Loudspeaker Enclosures 7251 kHz. The traditional, simplistic “ damping factor ” takes this ideal impedance at a nominal
point (say 100 Hz) and then describes attenuation against an 8-ohm resistor. This gives a
damping factor of about three orders, that is, 1000, but up to 10,000 at 30 Hz. Now look at
the middle curve of Figure 24.10. This is what the amplifi er’s damping ability is degraded
BDPFAZ3.CIR Temperature 27 Swr.dc.value 0.1
100101000m100m10m1m 10 100
v(Zo1) v(Zo3) v(Zo4)1 K 10 KA view of the damping surfaceWhat the 5" driverZobel look like
at the cabinet terminalsWhat the amplifier looks like at the speaker’s end (inc. cable & DCP cap)Series capacitor
Cable DC resSkin effectsNFB reductionWhat the amplifier looks like – at its output terminalsFrequency
Figure 24.10 : Views of the damping surface in 2D. The lower plot shows the very low steady-
state output source impedance of a typical transistor amplifi er with high NFB. The middle
plot shows how this degrades after passing down a few meters of reasonably rated cable
and a series capacitor (which might be the simplest crossover, or for fault protection). The
upper plot repeats the impedance versus frequency behavior of the 15 ” bass driver. The
effective damping factor is the smaller and highly variable difference between the upper and
the middle plots, not the difference between the highest impedance on the upper plot and
the lowest on the lower plot used by amplifi er makers!