Generalised solution to a n-order system of equations

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I want to solve (for the first term) of a system of n-1 equations, in terms of n. How should I do it?
Essentially I want to solve for a_1 in terms of n:
(This holds for all k=1,...,n-1).
For example, with n=4, I have these 3 equations I would like to solve:
.
Once can check that satifies this set of equations. In my example, I only want .
As a more general example, this is the set of (n-1) equations:
I can write the code to solve for specific n, (like n=4 above). However, I would like to have a general formula in terms of n.
How do I code this in MatLab? I always meet a lot of errors complaining about the general formula. Thank you.
  7 Comments
Aden
Aden on 12 Sep 2024
Edited: Torsten on 12 Sep 2024
@Torsten Here is my code, that provies a range of answers from a to b, inclusive.
% Example usage:
rangeSolutions(50,60);
n = 50: a1 = 24658466561372956606072219961585730241/200607444499636329906942199843718400 n = 51: a1 = 12095999817020908880806839172705842001/96381539428995418649814967947304320 n = 52: a1 = 296876662512585342903233000603819451373/2320227363430068965267573684590128000 n = 53: a1 = 145731168343163320419788860702885530923/1116316881358922544654288513268944000 n = 54: a1 = 131520038262372525763519193012546565211519/988946436362361212004404709873169728000 n = 55: a1 = 581429164068787472552498392939187591167489/4288711995721745855579202703142204736000 n = 56: a1 = 6172537074853875344545662543105451222283579/44719649242486541205586769842909654579200 n = 57: a1 = 30337972180019584268050518807218304758008109/215748762540829378179114736330044825456000 n = 58: a1 = 50635315839505187203721653607779887624851161/353936768935701591008964408883034189952000 n = 59: a1 = 821748863224299748123697346539124438846061261/5642413690350518644235221494358721275968000 n = 60: a1 = 2767201210279121773176706567854579026542586813041/18685182779533599510203630089217208636299136000
function rangeSolutions(a, b)
% Loop from A to B
for n = a:b
aSym = sym('a', [n-1, 1]);
eqns = sym(zeros(n-1, 1));
% Create the equations
for k = 1:n-1
eqns(k) = 2*k*aSym(k) == sum(aSym(1:min(n-1, 2*k))) + 2*k;
end
% Solve
sol = solve(eqns, aSym);
% Check if the solution is empty
if isempty(sol)
a1Solution = 'No solution';
else
% Extract a1
a1Solution = char(sol.a1); % Convert to string
end
% Print the solution "n = (n): a1 = (a1)"
fprintf('n = %d:\n', n);
fprintf(' a1 = %s\n', a1Solution);
fprintf('\n');
end
end
John D'Errico
John D'Errico on 12 Sep 2024
Thank you for your clarification. It was not at all clear what you meant at first, but I see your question now. It is actually an interesting one, IMHO, that gets into the linear algebra of how you solve such a question.
I'll post an answer now, first, in terms of how I would solve it for specific n, and then look to see how we might generalize it for any n.

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Accepted Answer

David Goodmanson
David Goodmanson on 13 Sep 2024
Edited: David Goodmanson on 14 Sep 2024
HI Aden,
Here is a method that produces, within 4.5 %, the experimental value a_1 = 2.518. The equation is (for simplicty n-1 is replaced by n since it is the same problem)
a_k = 1 + (1/2k) Sum{j = 1,min(n,2k)} a_j k = 1...n (1)
The value of a_k depends on all of the a's up to a_2k. Suppose that there are no restrictions set by n, so that the upper sum limit of 2k is always allowed. Then for any constant C the solution
a_k = nC -2(k-1) (2)
is exact. So for smaller values of k, that would appear to be the solution. That can't be the whole story, though, because the boundary conditions up at k = n seem to propagate down and have an effect. The lower half of the plot ends up being almost, but not quite linear.
For k >n/2 the sum index is fixed from 1 to n and the sum is a constant. Then from (1),
a_k = 1 + D/k exact (3)
for some constant D is exact for all k > n/2.
The plot of (a_k) /n for n=1000 is the blue line here. Experimentally it is almost linear all the way up to k = n/2 and then has the 1/k behavior of (3). Its slope in the almost-linear region is close to [ -2 / 1000 ] as expected.
The value of D can be determined experimentally from the upper half of the blue line, where D = k*(a_k -1) should be a constant for n/2<k<n, which it is.
The approximate calculation done below gives the red and yellow lines in the plot. For this calculation, from (2)
a_1 = nC (4)
a_(n/2) = nC - 2(n/2 -1) ~~ n(C-1)
where we start retaining only the highest powers of n. Also from (3)
a_(n/2) = 1 + D/(n/2) ~~ D/(n/2)
a_n = 1 + D/n ~~ D/n
Dropping the 1 is justified since it's already known that a(n/2) ~~ n(C-1). Equating the two values of a_(n/2) gives
D = (n^2/2)(C-1)
Now C can be determined by comparing both sides of (1) for k = n. From (3) the left hand side is
a_n = ~~ D/n = (n/2)(C-1) (5)
On the right hand side, the sum of the trapezoidal portion (using (4) and not including the 1/2n factor) is
~~ (1/2)(nC +n(C-1)) (n/2) = (n^2/4)(2C-1)
and the sum for the 1/k portion is by approximate integration
D Sum{k=n/2,n} (1/k) ~~ D log(2) ~~ (n^2/2) (C-1) log(2)
Equating both sides and now including the 1/2n factor
(n/2)(C-1) = (1/2n) ( (n^2/4)(2C-1) + (n^2/2) (C-1) log(2)
solve for C:
C = (3/2-log(2))/(1-log(2)) = 2.6294
and from (4),
a_1 /n = C
which is too large by about 4.5%.
  5 Comments
Aden
Aden on 15 Sep 2024
Hi, I see. I understand your explanation and am convinced by it. Thank you for your detailed explanation!
However, one thing holding me back is the experimental values. Somehow, it really looks like it converges to the experimental 2.517782 instead of the theoretical 2.6294. Here is the database: https://docs.google.com/spreadsheets/d/1K-MNti6u8QtdoZlhCqj-AKb8KngqLhrSU9VpvI1Cmr0/edit?usp=sharing
Instead of directly finding the ratio , I figured that a better way was to find the difference between the terms (as in, ( for n equations) - ( for n-1 equations)). This way, it would converge faster.
David Goodmanson
David Goodmanson on 15 Sep 2024
Edited: David Goodmanson on 15 Sep 2024
Hi Aden,
The model value of 2.63 is only an approximate value, which is not too bad since it is within 4.5% of the real result, which is probably very close to 2.5177.... The 'theoretical' model value It was never intended to be taken as the actual answer. That's because model presumes the lower half of the plot to be linear, wheras the real calculation shows that it is close to, but actually not, linear. So there will be correction terms to the model, but I don't know how to obtain them. Your difference idea definitely seems worth trying.

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More Answers (2)

John D'Errico
John D'Errico on 12 Sep 2024
Edited: John D'Errico on 12 Sep 2024
(Edited to fix my error in extrapolating your equation system. I had not seen at first you were essentially adding two terms to each equation for increasing k.)
For ANY value of n, you have n-1 unknowns, and n-1 equations. But all you want to do is to compute a_1, disregarding the other unknowns. And that would seem reasonable. Well, maybe possible.
I can create the problem in matrix form, as such:
function [A,b] = Ab(N)
[K,J] = ndgrid(1:N-1);
A = diag(2*(1:(N-1))) - (2*K >= J);
b = 2*(1:(N-1))';
end
As you can see, I combined all terms into one matrix A.
[A,b] = Ab(4)
A = 3×3
1 -1 0 -1 3 -1 -1 -1 5
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b = 3×1
2 4 6
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The complete solution for n==4 is then
format rat
A\b
ans =
27/4 19/4 7/2
First, we should notice that A is always full rank. Just by looking at A in general, that would seem clear, but a proof should not be impossible.
[A,b] = Ab(5)
A =
1 -1 0 0 -1 3 -1 -1 -1 -1 5 -1 -1 -1 -1 7
b =
2 4 6 8
A\b
ans =
51/5 41/5 29/5 23/5
[A,b] = Ab(6);
A\b
ans =
911/76 759/76 149/19 233/38 97/19
And that clearly works, at least for specific values of n to yield the same result you have.
One idea might be to look at the LU factors of A. Note they are quite well behaved as n grows. For example:
[A,b] = Ab(7);[L,U] = lu(A)
L =
1 0 0 0 0 0 -1 1 0 0 0 0 -1 -1 1 0 0 0 -1 -1 -1/2 1 0 0 -1 -1 -1/2 -3/5 1 0 -1 -1 -1/2 -3/5 -6/19 1
U =
1 -1 0 0 0 0 0 2 -1 -1 0 0 0 0 4 -2 -1 -1 0 0 0 5 -3/2 -3/2 0 0 0 0 38/5 -12/5 0 0 0 0 0 168/19
[A,b] = Ab(8);[L,U] = lu(A)
L =
1 0 0 0 0 0 0 -1 1 0 0 0 0 0 -1 -1 1 0 0 0 0 -1 -1 -1/2 1 0 0 0 -1 -1 -1/2 -3/5 1 0 0 -1 -1 -1/2 -3/5 -6/19 1 0 -1 -1 -1/2 -3/5 -6/19 -5/14 1
U =
1 -1 0 0 0 0 0 0 2 -1 -1 0 0 0 0 0 4 -2 -1 -1 0 0 0 0 5 -3/2 -3/2 -1 0 0 0 0 38/5 -12/5 -8/5 0 0 0 0 0 168/19 -40/19 0 0 0 0 0 0 78/7
Noting that as n grows, it is only the last column of L and U that seem to change, I might not be surprised if one could write those factors down in some simple form. I don't see how at the moment, but it might be worth looking at. And you can recover the solution as
U\(L\b)
ans =
7939/468 7003/468 235/18 424/39 347/39 887/117 259/39
A nice thing about LU factors is, if you are careful, you can get the last element of the solution, knowing only L, and the last diagonal element of U. And if we flip the matrix A from left to right, which is equivalent to resequencing the unknowns in reverse order....
[L,U] = lu(fliplr(A));
C = L\b;
C(end)/U(end,end)
ans =
7939/468
I hope you see where I am going. If we could write down the LU factors, in a simple way as a function of N, for the flipped (left to right) matrix A, then solving for the FIRST element of a becomes simple. All you need to know is a way to compute the factro L, as well as the last diagonal element of U. A very nice thing about this is it might also give you a way to prove the long term (linear with n) behavior of the first element of a.
  2 Comments
Aden
Aden on 12 Sep 2024
Edited: Aden on 12 Sep 2024
Hi! I'm not sure that your code here matches the sum in the question.
"A_n = @(n) diag(2*(1:(n-1))) - tril(ones(n-1),1);
b_n = @(n) 2*(1:(n-1))';"
However, is this matrix correct for A?
For n=5, the matrix produced should be
1 -1 0 0
-1 3 -1 -1
-1 -1 5 -1
-1 -1 -1 7
For row k < n/2, the number of "-1"s above the main diagonal should be increasing by 2 every row you go down.
(For n=5, a1 should be 51/5. For n=6, a1 should be 911/76.)
As such, your answer limit 7.2668730... is not the same as mine of 2.51778...
Thank you for your answer regardless though!
John D'Errico
John D'Errico on 12 Sep 2024
Edited: John D'Errico on 12 Sep 2024
No problem. I was in a hurry, so I'll check things over. I hope perhaps my re-written answer may give you a direction to follow.

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Torsten
Torsten on 12 Sep 2024
Edited: Torsten on 12 Sep 2024
Here is my code, that provies a range of answers from a to b, inclusive.
Besides that you shouldn't give the same names to the lower bound of your range and the symbolic array a, what is your question ?
I used the below code, and it seems to give similar results as yours. The behaviour of a1 with n looks quite linear - that's why I made a linear fit at the end.
nmax = 25;
a1 = sym('a1',[nmax,1]);
for n = 1:nmax
a = sym('a',[n 1]);
for k = 1:n
ub = min(n-1,2*k);
eqn(k) = 2*k*a(k)==sum(a(1:ub))+2*k;
end
[A,b] = equationsToMatrix(eqn,a);
sol = A\b;
a1(n) = sol(1);
end
a1 = double(a1);
M = [ones(nmax,1),(1:nmax).'];
rhs = a1;
sol = M\rhs;
hold on
plot(1:nmax,a1)
plot(1:nmax,sol(1)+sol(2)*(1:nmax))
hold off
grid on
  4 Comments
John D'Errico
John D'Errico on 12 Sep 2024
Still writing. It will take an extra hour though, as my wife is asking for a boat ride. ;-) But yes, my hope is to see if a solution exists as a function of n, and possibly as a limit.
Torsten
Torsten on 12 Sep 2024
Edited: Torsten on 12 Sep 2024
May I ask about the context in which this problem appeared ?
Is this a special field of investigation ?
Try asking the question in a pure maths forum:

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