vibratory motion. The strings alone, however, produce only a faint sound because they displace only a small volume of air as they vibrate. Consequently, foe sound of the strings atone requires impedance matching to the surrounding air by transmitting their vibrations to a larger surface area capable of displacing larger volumes of air (and thus producing louder sounds). This calls for an arrangement that allows for foe strings to vibrate freely, but also conducts those vibrations efficiently to the larger surface. A bridge is foe customary means by which this is accomplished (a bridge b a device that supports the strings on a stringed instrument and transmits the vibration of those strings to some other structural component of the instrument in order to transfer the sound to foe surrounding air).
Magnetic sound hole pickups exemplify the same functions as that of electric guitar pickups. Basically, they sense the movement of the strings of plain acoustic or acoustic electric guitars through a magnetic field.
Microphones are accurate transducers used to amplify both plain acoustic and acoustic electric guitars, they convert foe sound produced by foe guitar into electrical signals that are then picked up by amplifiers. In contrast with the magnetic sound hole pickups, microphones are more prone to feedback; as such, it is important that they are placed closely to the guitar, and that performers whose guitars have these transducers should have constrained motions. Despite the drawbacks of microphones, many musicians still prefer using these transducers because of their ability to pick up certain guitar sound characteristics such as high frequency and percussive sounds produced by tapping that cannot be picked up by other transducers.
Contact pickups are hi direct contact with some specific parts of acoustic guitars. They pick up the motions taking place in toe locations where they are installed and convert them into electrical signals that are then picked up by amplifiers. Almost all contact pickups use piezoelectric technology. Notable pickups that fall under this classification include the piezos, top pickups, and under-saddle pickups, toe latter two pickups generally being variations of piezos.
The invention disclosed in U.S. Pat. No. 9,024,712, issued on May 5, 2015, discloses an acoustical transducer which uses a reed member and flexure plate to modulate light in accordance with vibrations of the plucked strings of the instrument. Although this device performs as designed, an improved version of the transducer would be preferred.
What is desired is to provide an acoustical transducer, or pickup, that has a more accurate reproduction to tonal quality of the instrument than provided by current piezo and magnetic pickups and more resistant to feedback than provided by microphones and uses grates to modulate light in accordance with the frequency and intensity of a plucked or bowed instrument string.
The present invention relates to a transducer device for use with any acoustic string instrument the transducer device providing a more accurate reproduction of tonal quality to the instrument when compared to existing piezo and magnetic pickups and wherein feedback is significantly reduced when compared to microphone transducers.
The acoustic instrument is fitted with a pair of gratings (as used herein the term “grating” means a glass plate having a alternating fines, or patterns, printed on the plate surface) positioned on the instrument bridge or between the bridge and instrument body in such a fashion that the grating can vibrate freely in sync with the instrument. The instrument is also provided with a compact pickup unit attached thereto in an arrangement comprised of cooperating optoelectronic devices including a fight emitting diode (LED) and photodetector with one or both of the optoelectronic devices to measure the relative displacement between the grating mounting locations. The grating positioned between the LED and photodetector interferes with and when stationary, partially obstructs, the path of a light beam generated by the LED toward the light receiving device. The patterns formed on the gratings modulate the frequency and intensity of the light from the LED impinging on the photodetector to produce an electronic signal that corresponds to both the frequency of the note (or notes) played, the intensity of the note and to the tonal quality of the acoustic instrument on which the pickup is mounted. The associated circuitry of the receiving optoelectronic device is biased so that the output signal thereby can be connected to any industry standard instrument amplifier, sound miner board, or audio retorting device.
In essence, the optical pickup of the present invention comprises two primary components; the optical processor and the audio processor. The optical processor has two components; a pickup transmitter housing, a pickup receiver housing which are mounted in longitudinal coaxial alignment when in use. The components of each housing are as follows:
Pickup Transmitter:
The audio processor contains the pickup power supply, analog processing, the user operation controls and the external audio interface. The audio signal remains in the analog domain at aft times and is not digitized.
For a better understanding of the present invention as well as other objects and further features thereof, reference is made to the following description which is to be read m conjunction with the accompanying drawing therein:
Referring to
A physical representation of optical processor 10 and components 12, 14 and 16 are shown in
The audio processor 20 contains the pickup power supply, analog audio processing and a user operation controlling external audio interface.
When properly mounted and calibrated, the optical pickup 10 faithfully captures the acoustic energy present at its physical location and accurately produces a corresponding analog audio signal. After power-on, the LED source 12 transmits a controlled, fixed intensity of semi-collimated light through the fixed waveguide in the transmitter housing 50 where the light exits through the primary optical grating 30. Coaxially aligned, the light beam enters first the secondary optical grating 32, the receiver housing 52 through the waveguide within housing 52 and strikes the photo-detector 16.
The relative motion between the pick-up transmitter 50 and receiver 52 in the transverse axis perpendicular to the grating fine pairs 30, 32 produces amplitude modulation of the light beam incident thereon. This is measured as changes in the intensity of the light energy as captured by the photo-detector 16. The pair of primary and secondary gratifies 30, 32 capture relative motion between the two by serving as a continuously variable light shutter, alternatingly passing more or less light in synchronization with the relative motion of the pickup housing.
Performance of the pickup may be optimized for signal to noise and dynamic range by selecting the correct pitch grating with line pairs that are matched to the maximum offset displacement the pickup is to measure. It is desirable to avoid over-modulation by leaving a certain amount over the maximum expected displacement. The pickup will product audible non-linear distortion products when modulation levels exceed either the zero fullyopen or 100% fully closed threshold of the gratings. Due to the optical properties, small size and very low mass of the pickup assembly, the system has no resonant frequency within the audible range. This produces exceptional transient response for the musical instrument. Therefore, the pickup operation approaches an ideal transducer, capturing subtle and fast transient motions with no coloring or introduction of inherent sound artifacts.
The intrinsic properties of the pick-up transducer have a frequency response from DC to well beyond the audible range of 20 KHz. In practice, the very low frequencies may be filtered out in the audio signal processor.
Because of the high sensitivity of the pickup, microscopic changes to the geometry of the musical instrument caused by temperature, humidity or other external factors such as string tuning, may create a relative lateral position offset between the transmitter and receiver. For this reason, each pickup transmitter or receiver preferably contains an adjustment screw to finely align the housing's variable waveguide. Note that this tuning of the pickup does not affect the pitch of the instrument as does standard tuning but instead optimizes the alignment of the components to prevent over-modulation in either direction.
Electrically, the photo detector 16 produces a variable current signal in proportion to the level of light intensity it receives. A transimpedance amplifier stage 18 produces a voltage signal that is then processed solely m the analog domain for maximum signal purity. Low noise, low distortion and high-performance operational amplifiers and high-quality components are used to assure maximum fidelity. To maintain consistency hi operation over time and over the life of the LED battery, the audio processor precisely regulates the LED drive current and aft signal biases.
While the invention has been described with reference to its preferred embodiments, it will be understood by those dotted in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the true spirit and scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from its essential teachings.
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