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Optimum Home Theater Room Dimensions
July 2002
Sound is the propagation of energy that occurs
longitudinally among air molecules. When a sound generator, for example,
a speaker driver, pushes air molecules nearby, local molecules push
other molecules and the resultant wave of excitation travels throughout
airspace. You are probably familiar with sound waves being compared
visually to ocean waves. This is done for pedagogical purposes. The
reason for this is that water waves are easy to visualize, and represent
a similar phenomena. It's just that water waves are lateral in nature
and sound is air molecules excited in longitudinal form. The both of
them propagate with similar effects.
For the
purposes of analysis, professional acousticians divide up the sonic
behavior of listening rooms into four characteristic intervals. Each
interval is characterized by a frequency range of sound. As it turns
out, the physical dimensions of a listening room has the profoundest
effect on the behavior of the lowest frequency range, the one that bass
notes (200 hz and lower) occupy. The behavior of this interval, in
acoustic terms, is dominated by "standing wave resonance
effects".
Standing waves are the phenomena that
results when waves in an elastic medium, such as air, travel back and
forth within an enclosure. At certain critical frequencies, the waves
traveling in one direction combine with those bouncing back, with the
result that some areas multiply in strength and others actually cancel
out. In our diagram, we show low frequency sound waves being generated
by a speaker bouncing back and forth in a tubular enclosure. As you can
see, the energy in the sound is actually a pressure wave and the
combination of the waves traveling in opposite directions yields high
pressure zones and low pressure zones. If you were to step inside this
tube and walk to the areas of low pressure, you would actually hear the
sound disappear. At other points, the sound would sound twice as loud as
normal!
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A home
theater room behaves much the same way as our "resonance tube" but with
the added complexity of more dimensions. Instead of just two surfaces, we
have six (four walls, the floor and the ceiling). Sound waves can, and
will, bounce off not only just two surfaces (axial modes), but four
surfaces, (tangential modes) and even all six (oblique modes) at once. A
complete analysis of the sound field in a room must account for all these
mode interactions to understand the resultant pattern of high pressure and
cancellations. Our diagram shows the simple combination of sound energy of
two axial modes into tangential mode form. As you can see, complex
disturbances in the room's sound field emerge. This is exactly what we
want to avoid in a well designed home theater room.
As it turns
out, if you design a listening room with exactly the right dimensions, you
can spread out the high and low pressure areas so that anoptimum sound
field is obtained. Roy Allison, founder of RA labs and Allison Acoustics,
has written extensively on this, and in his paper "The Loudspeaker/Room
System" he examines some of the "golden room ratios" developed by
researchers L. Louden and L.W. Sepmeyer. These golden room ratios are the
result of calculating the modal distributions created by low frequency
sound waves, and striving for the most uniform distribution. L.W.
Sepmeyer's ratios, in particular, have been highly utilized. Our table
illustrates the three famous Sepmeyer room ratios that have formed the
basis for hundreds of listening room designs over the last 30
years.
It should be noted that if you are starting from scratch in
a home theater room project, it isn't absolutely necessary to design your
room around these golden ratios. Often these golden ratios may not fit
one's aesthetic needs or other constraints. Other options concern
modifying the sonic behavior of the room with acoustical treatments. This
is especially true in existing rooms. The general principle is to tame low
frequency behavior by disturbing standing wave formation with either
physical obstructions (furniture, bookcases, etc) or via absorbing objects
(furniture, tube traps, etc). However, having a good understanding of the
effect that room dimensions can have on the distribution of resonance
modes can provide you with a starting point if you are designing from
scratch. |
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Sepmeyer's 3 Golden
Room Ratios |
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Room Type |
Ceiling Height |
Room
Width |
Room
Hight |
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Room 1 |
C |
1.14C |
1.39C |
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Room 2 |
C |
1.28C |
1.54C |
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Room 3 |
C |
1.60C |
2.33C |
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