Table 3.2 Simple source near reflecting surfacesa.
| Intensity | Source | Condition | Number of Images |
|
Power | D | DI |
|---|---|---|---|---|---|---|---|
| I |
|
Free field | None |
|
W | 1 | 0 dB |
| 4 I |
|
Reflecting plane | 1 |
|
2W | 4 | 6 dB |
| 16 I |
|
Wall‐floor intersection | 3 |
|
4W | 16 | 12 dB |
| 64 I |
|
Room corner | 7 |
|
8W | 64 | 18 dB |
a Q and DI are defined in Eqs. (3.53), (3.58), and (3.60).
3.9 Directivity
The sound intensity radiated by a dipole is seen to depend on cos2 θ (see Figure 3.11). Most real sources of sound become directional at high frequency, although some are almost omnidirectional at low frequency. This phenomenon depends on the source dimension, d, which must be small in size compared with a wavelength λ, so d/λ ≪ 1 for them to behave almost omnidirectionally.
Figure 3.11 Polar directivity plots for the radial sound intensity in the far field of (a) monopole, (b) dipole, and (c) (lateral) quadrupole.
3.9.1 Directivity Factor (Q(θ, ϕ))
In general, a directivity factor Qθ,ϕ may be defined as the ratio of the radial intensity 〈Iθ, ϕ〉t (at angles θ and ϕ and distance r from the source) to the radial intensity 〈Is〉t at the same distance r radiated from an omnidirectional source of the same total sound power (Figure 3.12). Thus
Figure 3.12 Geometry used in derivation of directivity factor.
For a directional source, the mean square sound pressure measured at distance r and angles θ and ϕ is p2rms (θ,ϕ).
In the far field of this source (r ≫ λ), then
(3.54)
But if the source were omnidirectional of the same power W, then
(3.55)
where p2rms is a constant, independent of angles θ and ϕ.
We may therefore write:
(3.56)
and
(3.57)
where
We define the directivity factor Q as
the ratio of the mean‐square sound pressure at distance r to the space‐averaged mean‐square pressure at r, or equivalently the directivity Q may be defined as the ratio of the mean‐square sound