That's not possible. You have, in this case, 6 unknowns but only 1 equation.
How to find the vector b if we know the RMSE?
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If we have two vectors given by:
a=[3,6,8,20,35,45];
b=[3.0343, 6.2725, 8.5846, 18.3781, 34.2025, 44.9699];
Then its Mean Square Error MSE and Root Mean Sqaure Error RMSE are given by:
MSE = mean((a-b).^2,2);
RMSE = sqrt(MSE);
But if we know MSE and RMSE and one of the vector namely 'a', then how to find the 2nd vector b?
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John D'Errico
le 12 Jan 2023
There are infinitely many possible vectors b, for any given RMSE. And worse, they can have infinitely many possible shapes. This means it is flatly not possible to find a unique vector b that yields a given RMSE. Sorry.
Do you want proof?
a=[3,6,8,20,35,45];
b=[3.0343, 6.2725, 8.5846, 18.3781, 34.2025, 44.9699];
For example consider this simple vector b1:
n = length(a);
RMSEfun = @(b) sqrt(sum((a - b).^2/n));
syms x
rmsetarget = 1;
b1 = sym(a); b1(1) = x; % I will change only the first elememt of b
x1 = vpasolve(RMSEfun(b1) == rmsetarget,x)
b1 = double(subs(b1,x,x1))
RMSEfun(b1)
So by trivially changing one arbitrary element of a, I found a new vector b that yields exactly the desired RMSE. I could have perturbed ANY element and gotten the same result.
b2 = sym(a); b2(4) = x; % I will change only the first elememt of b
x2 = vpasolve(RMSEfun(b2) == rmsetarget,x)
b2 = double(subs(b2,x,x2))
RMSEfun(b2)
Or, I might have chosen b in a different way.
b3 = sym(a); b3 = b3*x; % I will change EVERY element of b, proportionally
x3 = vpasolve(RMSEfun(b3) == rmsetarget,x)
b3 = double(subs(b3,x,x3))
RMSEfun(b3)
Again, there are infinitely many solutions. I chose only 3 trivial examples.
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John D'Errico
le 13 Jan 2023
Modifié(e) : John D'Errico
le 13 Jan 2023
I will keep on saying it. You do not have sufficient information to solve for the unknowns. It is one equation only. And you have multiple unknowns. In your last example, we have:
a = [3,6,8,20];
With N and RMSE given, we have
N = 4;
RMSE = 1; % I'll just pick a number for RMSE
syms y [1,4]
N * RMSE^2 == sum((a - y).^2)
Do you recognize this as the equation of a sphere in 4 dimensions? If not, you should. The center of the sphere is the point a=[3 6 8 20], and the square of the radius is given here as 4=2^2.
But ANY point on the surface of that sphere is a solution to your problem. ANY point. Need I repeat that? ANY POINT. How many points lie on the surface of a sphere? (Infinitely many.)
There is NO solution to your question. You cannot solve for the unknown vector (here y or b as you prefer.) You can keep on insisting there is a solution, but the mathematics says you are completely wrong. There are infinitely many solutions and there is no way to choose any specific solution, beyond saying the solution lies SOMEWHERE on the surface of that sphere.
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