Need to solve the following equation with three knowns and 2 unknowns.

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Prabhath Manuranga on 21 May 2024

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Commented: Prabhath Manuranga on 30 May 2024

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W0 = Wi + (1 - L)*Hi*gi

W0 and L is an unknowns.

Wi, Hi, and gi are the knowns with 172 values per each.

I want to find W0 and L and their standard deviations as well.

I want to get each values comes for W0 and L when the program runs.

But when this code runs i got 0 for standard deviation of both W10 and L. Is this code is right? Can anyone help me to solve this?

The following code was written.

Wi = Wi;
Unrecognized function or variable 'Wi'.
Hi = H_BM;  
gi = g_mean;  
% Define the objective function
fun = @(x) norm(Wi + (1 - x(1))*Hi.*gi - x(2));
% Set initial guess for L and W0
x0 = [0, 0];
% Solve the optimization problem
x = fminsearch(fun, x0);
% Extract the values of L and W0
L = x(1);
L
W0 = x(2);
W0
% Calculate standard deviation of W0 and L
std_W0 = std(W0);
std_W0
std_L = std(L);
std_L

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Rik on 21 May 2024

Since you didn't post any data I can't show you what to do. You might want to try the fit function, since that will report the goodness of fit as the second output argument.

Prabhath Manuranga on 21 May 2024

data123.xlsx

Please find the attached excel file for Wi, H_BM, and g_mean values.

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Answer 1

Torsten on 21 May 2024

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H_BM = rand(100,1);
g_mean = rand(100,1);
Wi = rand(100,1);
Hi = H_BM;  
gi = g_mean;  
x = Hi.*gi;
y = Wi + Hi.*gi;
fitlm(x,y)
ans = 
Linear regression model:
    y ~ 1 + x1

Estimated Coefficients:
                   Estimate       SE       tStat       pValue  
                   ________    ________    ______    __________

    (Intercept)    0.41233     0.043102    9.5664    1.0575e-15
    x1              1.2316      0.15371     8.013    2.3796e-12


Number of observations: 100, Error degrees of freedom: 98
Root Mean Squared Error: 0.294
R-squared: 0.396,  Adjusted R-Squared: 0.39
F-statistic vs. constant model: 64.2, p-value = 2.38e-12

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Torsten on 21 May 2024

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data123.xlsx

format long
M = readmatrix("data123.xlsx")
M = 10x3
1.0e+07 *

   6.263682480329910   0.000000205900000   0.097810856393885
   6.263657062323940   0.000002802300000   0.097812165123015
   6.263669605757160   0.000001524500000   0.097811320851740
   6.263624373910401   0.000006129800000   0.097810680733666
   6.263620997894920   0.000006478400000   0.097810156445693
   6.263650330102171   0.000003480200000   0.097811560786981
   6.263682602864220   0.000000192100000   0.097810613817760
   6.263680818837160   0.000000373000000   0.097808759764806
   6.263617228951360   0.000006862700000   0.097809507129465
   6.263661105500140   0.000002381500000   0.097808297704551
<mw-icon class=""></mw-icon>
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Wi = M(:,1);
H_BM = M(:,2);
g_mean = M(:,3);
Hi = H_BM;  
gi = g_mean;  
x = Hi.*gi;
y = Wi;
fitlm(x,y)
ans = 
Linear regression model:
    y ~ 1 + x1

Estimated Coefficients:
                         Estimate           SE    tStat    pValue
                   _____________________    __    _____    ______

    (Intercept)         62636844.9371338    0      Inf       0   
    x1             -1.00231759363032e-05    0     -Inf       0   


Number of observations: 10, Error degrees of freedom: 8
R-squared: 1,  Adjusted R-Squared: 1
F-statistic vs. constant model: 4.65e+06, p-value = 2.4e-24
n = numel(Wi);
Mat = [ones(n,1),x];
rhs = y;
sol = Mat\rhs;
W0 = sol(1)
W0 = 
     6.263684493713374e+07
L = 1 + sol(2)
L = 
   0.999989976824064

Torsten on 27 May 2024

Edited: Torsten on 27 May 2024

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data123.xlsx

Note that the weights for "fitlm" must be the usual weights squared.

format long
M = readmatrix("data123.xlsx");
Wi = M(:,1);
H_BM = M(:,2);
g_mean = M(:,3);
Hi = H_BM;  
gi = g_mean;  
x = Hi.*gi;
y = Wi;
weights = 1./Hi / sum(1./Hi);
s = fitlm(x,y,'Weights',weights.^2)
s = 
Linear regression model:
    y ~ 1 + x1

Estimated Coefficients:
                         Estimate                    SE                   tStat                 pValue       
                   _____________________    ____________________    _________________    ____________________

    (Intercept)         62636844.9002729       0.535047793115774     117067756.761534    3.17482396862639e-62
    x1             -1.00215505545489e-05    1.32603813010255e-07    -75.5751311146224    1.04712464605067e-12


Number of observations: 10, Error degrees of freedom: 8
Root Mean Squared Error: 0.217
R-squared: 1,  Adjusted R-Squared: 1
F-statistic vs. constant model: 7.87e+05, p-value = 2.92e-21
Wohat = s.Coefficients.Estimate(1)
Wohat = 
     6.263684490027287e+07
Lhat = 1 + s.Coefficients.Estimate(2)
Lhat = 
   0.999989978449445
n = numel(Wi);
Mat = [weights,weights.*x];
rhs = weights.*y;
sol = Mat\rhs;
W0 = sol(1)
W0 = 
     6.263684490027288e+07
L = 1 + sol(2)
L = 
   0.999989978449443
syms W0 L
f = sum((weights.*(W0-(Wi + (1 - L)*Hi.*gi))).^2);
dfdW0 = diff(f,W0);
dfdL = diff(f,L);
sol = solve([dfdW0==0,dfdL==0],[W0,L])
sol = struct with fields:
    W0: 12040498260855305744269849528779227529092954537156824557392557339465700185329217840862105864303847686272978470720568140168141/192227087427943729367066220859610660420276...
     L: 57287562195798430748523865830601191935769536305576007891889226861407737951969429202951436538059542930491753/572881363117527155181962909876139940083851623062070447252942...
W0 = vpa(sol.W0)
W0 = 62636844.90027287747361312966808
L = vpa(sol.L)
L = 0.99998997844944439239438665630244

Torsten on 30 May 2024

Edited: Torsten on 30 May 2024

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Rename your variable "sum". "sum" is an inbuilt MATLAB function to sum elements, and you overwrite this function in your code.

If you are sure that sigma_e^2(V_n) equals what you compute as sum(n) (I doubt it because you don't sum anything when computing sum(n)), your Dw should be computed as

Dw = sqrt(sum(s(2:78)))

Here, I renamed you variable "sum" to "s" and used the MATLAB function "sum" to sum elements in an array.

According to the mathematical formulae, the sigma1 and beta1 are lower triangular matrices, and your "sum" variable is computed by summing both sigma1 and beta1 over their columns, adding the result and multiply it by (GM/alpha)^2.

Prabhath Manuranga on 30 May 2024

Thank you sir.

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Answer 2

Rupesh on 23 May 2024

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Hi Prabhat,

I understand that you want to calculate the values of W0 and L, and their standard deviations, from your given data using an optimization approach. The initial code calculates W0 and L but results in zero standard deviations because it operates on single scalar values instead of distributions (set of values) and single scalar values don’t have standard deviation associated with them.

To solve this, we can use a bootstrapping method. By repeatedly sampling your data and performing the optimization for each sample, we can obtain distributions of W0 and L. From these distributions, we can calculate the standard deviations.

Wi = Wi;  % Your known values 
Hi = H_BM;  % Your known values 
gi = g_mean;  % Your known values 
% Number of bootstrap samples 
num_samples = 100; 
% Arrays to store the results 
L_values = zeros(1, num_samples); 
W0_values = zeros(1, num_samples); 
% Perform bootstrap sampling 
for i = 1:num_samples 
    % Randomly sample indices with replacement 
    sample_indices = randsample(length(Wi), length(Wi), true); 
    
    % Sample the data 
    Wi_sample = Wi(sample_indices); 
    Hi_sample = Hi(sample_indices); 
    gi_sample = gi(sample_indices); 
    
    % Define the objective function for this sample 
    fun = @(x) norm(Wi_sample + (1 - x(1))*Hi_sample.*gi_sample - x(2)); 
    
    % Set initial guess for L and W0 
    x0 = [0, 0]; 
    
    % Solve the optimization problem for this sample 
    x = fminsearch(fun, x0); 
    
    % Store the results 
    L_values(i) = x(1); 
    W0_values(i) = x(2); 
end 
% Calculate mean and standard deviation of L and W0 
L_mean = mean(L_values); 
L_std = std(L_values); 
W0_mean = mean(W0_values); 
W0_std = std(W0_values); 
% Display the results 
disp(['L mean: ', num2str(L_mean)]); 
disp(['L std: ', num2str(L_std)]); 
disp(['W0 mean: ', num2str(W0_mean)]); 
disp(['W0 std: ', num2str(W0_std)]); 

This script repeatedly samples your data and runs the optimization to build up distributions for W0 and L, allowing for the calculation of their standard deviations. You can refer to below documentation to get clear understanding of inbuilt sample bootstrapping.

Need to solve the following equation with three knowns and 2 unknowns.

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