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Possible Duplicate:
Algorithm to determine fundamental frequency from potential harmonics

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I am back to figuring out fundamental frequency from a set of harmonics, some of which are missing.

What I am doing is looking at the Gap between adjacent harmonics. I will get a set of numbers, something like:

pH(1): (1,2) -> 107.410568
pH(2): (2,3) -> 111.918732
pH(3): (3,4) -> 219.100800
pH(4): (4,5) -> 106.097473
pH(5): (5,6) -> 113.122009
pH(6): (6,7) -> 112.224731
pH(7): (7,8) -> 124.215942

from this I need to calculate a fundamental. In this case, ~110.

there is an added problem that sometimes one particular harmonic will be way out, for example:

pH(1): (1,2) -> 107.376312
pH(2): (2,3) -> 135.100433
pH(3): (3,4) -> 86.590515
pH(4): (4,5) -> 111.350891
pH(5): (5,6) -> 110.659119
pH(6): (6,7) -> 111.361755
pH(7): (7,8) -> 108.807129

here, obviously harmonic number three is much closer to 4 than it is to 2. but 135+86 = 221 = 2x110.5

can anyone suggest an algorithm?

Here is a more complete data dump:

Analysing Frame: 4!
(Peak[0].power=496.263458, .freq=209.053009 
(Peak[1].power=60.337341, .freq=306.794373 
(Peak[2].power=46.169617, .freq=457.628998 
(Peak[3].power=10.675227, .freq=576.183167 
(Peak[4].power=8.550637, .freq=752.681885 
(Peak[5].power=3.088022, .freq=840.088318 
(Peak[6].power=4.913011, .freq=1044.712402 
(Peak[7].power=1.566417, .freq=1201.859741 
(Peak[8].power=1.343318, .freq=1350.521240 
(Peak[9].power=7.540891, .freq=1600.914307 
      Harmonic PeakPair: (0,1)=2/3, error:0.01474 => f0 @ 103.395645
      Harmonic PeakPair: (0,2)=1/2, error:0.04318 => f0 @ 218.933746
      Harmonic PeakPair: (0,3)=1/3, error:0.02949 => f0 @ 200.557037
      Harmonic PeakPair: (0,4)=1/4, error:0.02774 => f0 @ 198.611740
      Harmonic PeakPair: (0,5)=1/4, error:0.00115 => f0 @ 209.537537
      Harmonic PeakPair: (0,6)=1/4, error:0.04989 => f0 @ 235.115555
      Harmonic PeakPair: (0,7)=1/5, error:0.02606 => f0 @ 224.712479
      Harmonic PeakPair: (0,8)=1/5, error:0.04521 => f0 @ 239.578629
      Harmonic PeakPair: (0,9)=1/6, error:0.03608 => f0 @ 237.936035
      Harmonic PeakPair: (0,10)=1/7, error:0.03643 => f0 @ 244.831329
pH(1): (1,2) -> 150.834625
pH(2): (2,3) -> 118.554169
pH(3): (3,4) -> 176.498718
pH(4): (4,5) -> 87.406433
pH(5): (5,6) -> 204.624084
pH(6): (6,7) -> 157.147339
pH(7): (7,8) -> 148.661499
pH(8): (8,9) -> 250.393066
pH(9): (9,10) -> 363.353149
 ~
Analysing Frame: 5!
(Peak[0].power=323.802490, .freq=107.108635 
(Peak[1].power=156.096497, .freq=212.943176 
(Peak[2].power=65.058685, .freq=327.891602 
(Peak[3].power=55.066936, .freq=443.307678 
(Peak[4].power=11.969029, .freq=662.717896 
(Peak[5].power=12.774710, .freq=771.691284 
(Peak[6].power=3.965956, .freq=991.746338 
(Peak[7].power=1.290497, .freq=1218.169434 
(Peak[8].power=1.384800, .freq=1428.509766 
(Peak[9].power=6.819193, .freq=1651.377319 
      Harmonic PeakPair: (0,1)=1/2, error:0.00299 => f0 @ 106.790115
      Harmonic PeakPair: (0,2)=1/3, error:0.00667 => f0 @ 108.202919
      Harmonic PeakPair: (0,3)=1/4, error:0.00839 => f0 @ 108.967773
      Harmonic PeakPair: (0,4)=1/5, error:0.03838 => f0 @ 119.826111
      Harmonic PeakPair: (0,5)=1/6, error:0.02787 => f0 @ 117.861923
      Harmonic PeakPair: (0,6)=1/7, error:0.03486 => f0 @ 124.393341
pH(1): (1,2) -> 114.948425
pH(2): (2,3) -> 115.416077
pH(3): (3,4) -> 219.410217
pH(4): (4,5) -> 108.973389
pH(5): (5,6) -> 220.055054
(gdb) continue
 ~
Analysing Frame: 6!
(Peak[0].power=351.608368, .freq=106.752106 
(Peak[1].power=115.021736, .freq=226.598923 
(Peak[2].power=71.564438, .freq=332.445831 
(Peak[3].power=45.963409, .freq=441.119476 
(Peak[4].power=10.906013, .freq=660.755127 
(Peak[5].power=7.464951, .freq=768.980408 
(Peak[6].power=6.169244, .freq=881.256714 
(Peak[7].power=3.427589, .freq=987.147461 
(Peak[8].power=1.140599, .freq=1214.196167 
(Peak[9].power=1.282757, .freq=1426.420532 
      Harmonic PeakPair: (0,1)=1/2, error:0.02889 => f0 @ 110.025787
      Harmonic PeakPair: (0,2)=1/3, error:0.01222 => f0 @ 108.783691
      Harmonic PeakPair: (0,3)=1/4, error:0.00800 => f0 @ 108.515991
      Harmonic PeakPair: (0,4)=1/5, error:0.03844 => f0 @ 119.451569
      Harmonic PeakPair: (0,5)=1/6, error:0.02784 => f0 @ 117.457756
      Harmonic PeakPair: (0,6)=1/6, error:0.04553 => f0 @ 126.814110
      Harmonic PeakPair: (0,7)=1/7, error:0.03472 => f0 @ 123.886589
pH(1): (1,2) -> 105.846909
pH(2): (2,3) -> 108.673645
pH(3): (3,4) -> 219.635651
pH(4): (4,5) -> 108.225281
pH(5): (5,6) -> 112.276306
pH(6): (6,7) -> 105.890747
(gdb) continue
 ~
Analysing Frame: 7!
(Peak[0].power=441.757996, .freq=109.572845 
(Peak[1].power=75.059662, .freq=333.819489 
(Peak[2].power=44.463955, .freq=439.749634 
(Peak[3].power=10.445498, .freq=658.419373 
(Peak[4].power=7.832435, .freq=773.341919 
(Peak[5].power=6.903655, .freq=876.133972 
(Peak[6].power=3.478840, .freq=988.908691 
(Peak[7].power=0.862488, .freq=1213.805176 
(Peak[8].power=0.325413, .freq=1321.078613 
(Peak[9].power=1.074599, .freq=1428.187744 
      Harmonic PeakPair: (0,1)=1/3, error:0.00509 => f0 @ 110.423004
      Harmonic PeakPair: (0,2)=1/4, error:0.00083 => f0 @ 109.755127
      Harmonic PeakPair: (0,3)=1/5, error:0.03358 => f0 @ 120.628357
      Harmonic PeakPair: (0,4)=1/6, error:0.02498 => f0 @ 119.231583
      Harmonic PeakPair: (0,5)=1/6, error:0.04160 => f0 @ 127.797585
      Harmonic PeakPair: (0,6)=1/7, error:0.03206 => f0 @ 125.422760
pH(1): (1,2) -> 105.930145
pH(2): (2,3) -> 218.669739
pH(3): (3,4) -> 114.922546
pH(4): (4,5) -> 102.792053
pH(5): (5,6) -> 112.774719
(gdb) continue
 ~
Analysing Frame: 8!
(Peak[0].power=329.370514, .freq=107.008003 
(Peak[1].power=121.794647, .freq=216.109497 
(Peak[2].power=95.227448, .freq=330.530731 
(Peak[3].power=51.529533, .freq=441.920685 
(Peak[4].power=10.398799, .freq=660.634460 
(Peak[5].power=8.171947, .freq=771.948364 
(Peak[6].power=7.004751, .freq=883.576904 
(Peak[7].power=3.711878, .freq=991.915100 
(Peak[8].power=1.043736, .freq=1212.797363 
(Peak[9].power=0.866450, .freq=1425.700073 
      Harmonic PeakPair: (0,1)=1/2, error:0.00484 => f0 @ 107.531372
      Harmonic PeakPair: (0,2)=1/3, error:0.00959 => f0 @ 108.592453
      Harmonic PeakPair: (0,3)=1/4, error:0.00786 => f0 @ 108.744087
      Harmonic PeakPair: (0,4)=1/5, error:0.03802 => f0 @ 119.567444
      Harmonic PeakPair: (0,5)=1/6, error:0.02805 => f0 @ 117.833038
      Harmonic PeakPair: (0,6)=1/6, error:0.04556 => f0 @ 127.135406
      Harmonic PeakPair: (0,7)=1/7, error:0.03498 => f0 @ 124.355087
pH(1): (1,2) -> 114.421234
pH(2): (2,3) -> 111.389954
pH(3): (3,4) -> 218.713776
pH(4): (4,5) -> 111.313904
pH(5): (5,6) -> 111.628540
pH(6): (6,7) -> 108.338196
(gdb) continue
 ~
Analysing Frame: 9!
(Peak[0].power=323.231262, .freq=110.575546 
(Peak[1].power=125.892311, .freq=216.045319 
(Peak[2].power=144.429672, .freq=329.892181 
(Peak[3].power=11.046881, .freq=658.773499 
(Peak[4].power=8.210341, .freq=768.891541 
(Peak[5].power=6.895733, .freq=882.592957 
(Peak[6].power=4.029165, .freq=993.767395 
(Peak[7].power=1.674952, .freq=1237.208374 
(Peak[8].power=0.383828, .freq=1425.728271 
(Peak[9].power=6.948928, .freq=1652.006470 
      Harmonic PeakPair: (0,1)=1/2, error:0.01182 => f0 @ 109.299103
      Harmonic PeakPair: (0,2)=1/3, error:0.00185 => f0 @ 110.269806
      Harmonic PeakPair: (0,3)=1/5, error:0.03215 => f0 @ 121.165123
      Harmonic PeakPair: (0,4)=1/6, error:0.02286 => f0 @ 119.362068
      Harmonic PeakPair: (0,5)=1/6, error:0.04138 => f0 @ 128.837189
      Harmonic PeakPair: (0,6)=1/7, error:0.03159 => f0 @ 126.271156
pH(1): (1,2) -> 113.846863
pH(2): (2,3) -> 328.881317
pH(3): (3,4) -> 110.118042
pH(4): (4,5) -> 113.701416
pH(5): (5,6) -> 111.174438
(gdb) continue
 ~
Analysing Frame: 10!
(Peak[0].power=433.398010, .freq=107.317390 
(Peak[1].power=77.993584, .freq=330.160217 
(Peak[2].power=44.671906, .freq=437.536530 
(Peak[3].power=2.209188, .freq=572.636963 
(Peak[4].power=11.950575, .freq=659.227478 
(Peak[5].power=8.283246, .freq=770.578369 
(Peak[6].power=7.082703, .freq=881.237488 
(Peak[7].power=4.196370, .freq=992.599243 
(Peak[8].power=0.347792, .freq=1101.406372 
(Peak[9].power=0.496907, .freq=1221.087769 
      Harmonic PeakPair: (0,1)=1/3, error:0.00829 => f0 @ 108.685394
      Harmonic PeakPair: (0,2)=1/4, error:0.00472 => f0 @ 108.350761
      Harmonic PeakPair: (0,3)=1/5, error:0.01259 => f0 @ 110.922394
      Harmonic PeakPair: (0,4)=1/5, error:0.03721 => f0 @ 119.581436
      Harmonic PeakPair: (0,5)=1/6, error:0.02740 => f0 @ 117.873566
      Harmonic PeakPair: (0,6)=1/6, error:0.04489 => f0 @ 127.095154
      Harmonic PeakPair: (0,7)=1/7, error:0.03474 => f0 @ 124.558640
      Harmonic PeakPair: (0,8)=1/7, error:0.04542 => f0 @ 132.330582
pH(1): (1,2) -> 107.376312
pH(2): (2,3) -> 135.100433
pH(3): (3,4) -> 86.590515
pH(4): (4,5) -> 111.350891
pH(5): (5,6) -> 110.659119
pH(6): (6,7) -> 111.361755
pH(7): (7,8) -> 108.807129
(gdb) continue
 ~
Analysing Frame: 11!
(Peak[0].power=301.910400, .freq=110.975166 
(Peak[1].power=74.653061, .freq=222.941483 
(Peak[2].power=96.621552, .freq=330.352051 
(Peak[3].power=46.238697, .freq=442.270782 
(Peak[4].power=11.802574, .freq=661.371582 
(Peak[5].power=8.117818, .freq=767.469055 
(Peak[6].power=7.903056, .freq=880.591064 
(Peak[7].power=4.756960, .freq=992.815796 
(Peak[8].power=0.474961, .freq=1117.031738 
(Peak[9].power=0.436229, .freq=1223.791870 
      Harmonic PeakPair: (0,1)=1/2, error:0.00222 => f0 @ 111.222954
      Harmonic PeakPair: (0,2)=1/3, error:0.00260 => f0 @ 110.546257
      Harmonic PeakPair: (0,3)=1/4, error:0.00092 => f0 @ 110.771431
      Harmonic PeakPair: (0,4)=1/5, error:0.03220 => f0 @ 121.624741
      Harmonic PeakPair: (0,5)=1/6, error:0.02207 => f0 @ 119.443336
      Harmonic PeakPair: (0,6)=1/6, error:0.04064 => f0 @ 128.870178
      Harmonic PeakPair: (0,7)=1/7, error:0.03108 => f0 @ 126.403000
      Harmonic PeakPair: (0,8)=1/7, error:0.04351 => f0 @ 135.275558
pH(1): (1,2) -> 107.410568
pH(2): (2,3) -> 111.918732
pH(3): (3,4) -> 219.100800
pH(4): (4,5) -> 106.097473
pH(5): (5,6) -> 113.122009
pH(6): (6,7) -> 112.224731
pH(7): (7,8) -> 124.215942
(gdb) continue
 ~
Analysing Frame: 12!
(Peak[0].power=276.669220, .freq=107.785210 
(Peak[1].power=66.769165, .freq=237.818069 
(Peak[2].power=138.767258, .freq=330.801727 
(Peak[3].power=11.674421, .freq=658.715271 
(Peak[4].power=8.167289, .freq=768.212402 
(Peak[5].power=7.488355, .freq=882.716919 
(Peak[6].power=4.416694, .freq=993.001709 
(Peak[7].power=0.375417, .freq=1116.808472 
(Peak[8].power=0.594698, .freq=1223.301270 
(Peak[9].power=1.041116, .freq=1428.525635 
      Harmonic PeakPair: (0,1)=1/2, error:0.04677 => f0 @ 113.347122
      Harmonic PeakPair: (0,2)=1/3, error:0.00750 => f0 @ 109.026230
      Harmonic PeakPair: (0,3)=1/5, error:0.03637 => f0 @ 119.764130
      Harmonic PeakPair: (0,4)=1/6, error:0.02636 => f0 @ 117.910309
      Harmonic PeakPair: (0,5)=1/6, error:0.04456 => f0 @ 127.452347
      Harmonic PeakPair: (0,6)=1/7, error:0.03431 => f0 @ 124.821304
      Harmonic PeakPair: (0,7)=1/7, error:0.04635 => f0 @ 133.664642
pH(1): (1,2) -> 92.983658
pH(2): (2,3) -> 327.913544
pH(3): (3,4) -> 109.497131
pH(4): (4,5) -> 114.504517
pH(5): (5,6) -> 110.284790
pH(6): (6,7) -> 123.806763
(gdb) continue
 ~
Analysing Frame: 13!
(Peak[0].power=374.303864, .freq=111.099991 
(Peak[1].power=95.248856, .freq=330.270538 
(Peak[2].power=44.554127, .freq=439.593628 
(Peak[3].power=11.259159, .freq=659.028381 
(Peak[4].power=7.960227, .freq=772.035156 
(Peak[5].power=6.881539, .freq=880.567810 
(Peak[6].power=4.322595, .freq=990.723938 
(Peak[7].power=0.696263, .freq=1207.584595 
(Peak[8].power=0.975314, .freq=1427.747314 
(Peak[9].power=6.522787, .freq=1651.469360 
      Harmonic PeakPair: (0,1)=1/3, error:0.00306 => f0 @ 110.595085
      Harmonic PeakPair: (0,2)=1/4, error:0.00273 => f0 @ 110.499199
      Harmonic PeakPair: (0,3)=1/5, error:0.03142 => f0 @ 121.452835
      Harmonic PeakPair: (0,4)=1/6, error:0.02276 => f0 @ 119.886261
      Harmonic PeakPair: (0,5)=1/6, error:0.04050 => f0 @ 128.930649
      Harmonic PeakPair: (0,6)=1/7, error:0.03072 => f0 @ 126.315994
      Harmonic PeakPair: (0,7)=1/8, error:0.03300 => f0 @ 131.024033
pH(1): (1,2) -> 109.323090
pH(2): (2,3) -> 219.434753
pH(3): (3,4) -> 113.006775
pH(4): (4,5) -> 108.532654
pH(5): (5,6) -> 110.156128
pH(6): (6,7) -> 216.860657
(gdb) continue
 ~
Analysing Frame: 14!
(Peak[0].power=270.657196, .freq=108.657944 
(Peak[1].power=159.946777, .freq=215.400558 
(Peak[2].power=70.223312, .freq=330.803284 
(Peak[3].power=44.181171, .freq=442.037598 
(Peak[4].power=11.405427, .freq=660.210876 
(Peak[5].power=7.531929, .freq=768.298645 
(Peak[6].power=6.746090, .freq=879.789978 
(Peak[7].power=4.604754, .freq=993.830872 
(Peak[8].power=1.025858, .freq=1216.780762 
(Peak[9].power=1.027342, .freq=1432.005981 
      Harmonic PeakPair: (0,1)=1/2, error:0.00445 => f0 @ 108.179108
      Harmonic PeakPair: (0,2)=1/3, error:0.00487 => f0 @ 109.462852
      Harmonic PeakPair: (0,3)=1/4, error:0.00419 => f0 @ 109.583672
      Harmonic PeakPair: (0,4)=1/5, error:0.03542 => f0 @ 120.350060
      Harmonic PeakPair: (0,5)=1/6, error:0.02524 => f0 @ 118.353859
      Harmonic PeakPair: (0,6)=1/6, error:0.04316 => f0 @ 127.644806
      Harmonic PeakPair: (0,7)=1/7, error:0.03352 => f0 @ 125.316895
pH(1): (1,2) -> 115.402725
pH(2): (2,3) -> 111.234314
pH(3): (3,4) -> 218.173279
pH(4): (4,5) -> 108.087769
pH(5): (5,6) -> 111.491333
pH(6): (6,7) -> 114.040894
(gdb) continue
 ~
Analysing Frame: 15!
(Peak[0].power=250.447220, .freq=110.362984 
(Peak[1].power=158.152161, .freq=215.532776 
(Peak[2].power=66.299492, .freq=331.592072 
(Peak[3].power=39.972214, .freq=436.681610 
(Peak[4].power=11.086418, .freq=658.636780 
(Peak[5].power=7.820132, .freq=767.756409 
(Peak[6].power=5.995249, .freq=881.713013 
(Peak[7].power=3.804143, .freq=994.803406 
(Peak[8].power=0.285258, .freq=1088.384888 
(Peak[9].power=1.440606, .freq=1220.270020 
      Harmonic PeakPair: (0,1)=1/2, error:0.01205 => f0 @ 109.064682
      Harmonic PeakPair: (0,2)=1/3, error:0.00051 => f0 @ 110.446838
      Harmonic PeakPair: (0,3)=1/4, error:0.00273 => f0 @ 109.766693
      Harmonic PeakPair: (0,4)=1/5, error:0.03244 => f0 @ 121.045166
      Harmonic PeakPair: (0,5)=1/6, error:0.02292 => f0 @ 119.161194
      Harmonic PeakPair: (0,6)=1/6, error:0.04150 => f0 @ 128.657578
      Harmonic PeakPair: (0,7)=1/7, error:0.03192 => f0 @ 126.238876
      Harmonic PeakPair: (0,8)=1/7, error:0.04146 => f0 @ 132.923264
pH(1): (1,2) -> 116.059296
pH(2): (2,3) -> 105.089539
pH(3): (3,4) -> 221.955170
pH(4): (4,5) -> 109.119629
pH(5): (5,6) -> 113.956604
pH(6): (6,7) -> 113.090393
pH(7): (7,8) -> 93.581482
(gdb) continue
 ~
Analysing Frame: 16!
(Peak[0].power=225.168457, .freq=109.963272 
(Peak[1].power=148.453613, .freq=212.786423 
(Peak[2].power=65.515800, .freq=331.216644 
(Peak[3].power=42.287544, .freq=441.486938 
(Peak[4].power=11.021669, .freq=659.767517 
(Peak[5].power=8.184300, .freq=770.097107 
(Peak[6].power=6.571711, .freq=881.203125 
(Peak[7].power=3.726031, .freq=987.573914 
(Peak[8].power=1.173631, .freq=1215.363892 
(Peak[9].power=0.564619, .freq=1320.823242 
      Harmonic PeakPair: (0,1)=1/2, error:0.01678 => f0 @ 108.178238
      Harmonic PeakPair: (0,2)=1/3, error:0.00134 => f0 @ 110.184410
      Harmonic PeakPair: (0,3)=1/4, error:0.00093 => f0 @ 110.167503
      Harmonic PeakPair: (0,4)=1/5, error:0.03333 => f0 @ 120.958389
      Harmonic PeakPair: (0,5)=1/6, error:0.02388 => f0 @ 119.156395
      Harmonic PeakPair: (0,6)=1/6, error:0.04188 => f0 @ 128.415222
      Harmonic PeakPair: (0,7)=1/7, error:0.03151 => f0 @ 125.522629
pH(1): (1,2) -> 118.430222
pH(2): (2,3) -> 110.270294
pH(3): (3,4) -> 218.280579
pH(4): (4,5) -> 110.329590
pH(5): (5,6) -> 111.106018
pH(6): (6,7) -> 106.370789
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marked as duplicate by Paul R, belisarius, marcog, Potatoswatter, Andrzej Doyle Jan 31 '11 at 14:56

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1  
An algorithm to do what, precisely? –  Oliver Charlesworth Jan 29 '11 at 17:39
    
Calculate the implied fundamental... sorry -- I have edited the question slightly to make that clear. –  P i Jan 29 '11 at 17:49
1  
Why aren't you using one of the standard techniques, such as cepstral analysis ? You've already had a lot of help on all your previous similar questions but you seem to be ignoring it ? –  Paul R Jan 29 '11 at 17:52
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Why didn't you just edit the previous question? –  Lasse V. Karlsen Jan 29 '11 at 18:23
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Perhaps we should close the other one as a duplicate of this one then? –  Lasse V. Karlsen Jan 29 '11 at 18:25

1 Answer 1

up vote 0 down vote accepted

I found a fairly simple solution that is very low on computing power.

It involves giving a proximity score for each gap.

to calculate the proximity score for gap i, I simply sum 1 / {dist(gap_i, gap_j)+1} for all j!=i

I stuck a +1 to avoid division by zero. this way if two values are almost equal they will get a score of 1, and this score heads to 0 as the gap increases

but if Gap j is almost exactly twice gap i, it should also be considered as close proximity. so I first get the closest integer to gap_j/gap_i (maybe have to swap so that gap_j is bigger), then divide gap_j by this integer, and then consider dist(gap_i, fiddled_gap_j)

if for example gap_j ~= 2*gap_i, Then I am careful to boost the score for Gap_i, and not gap_j

this works very well to get a reasonably accurate candidate. a couple more processing passes should refine the value quite easily. the first I guess would be to average out values in light of the successful candidate. and then maybe a second that creates a harmonicity(f) function, and uses some sort of Newton-Raphson process starting at the previously calculated point to isolate the local maximum.

anyway, fwiw here is the code:

    float ascertain_f0(PEAK * peaks, POTENTIAL_HARMONIC * pH, int phCount)
{
    int gaps = phCount;

    // enumerate GAPS
    GAP gap [ MAX_POTENTIAL_HARMONICS ];

    gap[0].len = peaks[pH[0].peakQ].freq;
    for (int i=1; i < gaps; i++)
    {
        int a = pH[i-1].peakQ, 
            b = pH[i].peakQ;

        gap[i].len = peaks[b].freq - peaks[a].freq;
    }

    for (int i=0; i < gaps; i++)
        gap[i].score = 0.;

    // find best scoring gap
    for (int i=0; i < gaps; i++)
        for (int j=0; j < gaps; j++)
        {
            if (i == j)
                continue;

            float a = gap[i].len;
            float B_ = gap[j].len;

            if (a > B_)
                continue;

            // a < B_
            int multiplier = closestInt(B_ / a);
            float b = B_ / multiplier;

            float dist = fabs(b - a);           
            float sc = 1. / (dist + 1.);

            gap[i].score += sc;
            if (multiplier == 1)
                gap[j].score += sc;
        }

    int best = 0;
    for (int i=1; i < gaps; i++)
        if (gap[i].score > gap[best].score)
            best = i;

    return gap[best].len;
}
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Some other approaches are discussed here: stackoverflow.com/questions/445113/… –  Christopher Oezbek Jul 21 '12 at 16:50

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