一尘不染

算法挑战:为浮点数生成连续分数

algorithm

编辑
:回应脾气暴躁的评论,不,这不是功课。我正在进行音调检测,采集一系列潜在的谐波峰,并试图构建基本频率的候选者。因此,这实际上是一个非常实际的问题。 )

考虑pi的最佳分数近似,以分母递增的顺序排列:3/1,22/7,355/113,…

挑战:创建一个 整洁的 C算法,该算法将为给定的浮点数生成第n个商近似a / b,同时还返回差异。

calcBestFrac(float frac,int n,int * a,int * b,float * err){…}

我认为最好的技术是 连续分数

除去pi的小数部分,您将得到3
现在,余数为0.14159 … = 1 / 7.06251。

因此,下一个最佳有理数是3 + 1/7 = 22/7
从7.06251中减去7,您将得到0.06251 ..大约是1 / 15.99659 ..

称它为16,那么下一个最佳逼近度是
3 + 1 /(7 + 1/16)= 355/113

但是,将其转换为干净的C代码绝非易事。如果我整理整齐,我会发布。同时,有人可能会喜欢脑筋急转弯。


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2020-07-28

共1个答案

一尘不染

[因为您要求的是答案而不是评论。]

对于任何实数,其连续分数的收敛点p [k] / q [k]始终是最佳有理逼近,但并非 全部都是 最佳有理逼近。要获得所有这些,您还必须采用半收敛/中值-
(p[k]+n*p[k+1])/(q[k]+n*q[k+1])某个n≥1的整数的形式的分数。取n = a [k + 2]得出p [k + 2] / q
[k + 2],要取的整数n是下限(a [k + 2] / 2)或上限(a [ k + 2] / 2)到a [k +
2]。维基百科上也提到这一点。

约π

π的连续分数为[3; 7,15,1,292,1,1,1,2,2,1,3,1,14,2
…](OEIS中的序列A001203),会聚的顺序为3
/ 1、22 / 7、333 / 106 ,355 / 113、103993 /
33102…(A002485 /
A002486),最佳逼近顺序为3 / 1、13
/ 4、16 / 5、19 /
6、22 / 7、179 /
57…(A063674 / A063673)。

因此该算法表示π= [3; 7,15,1,292,1,1,…]是

3/1     = [3]

13/4    = [3; 4]
16/5    = [3; 5]
19/6    = [3; 6]
22/7    = [3; 7]

179/57  = [3; 7, 8]
201/64  = [3; 7, 9]
223/71  = [3; 7, 10]
245/78  = [3; 7, 11]
267/85  = [3; 7, 12]
289/92  = [3; 7, 13]
311/99  = [3; 7, 14]
333/106 = [3; 7, 15]

355/113 = [3; 7, 15, 1]

52163/16604  = [3; 7, 15, 1, 146]
52518/16717  = [3; 7, 15, 1, 147]
… (all the fractions from [3; 7, 15, 1, 148] to [3; 7, 15, 1, 291])…
103993/33102 = [3; 7, 15, 1, 292]

104348/33215 = [3; 7, 15, 1, 292, 1]
...

程序

这是一个给定正实数的C程序,它生成其连续分数,其收敛和最佳有理逼近序列。该函数find_cf找到连续分数(将a []中的项以及p []和q
[]中的收敛项-排除全局变量),并且该函数将all_best打印所有最佳有理逼近。

#include <math.h>
#include <stdio.h>
#include <assert.h>

// number of terms in continued fraction.
// 15 is the max without precision errors for M_PI
#define MAX 15
#define eps 1e-9

long p[MAX], q[MAX], a[MAX], len;
void find_cf(double x) {
  int i;
  //The first two convergents are 0/1 and 1/0
  p[0] = 0; q[0] = 1;
  p[1] = 1; q[1] = 0;
  //The rest of the convergents (and continued fraction)
  for(i=2; i<MAX; ++i) {
    a[i] = lrint(floor(x));
    p[i] = a[i]*p[i-1] + p[i-2];
    q[i] = a[i]*q[i-1] + q[i-2];
    printf("%ld:  %ld/%ld\n", a[i], p[i], q[i]);
    len = i;
    if(fabs(x-a[i])<eps) return;
    x = 1.0/(x - a[i]);
  }
}

void all_best(double x) {
  find_cf(x); printf("\n");
  int i, n; long cp, cq;
  for(i=2; i<len; ++i) {
    //Test n = a[i+1]/2. Enough to test only when a[i+1] is even, actually...
    n = a[i+1]/2; cp = n*p[i]+p[i-1]; cq = n*q[i]+q[i-1];
    if(fabs(x-(double)cp/cq) < fabs(x-(double)p[i]/q[i])) 
      printf("%ld/%ld, ", cp, cq);
    //And print all the rest, no need to test
    for(n = (a[i+1]+2)/2; n<=a[i+1]; ++n) {
      printf("%ld/%ld, ", n*p[i]+p[i-1], n*q[i]+q[i-1]);
    }
  }
}

int main(int argc, char **argv) {
  double x;
  if(argc==1) { x = M_PI; } else { sscanf(argv[1], "%lf", &x); }
  assert(x>0); printf("%.15lf\n\n", x);
  all_best(x); printf("\n");
  return 0;
}

例子

对于π,这是该程序的输出,大约需要0.003秒(即,这比循环遍历所有可能的分母要好!),并进行换行以提高可读性:

% ./a.out
3.141592653589793

3:  3/1
7:  22/7
15:  333/106
1:  355/113
292:  103993/33102
1:  104348/33215
1:  208341/66317
1:  312689/99532
2:  833719/265381
1:  1146408/364913
3:  4272943/1360120
1:  5419351/1725033
14:  80143857/25510582

13/4, 16/5, 19/6, 22/7, 179/57, 201/64, 223/71, 245/78, 267/85, 289/92, 311/99,
333/106, 355/113, 52163/16604, 52518/16717, 52873/16830, 53228/16943, 53583/17056,
53938/17169, 54293/17282, 54648/17395, 55003/17508, 55358/17621, 55713/17734,
56068/17847, 56423/17960, 56778/18073, 57133/18186, 57488/18299, 57843/18412,
58198/18525, 58553/18638, 58908/18751, 59263/18864, 59618/18977, 59973/19090,
60328/19203, 60683/19316, 61038/19429, 61393/19542, 61748/19655, 62103/19768,
62458/19881, 62813/19994, 63168/20107, 63523/20220, 63878/20333, 64233/20446,
64588/20559, 64943/20672, 65298/20785, 65653/20898, 66008/21011, 66363/21124,
66718/21237, 67073/21350, 67428/21463, 67783/21576, 68138/21689, 68493/21802,
68848/21915, 69203/22028, 69558/22141, 69913/22254, 70268/22367, 70623/22480,
70978/22593, 71333/22706, 71688/22819, 72043/22932, 72398/23045, 72753/23158,
73108/23271, 73463/23384, 73818/23497, 74173/23610, 74528/23723, 74883/23836,
75238/23949, 75593/24062, 75948/24175, 76303/24288, 76658/24401, 77013/24514,
77368/24627, 77723/24740, 78078/24853, 78433/24966, 78788/25079, 79143/25192,
79498/25305, 79853/25418, 80208/25531, 80563/25644, 80918/25757, 81273/25870,
81628/25983, 81983/26096, 82338/26209, 82693/26322, 83048/26435, 83403/26548,
83758/26661, 84113/26774, 84468/26887, 84823/27000, 85178/27113, 85533/27226,
85888/27339, 86243/27452, 86598/27565, 86953/27678, 87308/27791, 87663/27904,
88018/28017, 88373/28130, 88728/28243, 89083/28356, 89438/28469, 89793/28582,
90148/28695, 90503/28808, 90858/28921, 91213/29034, 91568/29147, 91923/29260,
92278/29373, 92633/29486, 92988/29599, 93343/29712, 93698/29825, 94053/29938,
94408/30051, 94763/30164, 95118/30277, 95473/30390, 95828/30503, 96183/30616,
96538/30729, 96893/30842, 97248/30955, 97603/31068, 97958/31181, 98313/31294,
98668/31407, 99023/31520, 99378/31633, 99733/31746, 100088/31859, 100443/31972,
100798/32085, 101153/32198, 101508/32311, 101863/32424, 102218/32537, 102573/32650,
102928/32763, 103283/32876, 103638/32989, 103993/33102, 104348/33215, 208341/66317,
312689/99532, 833719/265381, 1146408/364913, 3126535/995207,
4272943/1360120, 5419351/1725033, 42208400/13435351, 47627751/15160384,
53047102/16885417, 58466453/18610450, 63885804/20335483, 69305155/22060516,
74724506/23785549, 80143857/25510582,

所有这些术语都是正确的,尽管如果增加MAX会因为精度而开始出现错误。我对只有13个聚合词获得多少个条件印象深刻。(如您所见,存在一个小错误,有时它不会打印出第一个“
n / 1”近似值,或者打印不正确—我留给您修复!)

您可以尝试使用√2,其连续分数为[1; 2,2,2,2…]:

% ./a.out 1.41421356237309504880
1.414213562373095

1:  1/1
2:  3/2
2:  7/5
2:  17/12
2:  41/29
2:  99/70
2:  239/169
2:  577/408
2:  1393/985
2:  3363/2378
2:  8119/5741
2:  19601/13860
2:  47321/33461

3/2, 4/3, 7/5, 17/12, 24/17, 41/29, 99/70, 140/99, 239/169, 577/408, 816/577, 1393/985, 3363/2378, 4756/3363, 8119/5741, 19601/13860, 47321/33461,

或黄金分割比率φ=(1 +√5)/ 2,其连续分数为[1; 1,1,1,…]:

% ./a.out 1.61803398874989484820
1.618033988749895

1:  1/1
1:  2/1
1:  3/2
1:  5/3
1:  8/5
1:  13/8
1:  21/13
1:  34/21
1:  55/34
1:  89/55
1:  144/89
1:  233/144
1:  377/233

2/1, 3/2, 5/3, 8/5, 13/8, 21/13, 34/21, 55/34, 89/55, 144/89, 233/144, 377/233,

(查看斐波纳契数吗?这里的收敛子都是近似值。)

或使用4/3 = [1; 3]:

% ./a.out 1.33333333333333333333
1.333333333333333

1:  1/1
3:  4/3

3/2, 4/3,

或14/11 = [1; 3,1,2]:

% ./a.out 1.27272727272727272727
1.272727272727273

1:  1/1
3:  4/3
1:  5/4
2:  14/11

3/2, 4/3, 5/4, 9/7, 14/11,

请享用!

2020-07-28