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I agree - wideband.  To get the pitch frequency, I think you have to figure out the distance between the straitions.  If the whole segment is ~2sec long, the little crosses delineate 0.1sec segments, and I counted up 12 straitions between them in the middle of the segment, making the pitch period <math>\frac{0.1}{12} = 8.333</math>msec.  I could be way off though.  --[[User:Cg49me|cg49me]] 22:31, 16 April 2009 (UTC)
 
I agree - wideband.  To get the pitch frequency, I think you have to figure out the distance between the straitions.  If the whole segment is ~2sec long, the little crosses delineate 0.1sec segments, and I counted up 12 straitions between them in the middle of the segment, making the pitch period <math>\frac{0.1}{12} = 8.333</math>msec.  I could be way off though.  --[[User:Cg49me|cg49me]] 22:31, 16 April 2009 (UTC)
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What Cg49me said is right I think. I got the 9.5ms which is closed to 8.33ms. In the part (c), there is no exact answer.
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In part(d) I got 2000Hz-2900Hz. Is it right?--[[User:Kim415|Kim415]] 11:54, 20 April 2009 (UTC)

Latest revision as of 06:54, 20 April 2009

I got wideband for the first part. I can't figure out part (c) though. Anyone know how to do that? -vhsieh

I agree - wideband. To get the pitch frequency, I think you have to figure out the distance between the straitions. If the whole segment is ~2sec long, the little crosses delineate 0.1sec segments, and I counted up 12 straitions between them in the middle of the segment, making the pitch period $ \frac{0.1}{12} = 8.333 $msec. I could be way off though. --cg49me 22:31, 16 April 2009 (UTC)


What Cg49me said is right I think. I got the 9.5ms which is closed to 8.33ms. In the part (c), there is no exact answer. In part(d) I got 2000Hz-2900Hz. Is it right?--Kim415 11:54, 20 April 2009 (UTC)

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