Sound Source Segregation 141amplitude modulated (unmodulated masker) is added simul-
taneously to the amplitude-modulated probe, there is only a
small change in the threshold for discriminating a change in
modulation depth. This is consistent with the critical-band
view of auditory processing in that the unmodulated masking
tone’s frequency is not near the carrier frequency of the probe.
If the masker is now amplitude modulated with the same am-
plitude modulation pattern (same rate of modulation) of the
probe, then threshold is increased to around 20% (a 15–16 dB
increase). The increase in modulation-depth threshold due to
the common pattern of modulation between the probe and
masker is referred to as modulation detection interference,
MDI, and typical results are shown in Figure 5.16.
One argument for why MDI occurs is that the probe and
masker are grouped together as a single sound source based on
the common pattern of amplitude modulation. Because the
common pattern of amplitude modulation is the basis of
the grouping, the auditory system has difficulty detecting
changes in modulation unless it affects the pattern of modula-
tion. Because changes in amplitude modulation depth of one
tone would have a small affect on the modulation pattern of the
mixture of the two tones, it is difficult for the auditory system
to detect changes in the depth of amplitude modulation for the
probe. One test of this argument is to make the pattern (rate) of
masker modulation different from that of the probe. In this
case, the masker and probe would not be grouped as a single
sound source, and MDI would be less or disappear. The data
shown in Figure 5.16 are consistent with this argument.Models or Theories of Sound Source SegregationOne key aspect of accounting for sound source segregation is
the recognition that such processing requires the auditory
system to process sound across a wide spectral range andFigure 5.15 Both the basic CMR task and results are shown. At the bottom the time-domain waveforms
for the narrow-band maskers (Target and Cue Bands) and the amplitude spectra for the maskers and the
signal are shown in a schematic form. The dotted line above each time-domain waveform depicts the am-
plitude envelope of the narrow-band noises. The listener is asked to detect a signal (S) which is always
added to the target band. In the target-band alone condition, the signal is difficult to detect. When a cue
band is added to the target band such that it is located in a different frequency region than the target band
and has an amplitude envelope that is different (not comodulated with) from the target band, there is little
change in threshold from the target-band alone condition. However, when the target and cue bands are co-
modulated, the threshold is lowered by approximately 12 dB, indicating that the comodulated condition
makes it easier for the listener to detect the signal. The waveforms are not drawn to scale. Source:From
Yost (2000), based on data from Hall et al. (1984), with permission.