Car Audio Advice | Understanding Theile/Small Parameters

Understanding Theile/Small Parameters
(NOTE: For terms you do not understand,
please refer to our Glossary )

This mathematical description of loudspeaker behavior applies to any sound transducer, but finds it's most common application with enclosure design for woofers/subwoofers.

For most audiophiles, a standard enclosure that meets the VAS requirement for the their driver will usually perform quite adequately. See bold section below.

The three Theile/Small parameters that primarily determine the frequency response of a loudspeaker are:

Compliance or Vas

Free-air resonance or Fs

Response time or Qts

Compliance or Vas is a measure of the overall stiffness, or resistance to motion of the cone, the surround, and the spider. It is specified in term of the volume of air having the same compliance as the driver. A small number corresponds to a small volume of air, which is stiffer than a larger volume of air. Thus, compliance and stiffness are inversely proportional.

Optimum enclosure volume is proportional to Vas . It is usually measured in cubic feet, and generally is equivalent to the internal volume of the enclosure. This is the principle specification for the speaker cabinet

Free-air resonance or Fs is the resonant frequency of the driver's voice coil impedance with the driver suspended in free air (no enclosure). The -3 dB frequency (F3) of an enclosure is proportional to Fs.

Response time or Qts is a measure of the sharpness of the driver's free-air resonance. It is defined as (Fh-Fl)/Fs, where Fh and Fl are the upper and lower -3 dB points of the driver's voice coil impedance in free air. Optimum enclosure volume is related to Qts but is not directly proportional. It is accurate to say that the volume gets larger as Qts gets larger. Likewise, F3 gets smaller as Qts gets larger, and for the sealed box enclosure, F3 is inversely proportional to Qts.

Theile/Small Parameters And Speaker Design
Research done in the study of loudspeakers has been conducted by a number of acousticians. The work of Neville Theile and Richard Small is considered to have the most impact on the loudspeaker design field. They discovered a method that could predict the frequency response performance, and other characteristics of a loudspeaker system, based on its physical properties.

The reference nomenclatures for the Physical Characteristics of a speaker are:

Re: The static D.C. resistance of the voice coil measured in Ohms.

Sd: The surface area of the speaker's cone.

BL: The magnetic strength of the motor structure.

Mms: The total moving mass of the speaker including the small amount of air in front of and behind the cone.

Cms: The stiffness of the driver's suspension.

Rms: The losses due to the suspension.

~ * ~

The Theile/Small Response Parameters

By understanding the relationship of these 20 physical parameters and how to change them, we may alter the response of the system to fit the desired goal.

The most frequently cited measures in design are:

Re: The D.C. resistance of the voice coil measured in Ohms.

Sd: The surface area of the speaker.

Fs: The resonant frequency of the speaker.

Q: The ratio of resistance to reactance, or vice versa.

Qes: The electrical "Q" of the speaker.

Qms: The mechanical "Q" of the speaker.

Qts: The total "Q" of the speaker.

Vas: The volume of air having the same acoustic compliance as the speaker's suspension.

Xmax : The width of the voice coil that extends beyond the front plate plus 15%. This relates to how far the speaker can move in either direction without appreciable distortion. The amount of power required to move a speaker to its maximum excursion is referred to as the displacement limited power handling. Please note that this number varies with enclosure size and type.

Understanding the response parameters allows us to calculate the predicted frequency response of a given speaker system. The formulas that accomplish this are rather lengthy and complex, and are best left to a computer. There are a number of high quality computer programs on the market that automate the design process of building an enclosure. We have located a free example on line.

(Back To The Top)





Technical Help & Education Glossary Of Terms Speakers Main Page How Speakers Work Choosing Speakers What's A Woofer? What's A Midrange? What's A Tweeter? Other Speaker Types More Speaker Types What's A Capacitor? Installing A Capacitor What's A Crossover? What's An Equalizer? Speaker Enclosures Theile/Small Param. About Power Amps Installing An Amp Installation Tips Power Ratings Installing/Replacing Head Units/Receivers Installing Neon/LED Eliminating Noise Use The Right Tools Manufacturer's Links Personal & Marine Electronics Laptop Computers Cell Phones & PDAs Portable TV & Video Electronic Readers MP3/Music Players CD Players/Booms Earphones/Buds Digital Cameras Video Cameras Personal GPS Bluetooth Calculators Accessories Marine Electronics Stereo Amplifiers Stereo Speakers Stereo Woofers Enclosed Speakers TVS & Video CD/Mp3 Receivers GPS & Navigation Fish Finders Accessories Home Stereo & Office Electronics Flat Screen & HD TVs Surround Sound Home Theater DVD Players/Tivo DVD Recorders Blu-Ray Devices Amplifiers/Tuners Speaker Systems Subwoofer Drivers Midrange Drivers Tweeter Drivers Powered Subwoofers Outdoor Speakers Stereo Accessories Digital Photo Frames Video Game Systems Game Accessories Video Games Home Security/Alarms Computer Products Desktops & Laptops Add-Ons/Peripherals Computer Monitors Computer Software Computer Games Printers & Scanners Ink/Specialty Papers Parts & Components Computer Supplies Security/Tech Support Auto Electronics Amplifiers Subwoofers Full-Range Speakers Midrange Speakers Tweeters Power Capacitors Empty Enclosures Loaded Enclosures CD/Mp3 Receivers CD Changers Bass Packages Car TV & Video Satellite Radio Bluetooth Wireless GPS Navigation Neon/LED Lighting Radar Detectors Chrome Mufflers Car Alarms/Security V AUTO PARTS STORE Auto Wiring & Accessories Air Horns Power Antennas Antenna Boosters A/V Controllers Bass Blockers Crossovers Dynamat Equalizers Fans (Cooling) FM Modulators Interfaces Line Converters Noise Filters Power Inverters Power Supplies RCA Cables RCA Splitters Remote Controls Signal Boosters Vibration Control Speaker Grills Wiring Kits		Understanding Theile/Small Parameters (NOTE: For terms you do not understand, please refer to our Glossary ) This mathematical description of loudspeaker behavior applies to any sound transducer, but finds it's most common application with enclosure design for woofers/subwoofers. For most audiophiles, a standard enclosure that meets the VAS requirement for the their driver will usually perform quite adequately. See bold section below. The three Theile/Small parameters that primarily determine the frequency response of a loudspeaker are: Compliance or Vas Free-air resonance or Fs Response time or Qts Compliance or Vas is a measure of the overall stiffness, or resistance to motion of the cone, the surround, and the spider. It is specified in term of the volume of air having the same compliance as the driver. A small number corresponds to a small volume of air, which is stiffer than a larger volume of air. Thus, compliance and stiffness are inversely proportional. Optimum enclosure volume is proportional to Vas . It is usually measured in cubic feet, and generally is equivalent to the internal volume of the enclosure. This is the principle specification for the speaker cabinet Free-air resonance or Fs is the resonant frequency of the driver's voice coil impedance with the driver suspended in free air (no enclosure). The -3 dB frequency (F3) of an enclosure is proportional to Fs. Response time or Qts is a measure of the sharpness of the driver's free-air resonance. It is defined as (Fh-Fl)/Fs, where Fh and Fl are the upper and lower -3 dB points of the driver's voice coil impedance in free air. Optimum enclosure volume is related to Qts but is not directly proportional. It is accurate to say that the volume gets larger as Qts gets larger. Likewise, F3 gets smaller as Qts gets larger, and for the sealed box enclosure, F3 is inversely proportional to Qts. Theile/Small Parameters And Speaker Design Research done in the study of loudspeakers has been conducted by a number of acousticians. The work of Neville Theile and Richard Small is considered to have the most impact on the loudspeaker design field. They discovered a method that could predict the frequency response performance, and other characteristics of a loudspeaker system, based on its physical properties. The reference nomenclatures for the Physical Characteristics of a speaker are: Re: The static D.C. resistance of the voice coil measured in Ohms. Sd: The surface area of the speaker's cone. BL: The magnetic strength of the motor structure. Mms: The total moving mass of the speaker including the small amount of air in front of and behind the cone. Cms: The stiffness of the driver's suspension. Rms: The losses due to the suspension. *~ ~ The Theile/Small Response Parameters By understanding the relationship of these 20 physical parameters and how to change them, we may alter the response of the system to fit the desired goal. The most frequently cited measures in design are: Re: The D.C. resistance of the voice coil measured in Ohms. Sd: The surface area of the speaker. Fs: The resonant frequency of the speaker. Q: The ratio of resistance to reactance, or vice versa. Qes: The electrical "Q" of the speaker. Qms: The mechanical "Q" of the speaker. Qts: The total "Q" of the speaker. Vas: The volume of air having the same acoustic compliance as the speaker's suspension. Xmax : The width of the voice coil that extends beyond the front plate plus 15%. This relates to how far the speaker can move in either direction without appreciable distortion. The amount of power required to move a speaker to its maximum excursion is referred to as the displacement limited power handling. Please note that this number varies with enclosure size and type. Understanding the response parameters allows us to calculate the predicted frequency response of a given speaker system. The formulas that accomplish this are rather lengthy and complex, and are best left to a computer. There are a number of high quality computer programs on the market that automate the design process of building an enclosure. We have located a free example on line. (Back To The Top)**		MAIN PAGE GLOSSARY SPEAKERS: Choosing General Woofers Miidrange Tweeters Full-Range Full-Range 2 CAPACITORS CROSSOVERS EQUALIZERS	ENCLOSURES: Theile/Small AMPLIFIERS: About Installing Install Tips Power Ratings RECEIVERS: Installing NEON/LED: Installing TOOLS

	Home -- Policies -- Products -- Tech Center -- Auto Electronics -- Home Electronics -- Personal & Marine Electronics -- Stereo Tech Info Website Designed & Maintained by MetroDirect Communications Copyright (c) 2000 - 2009 Electronixwarehouse.com . Use of any material appearing on this site without specific written permission is prohibitied by law. electronixwarehouse.com --- logobannerfactory.com --- bleepthem.com (Political Satire) --- rlebeaux.com --- stereotechnicalinformation.com (Stereo Technical Help) --- electronixwarehouse.net --- thespeakerstore.com --- wmpublishing.com (Help For Writers) --- barbarathenovel.com --- cutethenovel.com
--			--