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- SPEAKER ENCLOSURE DESIGN CALCULATOR LINEAR DRIVERS
- SPEAKER ENCLOSURE DESIGN CALCULATOR LINEAR DRIVER
- SPEAKER ENCLOSURE DESIGN CALCULATOR LINEAR SERIES
Many others continued to develop various aspects of loudspeaker enclosure design in the 1960s and early 1970s. It is important to note that Thiele's work neglected enclosure losses and, although the application of filter theory is still important, his alignment tables now have little real-world utility due to neglecting enclosure losses. This paper remained relatively unknown outside Australia until it was re-published in the Journal of the Audio Engineering Society in 1971.
SPEAKER ENCLOSURE DESIGN CALCULATOR LINEAR SERIES
Thiele described a series of sealed and vented box "alignments" (i.e., enclosure designs based on electrical filter theory with well-characterized behavior, including frequency response, power handling, cone excursion, etc.) in a publication in an Australian journal. In 1961, leaning heavily on Novak's work, A.
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Novak used novel simplifying assumptions in an analysis in a 1959 paper which led to a practical solution for the response of a given loudspeaker in sealed and vented boxes, and also established their applicability by empirical measurement. Beranek of the Massachusetts Institute of Technology published Acoustics, a book summarizing and extending the electroacoustics of the era. Progress on loudspeaker enclosure design and analysis using acoustic analogous circuits by academic acousticians like Harry F. 1869178) his "Sound Translating Device" (essentially a vented box) which was evidence of the interest in many types of enclosure design at the time. Thuras of Bell Labs patented (US Patent No. Kellogg, fueled by advances in radio and electronics, increased interest in direct radiator loudspeakers.
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Rather than purchase off-the-shelf components, loudspeaker design engineers often define desired performance and work backwards to a set of parameters and manufacture a driver with said characteristics or order it from a driver manufacturer. when the entire cone moves in and out as a unit without cone breakup.
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Many of the parameters are strictly defined only at the resonant frequency, but the approach is generally applicable in the frequency range where the diaphragm motion is largely pistonic, i.e. Using these parameters, a loudspeaker designer may simulate the position, velocity and acceleration of the diaphragm, the input impedance and the sound output of a system comprising a loudspeaker and enclosure.
SPEAKER ENCLOSURE DESIGN CALCULATOR LINEAR DRIVERS
These parameters are published in specification sheets by driver manufacturers so that designers have a guide in selecting off-the-shelf drivers for loudspeaker designs. Thiele/Small parameters (commonly abbreviated T/S parameters, or TSP) are a set of electromechanical parameters that define the specified low frequency performance of a loudspeaker driver.