Unexpected result from lsqlin
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Recently I encountered an unexpecte result from lsqlin. Basically I have a linear system that can be any size, even 1x1. This is actually the case of interest. I attach the code:
s=[7.46355685131195e-06;2.61224489795918e-07;-7.46355685131195e-06;2.61224489795918e-07;0;0;0;0;0;0;0;0;0;0;2.61224489795918e-07;1.21904761904762e-08;-2.61224489795918e-07;6.09523809523810e-09;0;0;0;0;0;0;0;0;0;0;-7.46355685131195e-06;-2.61224489795918e-07;1.49271137026239e-05;0;-7.46355685131195e-06;2.61224489795918e-07;0;0;0;0;0;0;0;0;2.61224489795918e-07;6.09523809523810e-09;0;2.43809523809524e-08;-2.61224489795918e-07;6.09523809523810e-09;0;0;0;0;0;0;0;0;0;0;-7.46355685131195e-06;-2.61224489795918e-07;1.49271137026239e-05;0;-7.46355685131195e-06;2.61224489795918e-07;0;0;0;0;0;0;0;0;2.61224489795918e-07;6.09523809523810e-09;0;2.43809523809524e-08;-2.61224489795918e-07;6.09523809523810e-09;0;0;0;0;0;0;0;0;0;0;-7.46355685131195e-06;-2.61224489795918e-07;1.49271137026239e-05;0;-7.46355685131195e-06;2.61224489795918e-07;0;0;0;0;0;0;0;0;2.61224489795918e-07;6.09523809523810e-09;0;2.43809523809524e-08;-2.61224489795918e-07;6.09523809523810e-09;0;0;0;0;0;0;0;0;0;0;-7.46355685131195e-06;-2.61224489795918e-07;1.87420339044574e-05;8.27690603250169e-08;-1.12784770531454e-05;3.43993550120935e-07;0;0;0;0;0;0;0;0;2.61224489795918e-07;6.09523809523810e-09;8.27690603250169e-08;2.61795472287276e-08;-3.43993550120935e-07;6.99453551912568e-09;0;0;0;0;0;0;0;0;0;0;-1.12784770531454e-05;-3.43993550120935e-07;1.74696244982844e-05;-1.13373307789508e-07;-6.19114744513898e-06;2.30620242331427e-07;0;0;0;0;0;0;0;0;3.43993550120935e-07;6.99453551912568e-09;-1.13373307789508e-07;2.54432097407122e-08;-2.30620242331427e-07;5.72706935123043e-09;0;0;0;0;0;0;0;0;0;0;-6.19114744513898e-06;-2.30620242331427e-07;1.23822948902779e-05;-2.91167575618666e-22;0;0;0;0;0;0;0;0;0;0;2.30620242331427e-07;5.72706935123043e-09;-2.91167575618666e-22;2.29082774049217e-08];
z=[-8287.20136961842;-207.695733121256;-7600.97514253616;-534.391927360151;-5646.81895072033;-842.926473299020;-2749.01799205948;-608.263953041959;-1800.96549474418;-218.233277809774;-1246.61121855062;-222.701572169097;-454.985962888617;-229.489284788134;-207.695733121258;-4.31159651230973;-211.583072054673;-10.5817786869719;-207.469127449374;-19.4084812806167;-205.554052675241;-14.2334094340071;-127.980376432081;-5.82044377019796;-89.3993392954632;-10.0358904762527;-38.6028133285081;-12.8937660172881;-7600.97514253634;-211.583072054673;-6704.83421266254;-532.664018086793;-4247.04164361325;-784.667235831777;-374.396860142614;-575.355545468737;-646.254735224021;-237.767202031333;-565.502081093624;-211.802648689606;-245.788051294455;-215.794095284558;-534.391927360146;-10.5817786869719;-532.664018086794;-24.4250894201275;-533.575869722970;-44.6885886888697;-562.261663238565;-27.6728741709106;-340.294987483632;-3.91648028872448;-233.005638525614;-13.8504678942122;-98.9719393675175;-19.5724723345471;-5646.81895072033;-207.469127449374;-4247.04164361319;-533.575869722965;-874.961989329080;-681.827735041812;4550.00831251650;-524.710100984108;1754.26594854213;-278.456336087023;813.872071787322;-192.126815096214;174.918786479950;-186.341242826303;-842.926473299020;-19.4084812806167;-784.667235831777;-44.6885886888698;-681.827735041812;-73.1296054491854;-560.603026422607;-44.4867666242581;-367.876515600137;-5.36578138470502;-262.187708991285;-13.9626208876454;-116.168335764689;-19.6047309183772;-2749.01799205944;-205.554052675241;-374.396860142644;-562.261663238565;4550.00831251667;-560.603026422608;12023.7350216699;-465.718352496805;5337.97747610125;-338.507025489656;2511.57328179486;-178.101015182985;439.839230323449;-183.023532525701;-608.263953041959;-14.2334094340071;-575.355545468737;-27.6728741709106;-524.710100984101;-44.4867666242582;-465.718352496805;-15.3539182495451;-359.289436100471;17.6126762396493;-285.779177534844;7.60510383356906;-145.366784817360;0.0955479313669716;-1800.96549474418;-127.980376432081;-646.254735224029;-340.294987483632;1754.26594854214;-367.876515600137;5337.97747610143;-359.289436100471;2994.26975751692;-289.642137402146;1958.78945016873;-162.344662349205;811.528922972301;-119.802928873498;-218.233277809774;-5.82044377019797;-237.767202031333;-3.91648028872449;-278.456336087023;-5.36578138470502;-338.507025489655;17.6126762396493;-289.642137402146;35.6258773907798;-248.235934165285;25.5115603160600;-137.758663681854;17.5455698744229;-1246.61121855062;-89.3993392954633;-565.502081093631;-233.005638525614;813.872071787326;-262.187708991284;2511.57328179485;-285.779177534844;1958.78945016873;-248.235934165288;1588.04981195810;-144.928904474322;800.700832420902;-94.0273547749384;-222.701572169097;-10.0358904762527;-211.802648689606;-13.8504678942122;-192.126815096214;-13.9626208876454;-178.101015182985;7.60510383356905;-162.344662349205;25.5115603160600;-144.928904474323;20.8134206727082;-85.8545148794237;15.3928444934107;-454.985962888616;-38.6028133285082;-245.788051294462;-98.9719393675172;174.918786479950;-116.168335764689;439.839230323450;-145.366784817360;811.528922972296;-137.758663681854;800.700832420902;-85.8545148794237;488.887846553582;-53.5142394051840;-229.489284788134;-12.8937660172881;-215.794095284558;-19.5724723345471;-186.341242826303;-19.6047309183772;-183.023532525701;0.0955479313669731;-119.802928873498;17.5455698744229;-94.0273547749366;15.3928444934106;-53.5142394051840;10.5398416193868];
A=s'*s;
b=s'*z;
L=-3e10;
U=1e10;
x1=lsqlin(A,b,[],[],[],[],L,U);
x2=b/A;
disp(A*x1-b)
disp(A*x2-b)
Since the matrix A is actually a scalar, the solution can be computed also as b/A. Accidentally, b/A is also compliant to the lower and upper bound L and U, so I'm wondering why does lsqlin return a different solution. I use matlab 2015b with optimization toolbox 7.3. I thank you very much in advance.
2 Comments
Torsten
on 14 Oct 2016
Did you check whether A and b are the same before and after the call to lsqlin ?
Best wishes
Torsten.
Accepted Answer
John D'Errico
on 14 Oct 2016
Edited: John D'Errico
on 14 Oct 2016
Your problem is that you do not understand what / does, the difference between / and \, or the linear algebra, or what lsqlin does. I'm sorry, but that is true. (I'm not sure how to say that more tactfully, and it would take more time to write. Facts are facts.) Effectively, you have made several mistakes, that all combine into one mess of misunderstandings.
First, s is a column vector, as is z.
The solution that you are using uses something often (sometimes?) called the normal equations, to solve a linear least squares problem. It solves the problem
y = A*x
where A is a known matrix, as is y. (Y is usually a vector of knowns.) The normal equations have you solve this as
x = inv(A'*A)*A'*y
but some people think they are using an improvement is they use a tool like lsqlin here:
x = (A'*A,A'*y);
That is effectively what you have done.
However, a better solution to the problem is simply to use BACKSLASH, thus the \ operator, here:
x = A\y
backslash uses better linear algebra algorithms to solve the problems, NEVER forming the matrix A'*A. The problem is that when you create the matrix A'*A, you square the condition number of A. That makes a bad problem worse, is A is nearly singular.
In this case, the real problem is not that you formed A'*A here, although there are always numerical issues to worry about. The problem is that you think that this is the same as using the FORWARD slash operator!
Given two COLUMN vectors s and z, here is what you did:
A = s'*s
A =
2.3126e-09
b
b =
0.069217
When you solved the problem as
x2 = b/A
MATLAB sees that b and A are scalar variables. It simply divides the scalar b by the scalar A, so it is solving the problem as:
/ Slash or right division.
B/A is the matrix division of A into B, which is roughly the
same as B*INV(A) , except it is computed in a different way.
More precisely, B/A = (A'\B')'. See \.
which, in the case that A was a MATRIX, would be a different thing. Luckily, A is a scalar. Slash implicitly solves the problem that would have been posed as
x2*(s'*s) = s'*z
Since x2, (s'*s) and (s'*z) are ALL scalar variables, scalar multiplication commutes, and we can simply use divide here, so forward slash. Lets see what happens though.
format long g
x2 = b/A
x2 =
29930312.2584127
Here is what BACKSLASH (what you SHOULD have used in the first place) yields
x = s\z
x =
29930312.2584127
Here is what lsqlin gives, with no constraints:
lsqlin(A,b)
ans =
29930312.2584127
lsqlin(s,z)
ans =
29930312.2584127
So they all worked, and gave the same result. LSQLIN has a problem only when you give it bound constraints, due to the fact that a bound constrained problem forces it to use a different algorithm.
L=-3e10;
U=1e10;
x1=lsqlin(A,b,[],[],[],[],L,U)
Optimization terminated: relative function value changing by less
than sqrt(OPTIONS.FunctionTolerance), and rate of progress is slow.
x1 =
2.03201411306158
So LSQLIN could have done better, had it simply checked that A and b are scalars, and used a better (read that as simple) algorithm in that case. But LSQLIN was a bit dumb, and used an iterative method, that employs transformations. Those HUGE limits on the solution mess it up terribly.
For example, had I written this:
x1=lsqlin(A,b,[],[],[],[],1e6,1e8)
Optimization terminated: relative function value changing by less
than OPTIONS.FunctionTolerance.
x1 =
29930312.2600999
LSQLIN does a decent job, that gave around 9 correct digits or so. It still used an iterative method to solve the problem, when a simple divide, followed by a test to see if the result lay within the bounds would have sufficed.
But your bounds set a huge possible range for the result. So LSQLIN had to transform the problem, then it used an iterative scheme with a tolerance, and got a bit lost. Again, LSQLIN should be more intelligent here. But I think the author of LSQLIN never expected LSQLIN to be used for scalar division, so they never bothered to check for that case.
Let me try lsqlin with more reasonable bounds, to solve a real linear algebra problm as you might have posed it:
x1=lsqlin(s,z,[],[],[],[],1e6,1e8)
Optimization terminated: relative function value changing by less
than OPTIONS.FunctionTolerance.
x1 =
29930312.267375
x1=lsqlin(s,z,[],[],[],[],L,U)
Maximum number of iterations exceeded; increase OPTIONS.MaxIterations.
x1 =
298.5
These both try to solve the problem
s*x1 = z
where x1 is a scalar unknown variable. The difference is the width of the bounds.
By the way, I'm not sure why you are solving this problem, nor am I sure that s is the vector you REALLY want to be using. Note that roughly half of s is ZERO.
[s,z]
ans =
7.46355685131195e-06 -8287.20136961842
2.61224489795918e-07 -207.695733121256
-7.46355685131195e-06 -7600.97514253616
2.61224489795918e-07 -534.391927360151
0 -5646.81895072033
0 -842.92647329902
0 -2749.01799205948
0 -608.263953041959
0 -1800.96549474418
0 -218.233277809774
0 -1246.61121855062
0 -222.701572169097
0 -454.985962888617
0 -229.489284788134
2.61224489795918e-07 -207.695733121258
1.21904761904762e-08 -4.31159651230973
-2.61224489795918e-07 -211.583072054673
6.0952380952381e-09 -10.5817786869719
0 -207.469127449374
0 -19.4084812806167
0 -205.554052675241
0 -14.2334094340071
0 -127.980376432081
0 -5.82044377019796
0 -89.3993392954632
0 -10.0358904762527
0 -38.6028133285081
0 -12.8937660172881
-7.46355685131195e-06 -7600.97514253634
-2.61224489795918e-07 -211.583072054673
1.49271137026239e-05 -6704.83421266254
0 -532.664018086793
-7.46355685131195e-06 -4247.04164361325
2.61224489795918e-07 -784.667235831777
0 -374.396860142614
0 -575.355545468737
...
I'll stop there. So to solve the problem
s*x1 = z
see that roughly half of s is zero, so the residuals for those elements are always in the form of 0*x1 = z(i).
So I would bet that in reality whatever process created the vector s, there are truly some non-zero elements there that you theoretically WANTED to have as non-zero. But hey, what do I know?
Anyway, I expect that you will get upset at my response because I've told you that you don't understand what you are doing. But the facts are that you used the wrong equations to solve a problem, got lucky because scalar multiplication commutes where a matrix multiply would not have done so, then used LSQLIN without understanding what the bounds were doing to you. All of this suggests that you did not really understand what you were doing.
It is true that LSQLIN should be smart enough to see this is a scalar problem, and that they (the authors) could/should have special cased scalar problems without recourse to iterative methods and linear algebra. I'll assume only that nobody ever expected someone would have used lsqlin to divide one number into another number.
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