Active Noise Control FAQ Version 2007-02-04 The "FAQ" you are now reading discusses active noise control, a novel way of using basic physics to control noise and/or vibration. What is an FAQ, you say?  It's a "Frequently Asked Questions list."  The Internet supports thousands of "newsgroups" - discussion forums covering every imaginable topic. When certain questions tend to get asked over and over again, it's common to assemble the answers into a list for easy reference. This particular FAQ was written for the newsgroups news:alt.sci.physics.acoustics and news:comp.dsp to serve four purposes: * Provide concise, accurate answers to common questions about active noise control. * * Dispel popular misconceptions about what active noise control can and cannot do. * * Refer readers to web links, technical references, and other sources of information. * * Stimulate public interest in acoustics. * 1. Introduction 1.1  How to use this FAQ You can always find the latest version of this document here: http://www.ChrisRuckman.com/ancfaq.htm If you have general questions about active noise control, please post them in this newsgroup: news:alt.sci.physics.acoustics. To contribute to the FAQ or provide comments, praise, or criticism directly to the FAQ maintainer, send email to ancfaq@ChrisRuckman.com. To cite this FAQ as a reference: There is no universally accepted format for citing an Internet resource as a reference, but the following citation would be suitable for many publications: Ruckman, C.E., "Frequently Asked Questions: Active Noise Control," Internet FAQ document, available on the Worldwide Web at www.ChrisRuckman.com/ancfaq.htm, February 2007. 1.2  What's new in the Active Control FAQ In 1994, the Acoustical Society of America presented the author, Dr. Chris Ruckman, with its 1994 Science Writing Award for this FAQ. The award recognizes "distinguished writing (or producing) that improves public understanding and appreciation of acoustics." The ASA, which gives two such awards each year, had never before honored a work published only on the Internet. Date:        Topic added or changed: 2007-02-03 Moved to www.ChrisRuckman.com; updated and reformatted. 2001-02-27   Info on patents database; MathTools link. 2000-08-06   Updated format; updated some company info. 1999-07-31   Removed most links and other "perishable" information. 1998-02-14   Web site moved to www.erols.com/ruckman/ancfaq.htm. 1997-11-13   updated contact info and some web sites 1996-11-10   FAQ broken into 3 files 1996-06-23   translated to HTML 1995-12-04   rearranged sections; archive-name changed back to original 1995-11-27   archive-name changed 1995-02-24   expanded intro, revised format, added basics (1.5) 1994-06-14   initial release 1.3  Contributors The following people contributed to the discussions upon which this FAQ is based: Ralph T. Muehleisen, Chris Lawrenson, Stephen Lajoie, Susan Mercy, Rolf Diehl, Jeffrey Stuart Vipperman, Marcus Bronzel, Johan L. Nielsen, Colin Hansen, Michel Schonewille, Soeren Laugesen, Todd Toles, John Gilliver, Lee Leggore, Chris Fuller, Birger Bech Jessen, Dr. Dexter Smith, and many others. 1.4  Copyright information and disclaimer Copyright (c) 1994-2007 by Christopher E. Ruckman. All Rights Reserved. All rights are reserved. Christopher E. Ruckman ("Author") hereby grants permission to use, copy and distribute this document for any NON-PROFIT purpose, provided that the article is used in its complete, UNMODIFIED form including both the above Copyright notice and this permission notice. Reproducing this article by any means, including (but not limited to) printing, copying existing prints, or publishing by electronic or other means, implies full agreement to the above non-profit-use clause. Exceptions to the above, such as including the article in a compendium to be sold for profit, are permitted only by EXPLICIT PRIOR WRITTEN CONSENT of Christopher E. Ruckman. Disclaimer: This document represents the personal opinions of the Author, and does not necessarily represent the opinion of the US Government or the Author's employer, nor anyone other than the Author. Any mentions of commercial products, company names, or universities are solely for information purposes and do not imply any endorsement by the Author or any other entity. The Author provides this article "as is." The Author disclaims any express or implied warranties including, but not limited to, any implied warranties of commercial value, accuracy, or fitness for any particular purpose. If you use the information in this document in any way, you do so entirely at your own risk. 2. Background 2.1  Basics: What is sound? Frequency? Wavelength? If you are not familiar with how sound works, a brief refresher course may help. Don't be put off by occasional technical jargon. Most of the FAQ includes analogies and examples to illustrate ideas in plain language. (The author apologizes to acousticians everywhere for presuming to summarize their craft in a few paragraphs.) Sound is a pressure wave traveling in air or water. A sound wave resembles the surface wave made when you throw a stone into a calm pool of water, except that * the sound wave consists of tiny fluctuations in the air pressure rather than fluctuations in water height, * * a sound wave can travel in three dimensions rather than two, and * * the waves travel MUCH faster (340 meters per second in air). * Sound is usually generated by vibration of an object or surface such as a speaker cone, a violin body, or human vocal cords. The vibrating surface "radiates" pressure waves into the adjoining air or water as sound. (Obviously, sound can also be generated by turbulent airflow, by bubbles collapsing, or by many other phenomena.) The frequency (number of wave crests per unit time that pass a fixed location) measures the tone or pitch of a sound. For example, a bass guitar plays lower frequencies than a violin. The wavelength, or distance between wave crests, is related to frequency: lower frequencies have longer wavelengths. In some respects, sound and vibration are quite similar. You might find it useful to think of sound as a vibration traveling through air. Many of the same concepts apply for both sound and vibration, but there are certain significant differences. For example, when sound travels through air, all frequencies of sound travel at the same speed (340 meters per second). By contrast, for some types of vibration traveling through a structure such as a wall or floor, low frequencies travel faster than high frequencies. How is noise different from sound? Noise is simply unwanted sound. Philosophers wonder: "If a tree falls in the forest and nobody is there to hear it, does it make any noise?" When they phrase the question in precisely that way, the answer is NO for this reason: "sound" is not really "noise" unless someone hears it AND finds it offensive. 2.2  What is active noise control? The question is usually posed like this: "I heard about a new noise control technology called Active Something-Or-Other. Can I use it to make my house quiet when my neighbor’s son plays 'Black Sabbath' on his electric guitar?" Another variant is “Can I create a silent paradise in my back yard next to a major highway?” The technology in question is "active noise control," also known as "active noise cancellation" or "anti-noise," and it has been a topic of intense scientific research for several decades. Let's jump straight to the bottom line: yes, active noise control works in the proper circumstances, but no, you cannot use it to noise-proof an entire house. Active noise control is sound field modification, particularly sound field cancellation, by electro-acoustical means. In its simplest form, a control system drives a speaker to produce a sound field that is an exact mirror-image the offending sound (the "disturbance"). The speaker thus "cancels" the disturbance, and the net result is no sound at all. In practice, of course, active control is somewhat more complicated. The name differentiates "active control" from traditional "passive" methods for controlling unwanted sound and vibration. Passive noise control treatments include "insulation", silencers, vibration mounts, damping treatments, absorptive treatments such as ceiling tiles, and conventional mufflers like the ones used on today's automobiles. Passive techniques work best at middle and high frequencies, and are important to nearly all products in today's increasingly noise-sensitive world. But passive treatments can be bulky and heavy when used for low frequencies. The size and mass of passive treatments usually depend on the acoustic wavelength, making them thicker and more massive for lower frequencies. The light weight and small size of active systems can be a critically important benefit; see later sections for other benefits. In control systems parlance, the four major parts of an active control system are: * The plant is the physical system to be controlled; typical examples are a headphone and the air inside it, or air traveling through an air-conditioning duct. * * Sensors are the microphones, accelerometers, or other devices that sense the disturbance and monitor how well the control system is performing. * * Actuators are the devices that physically do the work of altering the plant response; usually they are electromechanical devices such as speakers or vibration generators. * * The controller is a signal processor (usually digital) that tells the actuators what to do; the controller bases its commands on sensor signals and, usually, on some knowledge of how the plant responds to the actuators. * Analog controllers may also be used, although they are somewhat less flexible and more difficult to use. 2.3  Is active control new? The idea of active noise control was actually conceived in the 1930's (see the Lueg patent mentioned below), and more development was done in the 1950's. However, it was not until the advent of modern digital computers that active control became truly practical. Active control became a "mainstream" research topic in the 1970's and 1980's. In recent years, researchers have published technical articles at the rate of several hundred per year. There are now dozens of companies that specialize in active control products, and the topic is widely studied in universities and government research laboratories. 2.4  Are there different kinds of active control? There are two basic approaches for active noise control: active noise cancellation (ANC) and active structural-acoustic control (ASAC). In ANC, the actuators are acoustic sources (speakers) which produce an out-of-phase signal to "cancel" the disturbance. Most people think of ANC when they think of active noise control; some examples are mentioned below. On the other hand, if the noise is caused by the vibration of a flexible structure, then ASAC may be more appropriate than ANC. In ASAC, the actuators are vibration sources (shakers, piezoceramic patches, etc.) which can modify how the structure vibrates, thereby altering the way it radiates noise. (ASAC is distinguished from ANC only in how it is applied, since in either case you have a controller using actuators to control the response of a plant.) Active vibration control is a related technique that resembles active noise control. In either case, electromechanical actuators control the response of an elastic medium. In active noise control, the elastic medium is air or water through which sound waves are traveling. In active vibration control, the elastic medium is a flexible structure such a satellite truss or a piece of vibrating machinery. The critical difference, however, is that active vibration control seeks to reduce vibration without regard to acoustics. Although vibration and noise are closely related, reducing vibration does not necessarily reduce noise. Actually, you can generate your own catchy phrases with the following handy buzzword generator. Simply choose one word from each column, string them all together without commas, and paste the result or its acronym into your document or conversation. / Column A    \    / Column B (optional) \    / Column C     \ | ----------- |    | ------------------- |    | ------------ | | active      |    | vibration           |    | cancellation | <  adaptive     >  <  noise                >  <  control       > | semi-active |    | sound               |    | damping      | | electronic  |    | structural-acoustic |    | suppression  | \             /    \ vibro-acoustic      /    \ isolation    / 2.5  Is active noise control like noise masking? Active noise control is quite different from noise masking. Acoustic masking is the practice of intentionally adding low-level background sounds to either make noises less distracting, or reduce the chance of overhearing conversations in adjoining rooms. In active noise control, the system seeks not to mask offending sound, but to eliminate it. Masking increases the overall noise level; active control decreases it -- at least, in some locations if not all. 2.6  How can adding sound make a system quieter? It may seem counter-intuitive to say that adding more sound to a system can reduce noise levels, but the method can and does work. Active noise control usually occurs by one, or sometimes both, of two physical mechanisms: "destructive interference" and "impedance coupling". Here is how they work: On one hand, you can say that the control system creates an inverse or "anti-noise" field that "cancels" the disturbance sound field. The principle is called "destructive interference." A sound wave is a moving series of compressions (high pressure) and rarefactions (low pressure). If the high-pressure part of one wave lines up with the low-pressure of another wave, the two waves interfere destructively and there is no more pressure fluctuation (no more sound). Note that the matching must occur in both space and time -- a tricky problem indeed. On the other hand, you can say that the control system changes the way the system "looks" to the disturbance, i.e., changes its input impedance. Consider the following analogy: Picture a spring-loaded door - one that opens a few centimeters when you push on it, but swings shut when you stop pushing. A person on the other side is repeatedly pushing on the door so that it repeatedly opens and closes at a low frequency, say, twice per second. Now suppose that whenever the other person pushes on the door, you push back just as hard. Your muscles are heating up from the exertion of pushing on the door, but end result is that the door moves less. Now, you could say that the door opens and that you "anti-open" it to "cancel" the opening. But that wouldn't be very realistic; at least, you would not actually see the door opening and anti-opening. You would be more accurate to say that you change the "input impedance" seen on the other side of the door: when the other person pushes, the door just doesn't open. (The spring-loaded door is supposed to represent the spring effect of compressing air in a sound wave. This is not a perfect analogy, but it helps illustrate impedance coupling.) In some cases, destructive interference and impedance coupling can be two sides of the same coin; in other cases destructive interference occurs without impedance coupling. The difference is related to whether the acoustic waves decay with distance traveled: Sound from a speaker hanging in the middle of a stadium decays (is less loud) at a distance because of "spherical spreading." As you get farther away, the sound energy is spread out over an increasingly large area. Go far enough away and, for all intents and purposes, the sound decays completely down to nothing. On the other hand, sound in a "waveguide" such as a duct can travel long distances without significant decay. There are many situations in which walls, ducts, buildings, roadways, or other surfaces can act as waveguides for sound. If a control system actuator is close to the disturbance source, destructive interference and impedance coupling can both occur. But what about when the actuator is far away from the disturbance, so far away that any wave it creates decays completely down to nothing before reaching the disturbance? There can still be destructive interference near the actuator, even though the actuator cannot possibly affect the impedance seen by the disturbance. Example: the tiny speaker in an active control headphone will not affect the impedance seen by a cannon firing a mile away, but it can create destructive interference within the headphone. In some cases, an active control system can actually absorb acoustic energy from a system. Of course, the amount of energy absorbed by the system is usually tiny compared to mechanical losses or other losses in the system, but absorption is one possible mechanism for active systems. 2.7  When does active control work best? Active noise control works best for sound fields that are spatially simple. The classic example is low-frequency sound waves traveling through a duct, an essentially one-dimensional problem. The spatial character of a sound field depends on wavelength, and therefore on frequency. Active control works best when the wavelength is long compared to the dimensions of its surroundings, i.e., low frequencies. Fortunately, as mentioned above, passive methods tend to work best at high frequencies. Most active noise control systems combine passive and active techniques to cover a range of frequencies. For example, many active mufflers include a low-back-pressure "glass-pack" muffler for mid and high frequencies, with active control used only for the lowest frequencies. Controlling a spatially complicated sound field is beyond today's technology. The sound field surrounding your house when the neighbor's kid plays his electric guitar is hopelessly complex because of the high frequencies involved and the complicated geometry of the house and its surroundings. On the other hand, it is somewhat easier to control noise in an enclosed space such as a vehicle cabin at low frequencies where the wavelength is similar to (or longer than) one or more of the cabin dimensions. Easier still is controlling low-frequency noise in a duct, where two dimensions of the enclosed space are small with respect to wavelength. The extreme case would be low-frequency noise in a small box, where the enclosed space appears small in all directions compared to the acoustic wavelength. Often, reducing noise in specific localized regions has the unwanted side effect of amplifying noise elsewhere. The system reduces noise locally rather than globally. Generally, one obtains global reductions only for simple sound fields where the primary mechanism is impedance coupling. As the sound field becomes more complicated, more actuators are needed to obtain global reductions. As frequency increases, sound fields quickly become so complicated that tens or hundreds of actuators would be required for global control. Directional cancellation, however, is possible even at fairly high frequencies if the actuators and control system can accurately match the phase of the disturbance. Aside from the spatial complexity of the disturbance field, the most important factor is whether or not the disturbance can be measured before it reaches the area where you want to reduce noise. If you can measure the disturbance early enough, for example with an "upstream" detection sensor in a duct, you can use the measurement to compute the actuator signal (feedforward control). If there is no way to measure an upstream disturbance signal, the actuator signal must be computed solely from error sensor measurements (feedback control). Under many circumstances feedback control is inherently less stable than feedforward control, and tends to be less effective at high frequencies. Bandwidth is also important. Broadband noise, that is, noise that contains a wide range of frequencies, is significantly harder to control than narrowband (tonal or periodic) noise or a tone plus harmonics (integer multiples of the original frequency). For example, the broadband noise of wind flowing over an aircraft fuselage is much more difficult to control than the tonal noise caused by the propellers moving past the fuselage at constant rotational speed. Finally, lightly damped systems are easier to control than heavily damped ones. (Note: Damping refers to how quickly the sound or vibration dies out. Damping should not be confused with "dampening", which happens when you throw water on something.) 2.8  What is adaptive active control? Adaptive control is a special type of active control. Usually the controller employs some sort of mathematical model of the plant dynamics, and possibly of the actuators and sensors. Unfortunately, the plant can change over time because of changes in temperature or other operating conditions. If the plant changes too much, controller performance suffers because the plant behaves differently from what the controller expects. An adaptive controller is one that monitors the plant and continually or periodically updates its internal model of the plant dynamics. 3. Applications of Active Noise Contro 3.1  What are some typical applications for active noise control? The most successful demonstrations of active control have been for controlling noise in enclosed spaces such as ducts, vehicle cabins, exhaust pipes, and headphones. Note, however, that successful demonstrations are many, but successful commercial products are few. One exception, active noise control headphones, has achieved widespread commercial success. Active headphones use destructive interference to cancel low-frequency noise while still allowing the wearer to hear mid- and high-frequency sounds such as conversation and warning sirens. The system comprises a pair of earmuffs containing speakers and one or more small circuit boards. Some include a built-in battery pack, and many allow exterior signal inputs such as music or voice communications. Used extensively by pilots, active headphones are considered indispensable in helicopters and noisy propeller-driven aircraft. Prices have dropped in recent years. (See Section 3.2 for information about an active control conversion kit available for US$100.) Passenger headsets, which lack the microphone boom found on pilots headsets, are even cheaper. Some sell for less than US$100, and are readily found in catalogs and specialty gift shops such as "Brookstone". Another application that has seen some commercial success is active mufflers for industrial engine exhaust stacks. Active control mufflers have seen years of service on commercial compressors, generators, and so forth. As unit prices for active automobile mufflers have fallen in recent years, several automobile manufacturers are now considering active mufflers for future production cars. However, if you ask your local new car dealer about the active muffler option on their latest model, you will likely receive a blank stare: no production automobiles feature active mufflers as of this writing. Large industrial fans have also benefited from active control. Speakers placed around the fan intake or outlet not only reduce low-frequency noise downstream and/or upstream, but they also improve efficiency to such an extent that they pay for themselves within a year or two. The idea of canceling low-frequency noise inside vehicle cabins has received much attention. Most major aircraft manufacturers are developing such systems, especially for noisy propeller-driven aircraft. Speakers in the wall panels can reduce noise generated as the propeller tips pass by the aircraft fuselage. For instance, a system by Noise Cancellation Technologies (NCT) now comes as standard equipment on the new Saab 2000 and 340B+ aircraft. The key advantage is a dramatic weight savings compared to passive treatments alone. Automobile manufacturers are considering active control for reducing low-frequency noise inside car interiors. The car stereo speakers superpose cancellation signals over the normal music signal to cancel muffler noise and other sounds. For example, Lotus produces such a system for sale to other automobile manufacturers. Unit cost is a major consideration for automobile use. While such systems are not at all common, at least one vehicle (currently offered only in Japan) includes such a system as a factory option. The following list of applications for active control of noise and vibration was compiled by Colin Hansen and is used by permission; see IS&VD 1(2). The list includes topics which are currently being investigated by research groups throughout the world. ---------- begin quote from C. Hansen, IS&VD 1(2) ---------- * Control of aircraft interior noise by use of lightweight vibration sources on the fuselage and acoustic sources inside the fuselage. * * Reduction of helicopter cabin noise by active vibration isolation of the rotor and gearbox from the cabin. * * Reduction of noise radiated by ships and submarines by active vibration isolation of interior mounted machinery (using active elements in parallel with passive elements) and active reduction of vibratory power transmission along the hull, using vibration actuators on the hull. * * Reduction of internal combustion engine exhaust noise by use of acoustic control sources at the exhaust outlet or by use of high intensity acoustic sources mounted on the exhaust pipe and radiating into the pipe at some distance from the exhaust outlet. * * Reduction of low frequency noise radiated by industrial noise sources such as vacuum pumps, forced air blowers, cooling towers and gas turbine exhausts, by use of acoustic control sources. * * Lightweight machinery enclosures with active control for low frequency noise reduction. * * Control of tonal noise radiated by turbo-machinery (including aircraft engines). * * Reduction of low frequency noise propagating in air conditioning systems by use of acoustic sources radiating into the duct airway. * * Reduction of electrical transformer noise either by using a secondary, perforated lightweight skin surrounding the transformer and driven by vibration sources or by attaching vibration sources directly to the transformer tank. Use of acoustic control sources for this purpose is also being investigated, but a large number of sources are required to obtain global control. * * Reduction of noise inside automobiles using acoustic sources inside the cabin and lightweight vibration actuators on the body panels. * * Active headsets and earmuffs. * ---------- end quote from C. Hansen, IS&VD 1(2) ---------- 3.2  Are all 'active headphones' the same? No. Two types are often called "active," but only one actually uses noise cancellation. For the sake of discussion, let's call the two types "active headphones" and "amplified earmuffs". Active headphones rely primarily on noise cancellation for low-frequency quieting. In some, the earmuffs themselves provide relatively little passive noise reduction. In others, the earmuffs provide as much passive reduction as possible, using noise cancellation to get even better performance at low frequencies. In any case, the unit includes a microphone inside each earcup to monitor the "error"-the part of the signal that has not been cancelled by the speakers. A pilot's headset also includes a microphone boom to transmit the pilots voice, and an input jack to transmit communication signals into the earcups. The noise cancellation works best on tones or periodic noise like that from an aircraft propeller. Some models, such as the NoiseBuster Extreme! from Noise Cancellation Technologies (www.nct-active.com/), retail for less than US$100. Amplified earmuffs are quite different, as they do not use noise cancellation at all. A heavy passive earmuff attenuates as much noise as possible. Microphones on the outside of the unit pick up sounds that would ordinarily be heard by the ears. These microphone signals are then filtered before being played by speakers inside the earcups. The most common filtering is to mute loud, impulsive sounds such as gunshots; amplified earmuffs are therefore becoming quite popular at weapons firing ranges. (Example: the Peltor Tactical 7-S) Amplified earmuffs have also been suggested for use by sufferers of tinnitus ("ringing of the ears"), a condition that can be aggravated by loud noises. But amplified earmuffs should not be confused with true active noise control headphones. Numerous microphone-based products, such as cell phones and computer microphones, use electronic cancellation methods to reduce background noise. 3.3  What are the benefits of active control? The many practical benefits of active control technology are not all obvious at first glance. The main payoff, of course, is low-frequency quieting that would be too expensive, inconvenient, impractical, or heavy by passive methods alone. For example, the lead-impregnated sheets used to reduce aircraft cabin propeller noise impose a severe weight penalty, but active control might perform as well with a much smaller weight penalty. Other possible benefits reflect the wide range of problems on which active control can be applied. For instance, with conventional car mufflers the engine spends extra energy to push exhaust gasses through the restrictive muffler passages. On the other hand, an active control muffler can perform as well with less severe flow restrictions, thus improving performance and/or efficiency. Additional benefits include: * increased material durability and fatigue life * * lower operating costs due to reduced facility down-time for installation and maintenance * * reduced operator fatigue and improved ergonomics * Of these, the potential for reduced maintenance and increased material fatigue life have received new emphasis in recent years. In the long-term, however, benefits may extend far beyond those mentioned above. The compact size and modularity of active systems can provide additional flexibility in product design, even to the point of a complete product redesign. 3.4  What was that short story by Arthur C. Clarke? Arthur C. Clarke's short story entitled "Silence Please" appeared in his 1954 collection "Tales from the White Hart" (reprinted in 1970 by Harcourt, Brace & World Inc., New York). In it, Harry Purvis recounts the tale of the ill-fated "Fenton Silencer," an anti-noise device that goes disastrously awry. In the tradition of Clarke's other works, the story itself is entertaining and well-told. Strictly speaking, however, the basic premise requires some poetic license regarding the physics of sound cancellation. Well-informed readers must rely on their "willing suspension of disbelief" to overlook the inconsistencies. [Of course, I say that with the benefit of over forty years' hindsight. CR] 3.5  How can I do a simple, inexpensive active control demo? Because active control employs some interesting physics, readers often ask how to construct a simple, low-cost demonstration as a student project or for instructional purposes. Here are five possibilities: Option 1: Noise cancellation demo The easiest way to do a limited demonstration of sound cancellation is to visit the following web site, maintained by the Vibration and Acoustics Laboratory at Virginia Tech in Blacksburg, Virginia: www.val.me.vt.edu From this site you can download a simple Windows-compatible program that conducts a demonstration of sound cancellation (which, in a narrow sense, is a form of active noise control.) All you need is a PC, a sound card, and two speakers. The program plays a "disturbance" sound from one speaker and a "control" sound from the other, and demonstrate that one speaker can cancel sound from the other. No fuss, no mess. Of course, you can demonstrate cancellation without the software if you have a stereo amplifier, two speakers, and a way to generate a send a pure-tone signal to the amplifier (such as a signal generator). First, play a pure tone through both speakers. Move the speakers close together and far apart; you'll notice no real change in the sound level. Then, cross-wire one of the speakers (i.e., swap the positive and negative wires). Move the speakers close together and you'll hear the sound level fall dramatically. Experiment with different frequencies to find what works best for your particular setup. Again, these setups only demonstrate that one sound wave can cancel another, and some would argue that this is not truly active noise control. Option 2: Build an analog feedback controller The opposite end of the spectrum: It is possible to construct a simple analog feedback controller using op-amps, capacitors, speakers, and other parts available from any electronics supplier. While simple in concept, constructing such a demonstration requires a pretty solid foundation in acoustics, electronics, and control theory. A basic outline is given below, but the details are well beyond the scope of this FAQ. Readers interested in further discussion are encouraged to contact Dr. Dexter Smith (discoveryengineering@compuserve.com) or visit the following web site: ourworld.compuserve.com/homepages/discoveryengineering/fanc1.htm A simple analog system for feedback active control consists of a microphone sensor, a loudspeaker actuator, and an equalizer to correct for the delay from the speaker to the microphone and for the transfer function of the speaker itself. The microphone is usually placed close to the speaker, since the system transfer function (from power amplifier to output of mic preamp) is increasingly difficult to equalize as the mic moves away from the speaker. (The phase change goes from gradual to rapid as frequency increases). A disturbance input at the sensor (low frequency acoustic noise) can be attenuated by the proper choice of equalization. The zone of silence around the sensor is approximately 1/10th of the wavelength of the noise to be attenuated. The system can be equalized by taking data into a sound card on a PC, determining the transfer function, and equalizing it with a biquad op-amp circuit using, for example, 4 op-amps. Option 3: Build Ostergaard's feedback vibration controller A technical brief published recently in the Journal of the Acoustical Society of America describes how to make a simple active control experiment using a tuning fork, a function generator, and some simple, inexpensive electronics components. The reference is: * Ostergaard, P.B., "A simple harmonic oscillator teaching apparatus with active velocity feedback," Journal of the Acoustical Society of America, Vol. 99, No. 2, February 1996. * Option 4: Buy an off-the-shelf active control module This approach is much more powerful and flexible than any of those mentioned above, but also much more expensive. Several are available; try looking here, for example: www.technofirst.com Option 5: Modify an active control headset This alternative is much less expensive, but not as flexible: the "ANR Adapter" from Headsets, Inc. The ANR Adapter is an add-on kit that transforms an ordinary passive pilot's headset into an active noise control headset. The kit costs only US$100; you supply the headset. The makers claim roughly 22 dB attenuation from 20 Hz to 700 Hz. If you simply want a demonstration in which you flip a power switch to hear active noise control at work, this kit may be for you. (See Section 4.2 for contact information. For a review of the product, see the following magazine article: Picou, Gary, "Low-Rent ANC," The Aviation Consumer, vol.25, No.7, MAY 01 1995, p.10-12.) 4. Finding More Information 4.1  What is the active control newsletter? In the late 1990’s, there was a monthly newsletter about active control called "Active Sound & Vibration Control News". It is no longer published. 4.2  What companies produce active control products? Some readers may wish to contact vendors for product literature. The following companies, LISTED IN ALPHABETICAL ORDER, produce active noise control products. No endorsement of any kind is implied by inclusion in this list, nor is this meant to be a complete list. There are many other companies that produce system components or are involved in active control research and development -- far too many to list here. The companies listed below are only companies that produce commercially available products intended specifically for active noise control. Please suggest others as appropriate. * ABS GmbH Jena, Wildenbruchstraße 15, 07745 Jena, Germany, Tel:  +49 3641 675400, Fax: +49 3641 675410, email nancy@abs-jena.de * * ANR Headsets, 2955 Fawn Drive, Burlington, KY 41005, mmorgan@anr-headsets.com, www.anr-headsets.com/ * * Active Vibration Control Instrumentation, PCB Piezotronics, Inc., 3425 Walden Ave. Depew, NY 14043-2495, phone 716-684-0001 * * BBN Physical Systems & Technologies, 70 Fawcett St, Cambridge, MA 02138, phone 617-873-3533, fax 617-873-2918, email fberkman@bbn.com (Dr. E. Frank Berkman, Technical Director). * * Causal Systems Pty Ltd., P.O. Box 100, Rundle Mall, South Australia 5000, Australia, phone 61.8.303.5460, fax 61.8.303.4367, e-mail colin.hansen@mecheng.adelaide.edu.au (Colin Hansen), www.causal.on.net/ * * Digisonix, Inc. [Editor's note: Digisonix is no longer in business.], 8401 Murphy Drive, Middleton, WI 53562-2243 USA, phone 608.836.3999, fax 608.836.5583, email: information@digisonix.com, Web www.mailbag.com/users/dgsnx_mr/ * * dSPACE Inc., 22260 Haggerty Road, Suite 120, Northville, MI 48167, phone 810.344.0096, fax 810.344.2060, email 75371.36@compuserve.com, Web www.ti.com (search for DSPACE once there). * * Headsets, Inc., 2330-B Lakeview, Amarillo, Texas 79109, USA, phone 806.358.6336, fax 806.358.6449, Paige Brittain, President. * * Noise Cancellation Technologies, Inc., Headquarters: Stamford, Connecticut, 203.961.0500 (Joanna Lipper). Engineering facilities: Linthicum, Maryland, USA, 410.636.8700, www.nct-active.com/ * * Peltor Inc., 41 Commercial Way, E. Providence, RI 02914, Phone: 401.438.4800, Fax: 401.434.1708 * * Walker Electronic Silencing, Inc. (formerly Walker Noise Cancellation Technologies), www.WESilence.com . * * Sennheiser Electronic Corporation & Neumann USA, 6 Vista Drive, P.O. Box 987, Old Lyme, CT 06371, TEL 860.434.9190, FAX: 860.434.1759, info@sennheiserusa.com, www.sennheiserusa.com/ * * Sennheiser electronic GmbH & Co. KG, D-30900 Wedemark, 106005.55@Compuserve.com, www.sennheiser.com/ * * Sennheiser (Canada) Inc., 221 Labrosse Avenue, Pointe-Claire, Quebec, Canada, H9R 1A3, TEL: 514.426.3013/800.463.1006, FAX: .514.426.3953/800.463.3013, info@sennheiser.ca, www.sennheiser.ca/ * * Technofirst, Parc Technologique et Industriel de Napollon, 399, Avenue des Templiers, 13676 Aubagne Cedex France, Tel(33) 4 42 03 46 60, Fax (33) 4 42 03 06 43, technof@technofirst.com, www.technofirst.com * * Ultra Electronics Ltd., www.ultraquiet.com . * * Also: Bose, David Clark, Sony, others * 4.3  What universities teach active noise control? Some readers may wish to contact universities regarding curricula that include active noise control. At this point, it is safe to say that ALL major engineering programs teach at least one course that discusses active noise control. The following schools, LISTED IN ALPHABETICAL ORDER, have reasonably extensive graduate research programs in active noise control. No endorsement of any kind is implied by inclusion in this list, nor is this meant to be a complete list. * Cork Institute of Technology, Ireland * * Delft University of Technology, Delft, Netherlands www.tudelft.nl/home.html * * Duke University, Durham, North Carolina, USA, Professor Robert Clark, Director, Center for Applied Control, 919-660-5435, rclark@egr.duke.edu, www.duke.edu * * Georgia Institute of Technology, Atlanta, Georgia, USA www.gatech.edu * * Norwegian University of Science and Technology, Trondheim, Norway www.ntnu.no * * Massachusettes Institute of Technology, Cambridge, Massachusetts, USA web.mit.edu * * Northern Illinois University, DeKalb, Illinois, USA www.niu.edu * * Old Dominion University, Norfolk, Virginia, USA www.odu.edu * * Pennsylvania State University: The Graduate Program in Acoustics, Penn State University, PO Box 30, State College, PA 16804, Phone (814) 865-6364, Fax (814) 865-3119 www.acs.psu.edu * * Purdue University, West Lafayette, Indiana, USA www.purdue.edu * * RWTH Aachen, Germany, www.itm.rwth-aachen.de * * Southampton University, Southampton, England www.soton.ac.uk * * Technical University of Denmark, Denmark www.dtu.dk/dtu/dtu.html * * Technical University of Berlin, Germany www.tk.tu-berlin.de * * Technical University of Erlangen, Germany * * Technical University of Munich, Germany * * Technical University of Stuttgart, Germany * * University of Adelaide, Adelaide, South Australia, Australia, www.mecheng.adelaide.edu.au/anvc * * University of Auckland, New Zealand, Prof Marshall, h.marshall@auckland.ac.nz, Dr. George Dodd g.dodd@auckland.ac.nz * * University of Goettingen, Germany * * University of Hamburg, Germany * * University of Karlskrona/Ronneby, Ronneby, Sweden www.hk-r.se/isb/isb_e.html * * University of London/Royal Holloway, Egham, Surrey, England www.ph.rhbnc.ac.uk * * University of Salford, England * * Universite de Sherbrooke, Sherbrooke, Quebec, Canada www.usherb.ca/index.html * * Universite de Technologie de Compiegne, Compiegne, France www.univ-compiegne.fr * * University of Utah, Salt Lake City, Utah, USA www.utah.edu/HTML_Docs/Campus_Info.html * * Villanova University, Philadelphia, Pennsylvania, USA www.vill.edu * * Virginia Polytechnic Institute & State University, Blacksburg, Virginia, USA www.vt.edu * 4.4  How can I learn more via the Internet? When this section was first assembled in 1994, it listed nearly every existing Web site that even mentioned ANC - all ten of them. Today, not only are there far too many ANC Web sites to list here, but modern Web search engines such as Google have made such lists largely obsolete. The abbreviated list below includes only a handful of the available sites. Inclusion in this list does not imply any sort of product endorsement, and there are many worthwhile sites not listed here. To find out more using a Web search engine, search for the phrase "active noise control". For an up-to-date list of links, try this page at NVHMaterials.com: * www.nvhmaterials.com/nvh/Active_Noise_Control/ * Another useful site is Virginia Tech's Vibration and Acoustics Laboratory, which includes a software program that can perform a simple active noise control demonstration using a PC: * www.val.me.vt.edu * Other excellent sites, such as the one maintained by Causal Systems Limited, contain plenty of technical detail for those who want more than this FAQ provides. These excellent resources may be found at: * www.causal.on.net/ * * www.mecheng.adelaide.edu.au/anvc/ * * www.execpc.com/~erikres * * www.technofirst.com * * www.lordcorp.com/nvx/NVX_Home.html * * www.signal.se/ * * helmholtz.ecn.purdue.edu/OtherPages/Bernhard.html * * www.acs.psu.edu/Acoustics.html * * web.mit.edu/org/a/avlab/www/vl.home.html * * www.yahoo.com/Science/Acoustics * * www.signalsystemscorp.com/smanc.html * Here are some other resources that deal with general acoustics and vibration topics: * The Acoustics FAQ: www.point-and-click.com/campanella_acoustics/faq/faq.htm * * If you have access to USENET newsgroups, check out the following: news:alt.sci.physics.acoustics (general acoustics) news:comp.dsp (digital signal processing) * * Check out the new home page of the Acoustical Society of America: asa.aip.org * * Penn State University has an excellent acoustics home page: www.acs.psu.edu * * MathTools.net is a math and physics resource that includes information on sound and speech processing:  www.mathtools.net/Applications/DSP/Sound_and_Speech_Processing/ * 4.5  Are there short courses about active control? This section formerly listed short courses that discuss active noise control. I removed the entire list because I cannot keep it current. 4.6  References from the general literature This section formerly contained references to articles from popular sources, i.e., non-technical magazines that you might find in a public library. I removed the entire list because I cannot keep it current. 4.7  References from the technical literature This section formerly contained references to textbooks and technical journal articles. I removed the entire list because I cannot keep it current. 4.8  Are there any bibliographies of active control articles? Dr. Dieter Guicking has compiled a comprehensive bibliography of patents on active control of sound and vibration. This database is available as a CD-ROM that also includes a 90-page report giving an overview of active control patents.  Pricing is surprisingly affordable. For details, follow this link:  www.guicking.de/software/index_en.html Copyright (c) 1994-2007 by Christopher E. Ruckman. All Rights Reserved. ------------- End of the Active Noise Control FAQ ------------