Engineering Acoustics. Malcolm J. Crocker

Notice that the Sabine reverberation time formula T₆₀ = 0.16 V/S still predicts a reverberation time as → 1, which does not agree with the physical world. This is approximately the case of an anechoic room (see Figure 3.22). Some improved formulas have been devised by Eyring and Millington‐Sette that overcome this problem. Sabine's formula is acceptable, provided ≤ 0.5.

      Example 3.14

      A classroom has dimensions 4 × 6 × 10 m³ and a reverberation time of 1.5 seconds. (a) Determine the total sound absorption of the classroom; (b) if 35 students are in the classroom, and each is equivalent to 0.45 sabins (m²) sound absorption, what is the new reverberation time of the classroom?

      Solution

Figure 3.22 Sound source in anechoic room.

3.15 Room Equation

      If we have a diffuse sound field (the same sound energy at any point in the room) and the field is also reverberant (the sound waves may come from any direction, with equal probability), then the sound intensity striking the wall of the room is found by integrating the plane wave intensity over all angles θ, 0 < θ < 90°. This involves a weighting of each wave by cos θ, and the average intensity for the wall in a reverberant field becomes

      (3.75)

      Note the factor 1/4 compared with the plane wave case.

      For a point in a room at distance r from a source of power W watts, we will have a direct field intensity contribution W/4πr² from an omnidirectional source to the mean square pressure and also a reverberant contribution.

      We may define the reverberant field as the field created by waves after the first reflection of direct waves from the source. Thus the energy/second absorbed at the first reflection of waves from the source of sound power W is W , where is the average absorption coefficient of the walls. The power thus supplied to the reverberant field is W(1 −) (after the first reflection). Since the power lost by the reverberant field must equal the power supplied to it for steady‐state conditions, then

      (3.76)

      where p²_rms is the mean‐square sound pressure contribution caused by the reverberant field.

      There is also the direct field contribution to be accounted for. If the source is a broadband noise source, these two contributions: (i) the direct term p²_d,rms = ρcW/4πr² and (ii) the reverberant contribution, . So,

(3.77)

      and after dividing by p²_ref, and W_ref and taking 10 log, we obtain

(3.78)

      where R is the so‐called room constant .

      3.15.1 Critical Distance

      The critical distance r_c (or sometimes called the reverberation radius) is defined as the distance from the sound source where the direct field and reverberant field contributions to p²_rms are equal:

      (3.79)

      thus,

      (3.80)

Figure 3.23 gives a plot of Eq. (3.78) (the so‐called room equation).