Getting the Best from Your Loudspeakers

Because loudspeakers interact with the acoustics of the room in which they are used, optimizing their positions within that room pays major dividends. Inexpensive speakers, optimally set up, may well outperform more expensive models just plonked down willy-nilly.

Over the years, I have developed a library of test signals that make it easier to set up speakers by ear. I made this suite of signals available on my Editor's Choice Sampler & Test CD (Stereophile STPH016-2), released in July 2003. In this article, I suggest how these signals can best be used. (The CD, which also contains a selection of purist music recordings I made between 1998 and 2002, can be purchased online from this site's e-commerce page for $9.97 plus S&H.)

Note that I make no distinction between floorstanding "tower" speakers and so-called "bookshelf" designs—the worst place to put a bookshelf speaker is on a bookshelf. With very few exceptions, all loudspeakers work best out in the room, away from room boundaries. The only real difference between tower and bookshelf models is that the latter need to be placed on stands, though that does give you some extra flexibility when it comes to optimizing placement. Also note that in this article I have completely ignored the issue of domestic compatibility and bliss—if the optimal speaker positions conflict with the need for a harmonious relationship with your partner, I must leave that sort of resolution to you.

Triangles and Phase
Entire books have been written about the relationship between loudspeakers and room acoustics, but the starting point for any successful setup is to position the two speakers and your listening chair as the apices of an equilateral triangle; that is, the speakers are each as far away from you as they are from each other. The position of your chair is probably fixed, but to choose the starting points for the speaker positions, here's a tip I first heard from Stereophile founder J. Gordon Holt: while a friend is sitting in the listening chair talking, go to the spot you're thinking of placing your left speaker in, and kneel so that your ears are level with your friend's mouth. Where your friend's voice sounds most natural should be your initial position for that speaker; for now, just aim it at the listening position. Then place the right speaker to form the equilateral triangle mentioned earlier, again aimed at the listening position.

Next, you need to make sure that the speakers are wired correctly to your amplifier or receiver, with the left speaker receiving the left signal and the right speaker the right signal. In addition, the red (positive) terminal of your amplifier needs to be connected to the red (positive) terminal of the speaker; likewise for the black (negative) terminals. (It's easy to make a mistake.) When the wires are connected correctly, the speakers are "in phase," which means that the drive-unit diaphragms move in the same direction when fed the same signal. When one speaker is incorrectly wired—red to black instead of red to red—they are "out of phase"; ie, one is pushing while the other pulls.

Tracks 1 and 2 of Editor's Choice allow you to check that everything is hunky-dory in these respects, just by listening from your centrally placed chair. Using track 1 is self-explanatory: the sound of my Fender bass guitar should come from first the left channel, then the right. If this doesn't happen, the solution is obvious.

Using track 2 is a little more subtle: The first selection in track 2 was recorded out of phase. The image of the out-of-phase bass guitar should not be centered; in fact, it should generally be diffuse and vague, and it should be hard for you to point to where it's coming from, coupled perhaps with a "buzzing" sensation. In addition, the instrument should sound thin in the bass compared with how it sounded in track 1. The second selection in track 2 was recorded with the bass guitar in phase. You should now hear the image of the instrument occupying a very narrow space centered between the speakers, and the bass frequencies should sound full.

If you don't hear these clear distinctions between the in- and out-of-phase selections, or if the distinctions are consistently the opposite of what I've just described for each track, then one of the speakers has its connections reversed—the two speakers are out of phase. Invert the connection to one of your speakers and listen to track 2 again. Now you should clearly hear the difference between 1) the out-of-phase bass guitar and 2) the in-phase bass guitar.

Reflections and the Golden Ratio
Having determined that the speakers are correctly wired to the amplifier, you now need to adjust the speaker positions to give the smoothest bass performance, which in turn means adjusting the distances between the woofer(s) of each speaker and the three nearest room boundaries—floor, the nearest sidewall, and the wall behind the speaker—so that they are as different as possible.

Placing a speaker next to a surface—on the floor, or on a bookshelf next to a wall—boosts the bass at the expense of the lower midrange. Placing it next to two surfaces—on the floor next to a wall, or on a shelf in a corner—raises the bass level yet again, while the maximum bass boost is obtained by placing the speaker next to three surfaces; ie, in a corner.

What you need to arrange, therefore, is that the interactions between the sound coming from the woofer and its reflection from each boundary, which is what cause these boosts and dips in the response, occur at different frequencies. That way, they will be spread out across the bass region, with the maximum evenness. By contrast, the worst placement is when the woofer is the same distance from the floor, the sidewall, and the wall behind the speaker. The boosts and dips will then occur at the same frequency, and reinforce each other to give a lumpy, ill-defined low-frequency balance.

You don't need to listen yet. To get the largest differences between the distances of the woofer from the floor and walls, you can use the Golden Ratio, which is approximately 1.618:1. Measure the distance from the center of the woofer to the floor. Let's say it's 20". Multiplying that distance by the Golden Ratio gives a distance of 32"; multiplying that distance again by the Golden Ratio gives a distance of 52". So if you move each speaker to make the distance between its woofer and the sidewall 32", and that between the woofer and the wall behind the speaker 52" (or vice versa, doing the same for both speakers to keep the distances to the listening chair the same), you will, in theory at least, end up with the smoothest low-frequency performance.

This, however, will be for a perfect speaker; you can now try some slight adjustments to optimize the placement of your specific speakers.

Track 21 of Editor's Choice comprises a descending series of warble tones, each 1/3-octave wide and with center frequencies of first 200Hz, then 160, 125, 100, 80, 63, 50, 40, 31.5, 25, and 20Hz. The 200–100Hz bands can be considered the upper bass, 80–40Hz the midbass, and the remaining bands the low bass. If these bass warbles sound uneven, with some either sticking out more than others or missing in action, then try moving each of the speakers or your listening chair, perhaps by as little as 2" at a time. The object is to get the tones to sound as even as possible.

These tones can also give you an idea of your loudspeakers' subjective bass extension, either by listening to them or by using one of the inexpensive sound-level meters from RadioShack. Set a reference playback level with the 1kHz tone (track 20), then note either when you can't hear the warble tone anymore, or by how much the sound level drops with each successive tone.

Tone Bursts and Stethoscopes
Once you've fine-tuned the positions of your speakers (making sure that the distances of each to your listening chair are still the same), play track 19 of Editor's Choice, which features tone bursts tuned to the frequencies of the modern equal-temperament scale. The track sweeps up in half-steps from low C1 at 32.7Hz (on the space five ledger lines below the bass clef) to the high C8 at 4.186kHz (nine ledger lines above the treble clef), and back down again. The scale is played first in the right channel, then in the left; in each case, to aid identification of system resonant frequencies, the other channel features the octave C notes played on a PC synthesizer card set to its Timpani voice. Middle C, or C4—the note midway between the bass and treble clefs—is identified with a double note, as is the very highest C. The marker Cs have the following frequencies, in Hz: 32.7, 65.4, 130.8, 261.6 (middle C), 523.25, 1046.5, 2093, and 4186.

With small speakers, it's possible that you won't hear the lowest notes. Otherwise, the scale should sound even, without some notes sounding louder or softer than others. If you do hear something wrong, note where it stands in relation to the marker Cs mentioned above in the other channel. You'll then have a rough idea of the frequency range affected, and whether it's due to a room resonance (primarily 30–300Hz) or a speaker-cabinet resonance (100–500Hz).

Your initial setup should already have optimized the interaction between the speakers and the room acoustics, but in the case of vibrational resonances in the speaker cabinets, you can zero in on these by playing track 19 and listening to the cabinet walls with a stethoscope (about $20 from any pharmacy). You'll hear a cabinet resonance as an accentuation of the note. If the resonance is particularly severe when you pause the CD player while the affected note is playing, you might even hear it ringing on its own as a kind of echo.

If your speakers do have some resonant problems, there are a number of things you can do. If you have bookshelf speakers sitting on stands, sitting the speakers on small pads of Blu-Tack (the tacky material used to stick pictures to walls) works well to damp the speaker cabinets' resonant vibrations. If the cabinets have resonances that don't lie at the frequencies of musical notes, it's possible that they'll have less of a deleterious effect on music. You can adjust the frequency of the resonance by putting a plastic ziplock bag packed with dry sand atop each speaker. This won't look very elegant, but see my note above about domestic harmony.

If the speakers or stands are just sitting on the rug, try using carpet-piercing spikes to couple them more securely to the floor beneath. This narrows the frequency range affected by the resonance, which again will make it less likely to be fully excited by conventional music. (If you don't want your floorboards pierced by spikes, place a penny coin under each spike.)

Pink Noise and Stereo Imaging
Now, with the speakers set up for the smoothest low frequencies, the setup can be fine-tuned for the best stereo imaging, and for the most naturally balanced midrange and high frequencies.

Track 18 of Editor's Choice consists of what's called pink noise: random noise with equal energy per musical octave, recorded in dual-mono (the left and right channels are fed identical signals), Pink noise ideally sounds like absolutely smooth rushing water, with no band of frequencies sticking out any more than any other. It should not sound hollow or colored in any way, and neither its level nor its tonal character should noticeably change from speaker to speaker. The image of the noise should appear to come from a narrow point midway between the speakers. If the sound "splashes" to the sides at some frequencies, or if the image is broadened at all frequencies, then there is something suspect in your system.

If the sound of track 18 fails to meet these criteria, then try sitting higher or lower, closer or farther away, or moving nearby furniture. If there's a coffee table between you and the speakers, for example, the reflections of the sound from its surface will interfere both with the smoothness of the pink noise and the stability of the stereo imaging. Get rid of it—remembering my note about domestic harmony, of course.

Try experimenting with the degree of speaker toe-in. So far, the speakers have been aimed directly at your listening position. Now try aiming them straight ahead, so you can see the inside side panel of each. Then try aiming them so that their axes cross in front of you. As Stereophile Editor-at-Large Art Dudley wrote in the 2007 Stereophile Buyer's Guide, "In a general sense, aiming your speakers directly at a central listening seat will provide the greatest perceived brightness—from which some designs will surely benefit. Quite often, you may find that a gentle degree of toe-in gives a good compromise between realistic high-frequency extension and the kind of spatial performance on stereo recordings that provides both good 'stage' size and image localization."

Finally, if all setup has been done with the speakers' grilles in place, try removing them. Them get yourself a glass of your favorite tipple, select one of your favorite recordings, settle back in your chair, and allow the sound of your system to transport you to that special place.

Happy Listening!

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ratfink454's picture

I love this article and will be using the principles and the CD to set up my speakers but I have a dumb question I need answered before I get started.  For the purpose of calculating the Golden ratio, by "woofer" I assume you mean the largest driver in the cabinet.  Some companies call the speaker just larger than the tweeter a woofer, especially if it is over 6" in diameter.  So am I correct in assuming the "woofer is the largest driver.

Also, I have a floor-standing speaker that has a vertical array of 3 of these largest drivers towards the bottom of the cabinet.  WHere do I measure from - the center of the middle one?

Thanks for any help you can give.  Since starting to read Stereophile, the little adjustments made so far have opened up a whole new world of music.  I hear a broad and deep sound stage with seperate instruments and voices coming from well in front of and behind the speakers and they extend well beyond the width of the speakers as well.



John Atkinson's picture

ratfink454 wrote:
am I correct in assuming the "woofer is the largest driver.

Yes, the largest driver is the woofer and you measure distances from the center of its dust cap.

ratfink454 wrote:
I have a floor-standing speaker that has a vertical array of 3 of these largest drivers towards the bottom of the cabinet.  WHere do I measure from - the center of the middle one?

If your speakers have more than one woofer, it gets complicated, as each of the woofers will be a different height from the floor. Start by measuring from the dustcap of the midpoint of the woofer array but be prepared to experiment more than usual with positioning to get the smoothest response through the upper bass and lower midrange.

If you have a large tower speaker with widely spaced woofers, one at the top and one at the  bottom, like the old Dunlavys - see, for example, - then it is possible that you will not be able to find a position that is optimal for both of the woofers

John Atkinson

Editor, Stereophile

allanb's picture


Interesting article: it leaves me with a couple of questions. 

I have speakers which I think are quite good (KEF Concerto Two) but my room is large and rather irregular; for example, on one side there is not really a side wall, rather an open space with a staircase going up from it.  In addition, the floor is tiled and the walls are also hard (stone and plaster).  I have been suffering from some form of mild echo or resonance, apparently provoked by bass notes.  Speaker placement may be the only significant thing that I can change.

I have tried to make use of one of the "rules" you suggest, concerning the ratio of about 1.6 between the woofer and various surfaces.   The distance from the floor to the midpoint of the woofer (actually, the half-way point between two identical units) is 68 cm.  In accordance with your example, it would be good to have a distance of about 110 cm between that point and the rear wall (which isn't practicable), but it seems to me from your article that in theory it would work just as well to make that distance about 42 cm, i.e. reversing the ratio.  Question one: does this make sense?

Anyway, I tried it and couldn't detect any improvement.  However, if I then change the angle of the speakers so that their centre lines are at about 45º from the wall, the resonance (if that's what it is) appears to go away.  

Of course, if it works, I should be happy, and so I am.  But it would be interesting to know whether there is any theoretical basis for the result, hence question two: can the angle of the speaker affect echo or resonance from the rear wall?  

Incidentally, the speaker centre lines now intersect well forward of the listening position, but I'm not aware of losing anything as a result.

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