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class:: LFDClipNoise
summary:: Dynamic clipped noise
related:: Classes/LFClipNoise, Classes/LFDNoise0, Classes/LFDNoise1, Classes/LFDNoise3, Classes/LFNoise0, Classes/LFNoise1, Classes/LFNoise2
categories:: UGens>Generators>Stochastic
Description::
Like link::Classes/LFClipNoise::, it generates the values -1 or +1 at a rate given
by the code::freq:: argument, with two differences:
list::
## no time quantization
## fast recovery from low freq values footnote::
link::Classes/LFClipNoise:: , as well as link::Classes/LFNoise0:: ,
link::Classes/LFNoise1:: and link::Classes/LFNoise2:: quantize to the
nearest integer division of the samplerate, and they poll the
code::freq:: argument only when scheduled; thus they often
seem to hang when freqs get very low.
::
::
If you don't need very high or very low freqs, or use fixed freqs,
link::Classes/LFDClipNoise:: is more efficient.
classmethods::
method::ar, kr
argument::freq
Approximate rate at which to generate random values.
argument::mul
Output will be multiplied by this value.
argument::add
This value will be added to the output.
Examples::
code::
// try wiggling the mouse quickly;
// LFNoise frequently seems stuck, LFDNoise changes smoothly.
{ LFClipNoise.ar(MouseX.kr(0.1, 1000, 1), 0.1) }.play
{ LFDClipNoise.ar(MouseX.kr(0.1, 1000, 1), 0.1) }.play
// silent for 2 secs before going up in freq
{ LFClipNoise.ar(XLine.kr(0.5, 10000, 3), 0.1) }.scope;
{ LFDClipNoise.ar(XLine.kr(0.5, 10000, 3), 0.1) }.scope;
// LFNoise quantizes time steps at high freqs, LFDNoise does not:
{ LFClipNoise.ar(XLine.kr(1000, 20000, 10), 0.1) }.scope;
{ LFDClipNoise.ar(XLine.kr(1000, 20000, 10), 0.1) }.scope;
::
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