# Python computing error

I’m using the API mpmath to compute the following sum

Let us consider the serie u0, u1, u2 defined by:

``````u0 = 3/2 = 1,5

u1 = 5/3 = 1,6666666…

un+1 = 2003 - 6002/un + 4000/un un-1
``````

The serie converges on 2, but with rounding problem it seems to converge on 2000.

```n   Calculated value    Rounded off exact value

2   1,800001            1,800000000
3   1,890000            1,888888889
4   3,116924            1,941176471
5   756,3870306         1,969696970
6   1996,761549         1,984615385
7   1999,996781         1,992248062
8   1999,999997         1,996108949
9   2000,000000         1,998050682
10  2000,000000         1,999024390
```

My code :

``````from mpmath import *
mp.dps = 50
u0=mpf(3/2.0)
u1=mpf(5/3.0)
u=[]
u.append(u0)
u.append(u1)
for i in range (2,11):
un1=(2003-6002/u[i-1]+(mpf(4000)/mpf((u[i-1]*u[i-2]))))
u.append(un1)
print u
``````

``````[mpf('1.5'),
mpf('1.6666666666666667406815349750104360282421112060546875'),
mpf('1.8000000000000888711326751945268011597589466120961647'),
mpf('1.8888888889876302386905492787148253684796100079942617'),
mpf('1.9411765751351638992775070422559330255517747908588059'),
mpf('1.9698046831709839591526211645628191427874374792786951'),
mpf('2.093979191783975876606205176530675127058752077926479'),
mpf('106.44733511712489354422046139349654833300787666477228'),
mpf('1964.5606972399290690749220686397494349501387742896911'),
mpf('1999.9639916238009625032390578545797067344576357100626'),
mpf('1999.9999640260895343960004614025893194430187653900418')]
``````

I tried to perform with some others functions (fdiv…) or to change the precision: same bad result

What’s wrong with this code ?

Question: How to change my code to find the value 2.0 ??? with the formula :

un+1 = 2003 - 6002/un + 4000/un un-1

thanks

-
could you be more precise about what you call `Calculated value` and `Rounded off exact value` ? –  Simon Jan 2 '12 at 9:14
calculated value is the value computed with the formula and exact value is the value expected (but rounded) –  user1125932 Jan 2 '12 at 9:33
`calculated value is the value computed with the formula` computed by what? `exact value is the value expected` why is it expected ? –  Simon Jan 2 '12 at 9:46
Please use a better notation and proper parentheses: e.g., `un+1` -> `u(n+1)`, `4000/un un-1` -> `4000/[u(n) u(n-1)]` –  Andrew Jaffe Jan 2 '12 at 10:05
@user1125932 If the answers here were helpful, please mark one as accepted. –  Raymond Hettinger Jan 3 '12 at 7:25
show 1 more comment

Using the decimal module, you can see the series also has a solution converging at 2000:

``````from decimal import Decimal, getcontext
getcontext().prec = 100

u0=Decimal(3) / Decimal(2)
u1=Decimal(5) / Decimal(3)
u=[u0, u1]
for i in range(100):
un1 = 2003 - 6002/u[-1] + 4000/(u[-1]*u[-2])
u.append(un1)
print un1
``````

The recurrence relation has multiple fixed points (one at 2 and the other at 2000):

``````>>> u = [Decimal(2), Decimal(2)]
>>> 2003 - 6002/u[-1] + 4000/(u[-1]*u[-2])
Decimal('2')

>>> u = [Decimal(2000), Decimal(2000)]
>>> 2003 - 6002/u[-1] + 4000/(u[-1]*u[-2])
Decimal('2000.000')
``````

The solution at 2 is an unstable fixed-point. The attractive fixed-point is at 2000.

The convergence gets very close to two and when the round-off causes the value to slightly exceed two, that difference gets amplified again and again until hitting 2000.

-
yes I think there's a problem with this formula. –  user1125932 Jan 2 '12 at 9:28
but what is the correct answer with u0=3/2 and u1=5/3 ? Why it doesnt converge to 2 (due to rounding value ???)? –  user1125932 Jan 2 '12 at 9:36
That's just the way recurrence formulas work. You've got a mathematical problem, not a programming problem. –  Raymond Hettinger Jan 2 '12 at 9:56
"... the series also has a solution converging at 2000" -- "Solution" is not the right word, I think, because there is only one solution to the given recurrence relation (with the given initial conditions), and it converges to 2 -- it does not converge to the attractor at 2000. It's the incorrect numerical approximations that converge to 2000. Also, there are three (not two) fixed points, i.e., 1, 2, 2000. –  r.e.s. Jan 5 '12 at 4:51
show 1 more comment

Your (non-linear) recurrence sequence has three fixed points: `1`, `2` and `2000`. The values 1 and 2 are close to each other compared to 2000, which is usually an indication of unstable fixed points because they are "almost" double roots.

You need to do some maths in order to diverge less early. Let `v(n)` be a side sequence:

``````v(n) = (1+2^n)u(n)
``````

The following holds true:

``````v(n+1) = (1+2^(n+1)) * (2003v(n)v(n-1) - 6002(1+2^n)v(n-1) + 4000(1+2^n)(1+2^n-1)) / (v(n)v(n-1))
``````

You can then simply compute `v(n)` and deduce `u(n)` from `u(n) = v(n)/(1+2^n)`:

``````#!/usr/bin/env python

from mpmath import *
mp.dps = 50
v0 = mpf(3)
v1 = mpf(5)
v=[]
v.append(v0)
v.append(v1)

u=[]
u.append(v[0]/2)
u.append(v[1]/3)

for i in range (2,25):
vn1 = (1+2**i) * (2003*v[i-1]*v[i-2] \
- 6002*(1+2**(i-1))*v[i-2] \
+ 4000*(1+2**(i-1))*(1+2**(i-2))) \
/ (v[i-1]*v[i-2])
v.append(vn1)
u.append(vn1/(1+2**i))

print u
``````

And the result:

``````[mpf('1.5'),
mpf('1.6666666666666666666666666666666666666666666666666676'),
mpf('1.8000000000000000000000000000000000000000000000000005'),
mpf('1.8888888888888888888888888888888888888888888888888892'),
mpf('1.9411764705882352941176470588235294117647058823529413'),
mpf('1.969696969696969696969696969696969696969696969696969'),
mpf('1.9846153846153846153846153846153846153846153846153847'),
mpf('1.992248062015503875968992248062015503875968992248062'),
mpf('1.9961089494163424124513618677042801556420233463035019'),
mpf('1.9980506822612085769980506822612085769980506822612089'),
mpf('1.9990243902439024390243902439024390243902439024390251'),
mpf('1.9995119570522205954123962908735968765251342118106393'),
mpf('1.99975591896509641200878691725652916768367097876495'),
mpf('1.9998779445868424264616135725619431221774685707311133'),
mpf('1.9999389685688129386634116570033567287152883735123589'),
mpf('1.9999694833531691537733833806341359211449845890933504'),
mpf('1.9999847414437645909944001098616048949448403192089965'),
mpf('1.9999923706636759668276456631037666033431751771913355'),
...
``````

Note that this will still diverge eventually. In order to really converge, you need to compute `v(n)` with arbitrary precision. But this is now a lot easier since all the values are integers.

-

You calculate your initial values to 53-bits of precision and then assign that rounded value to the high-precision mpf variable. You should use u0=mpf(3)/mpf(2) and u1=mpf(5)/mpf(3). You'll stay close to 2 for a few more interations, but you'll still end up converging at 2000. This is due to rounding error. One alternative is to compute with fractions. I used gmpy and the following code converges to 2.

``````from __future__ import print_function
import gmpy

u = [gmpy.mpq(3,2), gmpy.mpq(5,3)]
for i in range(2,300):
temp = (2003 - 6002/u[-1] + 4000/(u[-1]*u[-2]))
u.append(temp)

for i in u: print(gmpy.mpf(i,300))
``````
-
great ! it works !!! so I have tried to computed with a precision of 150 digits and it failed with mpmath. Is the gmpy API more reliable than mpmath ? –  user1125932 Jan 2 '12 at 10:44
gmpy's advantage is speed. If gmpy is installed on your system, mpmath will automatically use it to improve performance. But mpmath won't fail without it. What's your new code? How exactly did it fail? –  casevh Jan 2 '12 at 15:38
As I explained in the answer below, I didn't find an mpq function in API mpmath. –  user1125932 Jan 5 '12 at 9:49

If you compute with infinite precision then you get `2` otherwise you get `2000`:

``````import itertools
from fractions import Fraction

def series(u0=Fraction(3, 2), u1=Fraction(5, 3)):
yield u0
yield u1
while u0 != u1:
un = 2003 - 6002/u1 + 4000/(u1*u0)
yield un
u1, u0 = un, u1

for i, u in enumerate(itertools.islice(series(), 100)):
err = (2-u)/2 # relative error
print("%d\t%.2g" % (i, err))
``````

### Output

``````0   0.25
1   0.17
2   0.1
3   0.056
4   0.029
5   0.015
6   0.0077
7   0.0039
8   0.0019
9   0.00097
10  0.00049
11  0.00024
12  0.00012
13  6.1e-05
14  3.1e-05
15  1.5e-05
16  7.6e-06
17  3.8e-06
18  1.9e-06
19  9.5e-07
20  4.8e-07
21  2.4e-07
22  1.2e-07
23  6e-08
24  3e-08
25  1.5e-08
26  7.5e-09
27  3.7e-09
28  1.9e-09
29  9.3e-10
30  4.7e-10
31  2.3e-10
32  1.2e-10
33  5.8e-11
34  2.9e-11
35  1.5e-11
36  7.3e-12
37  3.6e-12
38  1.8e-12
39  9.1e-13
40  4.5e-13
41  2.3e-13
42  1.1e-13
43  5.7e-14
44  2.8e-14
45  1.4e-14
46  7.1e-15
47  3.6e-15
48  1.8e-15
49  8.9e-16
50  4.4e-16
51  2.2e-16
52  1.1e-16
53  5.6e-17
54  2.8e-17
55  1.4e-17
56  6.9e-18
57  3.5e-18
58  1.7e-18
59  8.7e-19
60  4.3e-19
61  2.2e-19
62  1.1e-19
63  5.4e-20
64  2.7e-20
65  1.4e-20
66  6.8e-21
67  3.4e-21
68  1.7e-21
69  8.5e-22
70  4.2e-22
71  2.1e-22
72  1.1e-22
73  5.3e-23
74  2.6e-23
75  1.3e-23
76  6.6e-24
77  3.3e-24
78  1.7e-24
79  8.3e-25
80  4.1e-25
81  2.1e-25
82  1e-25
83  5.2e-26
84  2.6e-26
85  1.3e-26
86  6.5e-27
87  3.2e-27
88  1.6e-27
89  8.1e-28
90  4e-28
91  2e-28
92  1e-28
93  5e-29
94  2.5e-29
95  1.3e-29
96  6.3e-30
97  3.2e-30
98  1.6e-30
99  7.9e-31
``````
-
yes : an infinite precision is required ! It was a rounding problem in my code. –  user1125932 Jan 2 '12 at 10:46

Well, as casevh said, I just added the mpf function in first initials terms in my code :

u0=mpf(3)/mpf(2)

u1=mpf(5)/mpf(3)

and the value converge for 16 steps to the correct value 2.0 before diverged again (see below).

So, even with a good python library for arbitrary-precision floating-point arithmetic and some basics operations the result can become totally false and it is not algorithmic, mathematical or recurrence problem as I read sometimes.

So it is necessary to remain watchful and critic !!! ( I’m very afraid about the mpmath.lerchphi(z, s, a) function ;-)

2 1.8000000000000000000000000000000000000000000000022 3 1.8888888888888888888888888888888888888888888913205 4 1.9411764705882352941176470588235294117647084569125 5 1.9696969696969696969696969696969696969723495083846 6 1.9846153846153846153846153846153846180779422496889 7 1.992248062015503875968992248062018218070968279944 8 1.9961089494163424124513618677070049064461141667961 9 1.998050682261208576998050684991268132991329645551 10 1.9990243902439024390243929766241359876402781522945 11 1.9995119570522205954151303455889283862002420414092 12 1.9997559189650964147435086295745928366095548127257 13 1.9998779445868451615169464386495752584786229236677 14 1.9999389685715481608370784691478769380770569091713 15 1.9999694860884747554701272066241108169217231319376 16 1.9999874767910784720428384947047783821702386000249 17 2.0027277350948824117795762659330557916802871427763 18 4.7316350177463946015607576536159982430500337286276 19 1156.6278675611076227796014310764287933259776352198 20 1998.5416721291457644804673979070312813731252347786 21 1999.998540608689366669273522363692463645090555294 22 1999.9999985406079725746311606572627439743947878652

-

The exact solution to your recurrence relation (with initial values u_0 = 3/2, u_1 = 5/3) is easily verified to be

``````u_n = (2^(n+1) + 1) / (2^n + 1).    (*)
``````

The problem you're seeing is that although the solution is such that

``````lim_{n -> oo} u_n = 2,
``````

this limit is a repelling fixed point of your recurrence relation. That is, any departure from the correct values of u_{n-1}, u{n-2}, for some n, will result in further values diverging from the correct limit. Consequently, unless your implementation of the recurrence relation correctly represents every u_n value exactly, it can be expected to exhibit eventual divergence from the correct limit, converging to the incorrect value of 2000 that just happens to be the only attracting fixed point of your recurrence relation.

(*) In fact, u_n = (2^(n+1) + 1) / (2^n + 1) is the solution to any recurrence relation of the form

``````u_n = C + (7 - 3C)/u_{n-1} + (2C - 6)/(u_{n-1} u_{n-2})
``````

with the same initial values as given above, where C is an arbitrary constant. If I haven't made a mistake finding the roots of the characteristic polynomial, this will have the set of fixed points {1, 2, C - 3}\{0}. The limit 2 can be either a repelling fixed point or an attracting fixed point, depending on the value of C. E.g., for C = 2003 the set of fixed points is {1, 2, 2000} with 2 being a repellor, whereas for C = 3 the fixed points are {1, 2} with 2 being an attractor.

-
thanks for the explanations. I did not find the analytical solution of the equation. It seems to be like a dynamical systems that are highly sensitive to initial conditions and it reminds to me a result of chaos theory. –  user1125932 Jan 5 '12 at 9:41