|This module corresponds to section 3.4 (Attenuation By Distance) of the
OpenAL Specification and Reference (version 1.1).
Samples usually use the entire dynamic range of the chosen format/encoding,
independent of their real world intensity. In other words, a jet engine and a
clockwork both will have samples with full amplitude. The application will
then have to adjust source gain accordingly to account for relative
Source gain is then attenuated by distance. The effective attenuation of a
source depends on many factors, among which distance attenuation and source
and listener gain are only some of the contributing factors. Even if the
source and listener gain exceed 1 (amplification beyond the guaranteed
dynamic range), distance and other attenuation might ultimately limit the
overall gain to a value below 1.
|Handling the Distance Model
OpenAL currently supports six modes of operation with respect to distance
attenuation, including one that is similar to the IASIG I3DL2 model. The
application chooses one of these models (or chooses to disable
distance-dependent attenuation) on a per-context basis.
The distance used in the formulas for the "clamped" modes below is clamped
to be in the range between referenceDistance and maxDistance:
clamped distance =
max(referenceDistance, min(distance, maxDistance))
The linear models are not physically realistic, but do allow full attenuation
of a source beyond a specified distance. The OpenAL implementation is still
free to apply any range clamping as necessary.
With all the distance models, if the formula can not be evaluated then the
source will not be attenuated. For example, if a linear model is being used
with referenceDistance equal to maxDistance, then the gain equation will
have a divide-by-zero error in it. In this case, there is no attenuation for
|NoAttenuation||Bypass all distance attenuation calculation for all sources. The
implementation is expected to optimize this situation.
Inverse distance rolloff model, which is equivalent to the IASIG I3DL2
model with the exception that referenceDistance does not imply any
gain = referenceDistance / (referenceDistance +
rolloffFactor * (distance - referenceDistance))
The referenceDistance parameter used here is a per-source attribute
which is the distance at which the listener will experience gain
(unless the implementation had to clamp effective gain to the available
dynamic range). rolloffFactor is per-source parameter the application
can use to increase or decrease the range of a source by decreasing or
increasing the attenuation, respectively. The default value is 1. The
implementation is free to optimize for a rolloffFactor value of 0,
which indicates that the application does not wish any distance
attenuation on the respective source.
|InverseDistanceClamped||Inverse Distance clamped model, which is essentially the inverse
distance rolloff model, extended to guarantee that for distances below
referenceDistance, gain is clamped. This mode is equivalent to the
IASIG I3DL2 distance model.
Linear distance rolloff model, modeling a linear dropoff in gain as
distance increases between the source and listener.
gain = (1 - rolloffFactor * (distance - referenceDistance) /
(maxDistance - referenceDistance))
|LinearDistanceClamped||Linear Distance clamped model, which is the linear model, extended to
guarantee that for distances below referenceDistance, gain is clamped.
Exponential distance rolloff model, modeling an exponential dropoff in
gain as distance increases between the source and listener.
gain = (distance / referenceDistance) ** (- rolloffFactor)
|ExponentDistanceClamped||Exponential Distance clamped model, which is the exponential model,
extended to guarantee that for distances below referenceDistance,
gain is clamped.
|Contains the current per-context distance model.
|Evaluation of Gain/Attenuation Related State
While amplification/attenuation commute (multiplication of scaling factors),
clamping operations do not. The order in which various gain related
operations are applied is:
1. Distance attenuation is calculated first, including minimum
(referenceDistance) and maximum (maxDistance) thresholds.
2. The result is then multiplied by source gain.
3. If the source is directional (the inner cone angle is less than the outer
cone angle, see coneAngles), an angle-dependent attenuation is calculated
depending on coneOuterGain, and multiplied with the distance-dependent
attenuation. The resulting attenuation factor for the given angle and
distance between listener and source is multiplied with sourceGain.
4. The effective gain computed this way is compared against gainBounds.
5. The result is guaranteed to be clamped to gainBounds, and subsequently
multiplied by listener gain which serves as an overall volume control.
The implementation is free to clamp listener gain if necessary due to
hardware or implementation constraints.
|No Culling By Distance
With the DS3D compatible inverse clamped distance model, OpenAL provides a
per-source maxDistance attribute that can be used to define a distance
beyond which the source will not be further attenuated by distance. The DS3D
distance attenuation model and its clamping of volume is also extended by a
mechanism to cull (mute) sources from processing, based on distance. However,
the OpenAL does not support culling a source from processing based on a
At this time OpenAL is not meant to support culling at all. Culling based on
distance, or bounding volumes, or other criteria, is best left to the
application. For example, the application might employ sophisticated
techniques to determine whether sources are audible that are beyond the scope
of OpenAL. In particular, rule based culling inevitably introduces acoustic
artifacts. E.g. if the listener-source distance is nearly equal to the culling
threshold distance, but varies above and below, there will be popping
artifacts in the absence of hysteresis.
|Produced by Haddock version 2.4.2|