README.md

# curve_fitting
# 1 #
linear_squares.m
```
function [ a,fx,r_2 ] = linear_squares(Z,y)
%linear-squares accepts a Z-matrix and dependent variable y and returns the
%vector of best-fit constants. This function allows for more reliable modeling of
%non-linear functions.

a = (Z'*Z)\(Z'*y); %calculate the parameters of function
fx = Z*a;
Sr = sum((y-Z*a).^2); %sum of the squares of the residuals
r_2 = 1-Sr/sum((y-mean(y)).^2); %calculate each elements distance from the regressionn line

end


```
### 1a. ###
```
%----Calculation of 1a.----------------------------

x = [1 2 3 4 5]';  %Column vector x
y = [2.2 2.8 3.6 4.5 5.5]'; % Column vector y
Z = [x.^0 x x.^-1];  %Compute Z matrix (from book)

[a, fx, r_2] = linear_squares(Z,y) %apply to linear_squares.m
x_fn = linspace(min(x),max(x));
% Plot to show fit
plot(x,y,'o',x_fn, a(1)+a(2)*x_fn+a(3)*x_fn.^-1);
title('Best fit case A');
xlabel('x');
ylabel('y');
```
Results:
```
a =
    0.3745
    0.9864
    0.8456
fx =
    2.2066
    2.7702
    3.6157
    4.5317
    5.4758
r_2 =
    0.9996
```
![fit1a] (fit1a.png)

### 1b. ###
```
%----Calculation of 1b.----------------------------
%Z matrix calculation altered to best fit polynomial
x = [3 4 5 7 8 9 11 12]';
y = [1.6 3.6 4.4 3.4 2.2 2.8 3.8 4.6]';
Z = [x.^0 x.^1 x.^2 x.^3];  %Compute Z matrix (from book)

[a, fx, r_2] = linear_squares(Z,y) %apply to linear_squares.m
x_fn = linspace(min(x),max(x));
plot(x,y,'o', x_fn, a(1)+a(2)*x_fn.^1+a(3)*x_fn.^2+a(4)*x_fn.^3);
title('Best fit case B');
xlabel('x');
ylabel('y');
```
Results:
```
a =
  -11.4887
    7.1438
   -1.0412
    0.0467
fx =
    1.8321
    3.4145
    4.0347
    3.5087
    2.9227
    2.4947
    3.2330
    4.9595
r_2 =
    0.8290
```
![fit1b] (fit1b.png)

### 1c. ###
```
%----Calculation of 1c.----------------------------
%Z matrix calculation altered to best fit polynomial
x = [0.5 1 2 3 4 5 6 7 9]';
y = [6 4.4 3.2 2.7 2.2 1.9 1.7 1.4 1.1]';
Z = [exp(-1.5.*x) exp(-0.3.*x) exp(-0.05.*x)];  %Compute Z matrix (from book)

[a, fx, r_2] = linear_squares(Z,y) %apply to linear_squares.m
x_fn = linspace(min(x),max(x));
% Plot to show fit
plot(x,y,'o',x_fn, a(1)*exp(-1.5.*x_fn)+a(2)*exp(-0.3.*x_fn)+a(3)*exp(-0.5.*x_fn));
title('Best fit case C');
xlabel('x');
ylabel('y');

```
Results:
```
a =
    4.0046
    2.9213
    1.5647
fx =
    5.9321
    4.5461
    3.2184
    2.5789
    2.1709
    1.8726
    1.6425
    1.4605
    1.1940
r_2 =
    0.9971
```
![fit1c] (fit1c.png)
# 2 #

### 2a ###

Function
```
function [cost, gradient] = cost_logisticV3(a, x, y)
% cost_logisticV3 Compute cost and gradient for logistic regression
%   cost = cost_logistic(theta, X, y) computes the cost of using theta as the
%   parameter for logistic regression and the gradient of the cost
%   w.r.t. to the parameters.

% ====================== YOUR CODE HERE ======================
% Compute the cost of a particular choice of a. Compute the partial derivatives and set grad to the partial derivatives of the cost w.r.t. each parameter in theta

cost = 0;       %initialize values
gradient = 0; %initalize a gradient
t = a(1).*(x.^0)+a(2).*x;  %time function
sigma = 1./(1+exp(-t));    %calculate sigma
cost = sum(-y.*log(sigma)- (1-y).*log(1-sigma)); %Calculation of cost
costFunction = @ (a) sum(-y.*log((1./(1+exp(-(a(1)+a(2).*x)))))-(1-y).*log(1-(1./(1+exp(-(a(1)+a(2).*x))))));
gradient = (1/length(x))*sum((sigma-y).*t); %Calculation of gradient
ai = [0 0]; %initialize a value for a

%---------------------- Plot of Regression -----------------------------
plot(x,y,'x', x, sigma);
title('Regression')
xlabel('Temp (Degrees Fahrenheit)')
ylabel('Pass or Fail (1 or 0)')

end
```
Script to optimize coefficients of A
```
%--------- Challenger_cost_logistic.m  ---------------------------
%The purpose of the script is to accept the O-ring data, and run it through
%a cost analysis that will also output a plot of the best fit model for
%part failures.

%--- Compile data from Challenger O-ring file -----------
challenger = [53,1;57,1;58,1;63,1;66,0;66.8,0;67,0;67.2,0;68,0;69,0;69.8,1;69.8,0;70.2,0;70.2,0;72,0;73,0;75,0;75,1;75.8,0;76.2,0;78,0;79,0;81,0];
x = challenger(:,1); % Independent variable x assigned to temperature
y = challenger(:,2);  % Dependent variable y assigned to status

% Set options for fminunc
options = optimset('GradObj', 'on', 'MaxIter', 400);
% Run fminunc to obtain the optimal theta
% This function will return theta and the cost
[theta, cost] = fminunc(@(a)(cost_logisticV3(a, x,y)), [20 -3]);  %Output the cost and gradient of data and graph and values of theta.
```
### 2b ###
theta = [a0,a1] = [16.9868,-0.2659]

### 2c ###
![Price of Tea in China] (Price of Tea in China.png)

# 3 #

### 3a ###
```
function sigma_z=boussinesq_lookup(q,a,b,z)
  % function that determines stress under corner of an a by b rectangular platform
  % z-meters below the platform. The calculated solutions are in the fmn data
  % m=fmn(:,1)
  % in column 2, fmn(:,2), n=1.2
  % in column 3, fmn(:,2), n=1.4
  % in column 4, fmn(:,2), n=1.6

  fmn= [0.1,0.02926,0.03007,0.03058  %provided data
        0.2,0.05733,0.05894,0.05994
        0.3,0.08323,0.08561,0.08709
        0.4,0.10631,0.10941,0.11135
        0.5,0.12626,0.13003,0.13241
        0.6,0.14309,0.14749,0.15027
        0.7,0.15703,0.16199,0.16515
        0.8,0.16843,0.17389,0.17739];

  m=a/z; %backslash operator to solve m
  n=b/z;    %backslash for n

  %------------- Building indices ---------------------------------------
  %Two loops designed to isolate the idices in the matrix that will be
  %interpolated between in the future
  mindex = [];
  b = sort(abs(fmn(:,1)-m));
  close2m = b(1:4);
  %Build indices for m values
  for j=1:4
      for i=1:8
          if close2m(j) == abs(fmn(i,1)-m)
              mindex=[mindex;i];
          end
      end
  end
  %Build indices for desired n values
  if n<1.2
      n=2;
  elseif n>1.6
      n=4;
  else
      n=int8((round(n*5)/5-1)/0.2+1);
  end
  %----------Value organization --------------------------------------
  %reference values of the previously found indices for n & m
  c=zeros(4,1);
  close2mtrue=zeros(4,1);
  for i=1:4 %organize values from the matrix
      close2mtrue(i) = fmn(mindex(i),1);
      c(i) = fmn(mindex(i),n);
  end

  sigma_z = q*ppval(interp1(close2mtrue,c,'cubic','pp'),m); %interpolation between the closest n & m values

end
```
### 3b ###
```
function sigma_z=boussinesq_splineV2(q,a,b,z)
  % function that determines stress under corner of an a by b rectangular platform
  % z-meters below the platform. The calculated solutions are in the fmn data
  % m=fmn(:,1)
  % in column 2, fmn(:,2), n=1.2
  % in column 3, fmn(:,2), n=1.4
  % in column 4, fmn(:,2), n=1.6

  fmn= [0.1,0.02926,0.03007,0.03058   %provided data
        0.2,0.05733,0.05894,0.05994
        0.3,0.08323,0.08561,0.08709
        0.4,0.10631,0.10941,0.11135
        0.5,0.12626,0.13003,0.13241
        0.6,0.14309,0.14749,0.15027
        0.7,0.15703,0.16199,0.16515
        0.8,0.16843,0.17389,0.17739];

  m=a/z;  %backslash operator to solve m
  n=b/z;    %backslash for n

  m1 = ppval(spline(fmn(:,1),fmn(:,2)),m);  % int. wrt to column 2
  m2 = ppval(spline(fmn(:,1),fmn(:,3)),m);  % int. wrt to column 3
  m3 = ppval(spline(fmn(:,1),fmn(:,4)),m);  % interpolate wrt column 4
  sigma_z = q*ppval(spline([1.2;1.4;1.6],[m1;m2;m3]),n); %interpolates across all previous interpolations
end
```
	# curve_fitting
	# 1 #
	linear_squares.m
	```
	function [ a,fx,r_2 ] = linear_squares(Z,y)
	%linear-squares accepts a Z-matrix and dependent variable y and returns the
	%vector of best-fit constants. This function allows for more reliable modeling of
	%non-linear functions.

	a = (Z'Z)\(Z'y); %calculate the parameters of function
	fx = Z*a;
	Sr = sum((y-Z*a).^2); %sum of the squares of the residuals
	r_2 = 1-Sr/sum((y-mean(y)).^2); %calculate each elements distance from the regressionn line

	end


	```
	### 1a. ###
	```
	%----Calculation of 1a.----------------------------

	x = [1 2 3 4 5]'; %Column vector x
	y = [2.2 2.8 3.6 4.5 5.5]'; % Column vector y
	Z = [x.^0 x x.^-1]; %Compute Z matrix (from book)

	[a, fx, r_2] = linear_squares(Z,y) %apply to linear_squares.m
	x_fn = linspace(min(x),max(x));
	% Plot to show fit
	plot(x,y,'o',x_fn, a(1)+a(2)x_fn+a(3)x_fn.^-1);
	title('Best fit case A');
	xlabel('x');
	ylabel('y');
	```
	Results:
	```
	a =
	0.3745
	0.9864
	0.8456
	fx =
	2.2066
	2.7702
	3.6157
	4.5317
	5.4758
	r_2 =
	0.9996
	```
	![fit1a] (fit1a.png)

	### 1b. ###
	```
	%----Calculation of 1b.----------------------------
	%Z matrix calculation altered to best fit polynomial
	x = [3 4 5 7 8 9 11 12]';
	y = [1.6 3.6 4.4 3.4 2.2 2.8 3.8 4.6]';
	Z = [x.^0 x.^1 x.^2 x.^3]; %Compute Z matrix (from book)

	[a, fx, r_2] = linear_squares(Z,y) %apply to linear_squares.m
	x_fn = linspace(min(x),max(x));
	plot(x,y,'o', x_fn, a(1)+a(2)x_fn.^1+a(3)x_fn.^2+a(4)*x_fn.^3);
	title('Best fit case B');
	xlabel('x');
	ylabel('y');
	```
	Results:
	```
	a =
	-11.4887
	7.1438
	-1.0412
	0.0467
	fx =
	1.8321
	3.4145
	4.0347
	3.5087
	2.9227
	2.4947
	3.2330
	4.9595
	r_2 =
	0.8290
	```
	![fit1b] (fit1b.png)

	### 1c. ###
	```
	%----Calculation of 1c.----------------------------
	%Z matrix calculation altered to best fit polynomial
	x = [0.5 1 2 3 4 5 6 7 9]';
	y = [6 4.4 3.2 2.7 2.2 1.9 1.7 1.4 1.1]';
	Z = [exp(-1.5.x) exp(-0.3.x) exp(-0.05.*x)]; %Compute Z matrix (from book)

	[a, fx, r_2] = linear_squares(Z,y) %apply to linear_squares.m
	x_fn = linspace(min(x),max(x));
	% Plot to show fit
	plot(x,y,'o',x_fn, a(1)exp(-1.5.x_fn)+a(2)exp(-0.3.x_fn)+a(3)exp(-0.5.x_fn));
	title('Best fit case C');
	xlabel('x');
	ylabel('y');

	```
	Results:
	```
	a =
	4.0046
	2.9213
	1.5647
	fx =
	5.9321
	4.5461
	3.2184
	2.5789
	2.1709
	1.8726
	1.6425
	1.4605
	1.1940
	r_2 =
	0.9971
	```
	![fit1c] (fit1c.png)
	# 2 #

	### 2a ###

	Function
	```
	function [cost, gradient] = cost_logisticV3(a, x, y)
	% cost_logisticV3 Compute cost and gradient for logistic regression
	% cost = cost_logistic(theta, X, y) computes the cost of using theta as the
	% parameter for logistic regression and the gradient of the cost
	% w.r.t. to the parameters.

	% ====================== YOUR CODE HERE ======================
	% Compute the cost of a particular choice of a. Compute the partial derivatives and set grad to the partial derivatives of the cost w.r.t. each parameter in theta

	cost = 0; %initialize values
	gradient = 0; %initalize a gradient
	t = a(1).(x.^0)+a(2).x; %time function
	sigma = 1./(1+exp(-t)); %calculate sigma
	cost = sum(-y.log(sigma)- (1-y).log(1-sigma)); %Calculation of cost
	costFunction = @ (a) sum(-y.log((1./(1+exp(-(a(1)+a(2).x)))))-(1-y).log(1-(1./(1+exp(-(a(1)+a(2).x))))));
	gradient = (1/length(x))sum((sigma-y).t); %Calculation of gradient
	ai = [0 0]; %initialize a value for a

	%---------------------- Plot of Regression -----------------------------
	plot(x,y,'x', x, sigma);
	title('Regression')
	xlabel('Temp (Degrees Fahrenheit)')
	ylabel('Pass or Fail (1 or 0)')

	end
	```
	Script to optimize coefficients of A
	```
	%--------- Challenger_cost_logistic.m ---------------------------
	%The purpose of the script is to accept the O-ring data, and run it through
	%a cost analysis that will also output a plot of the best fit model for
	%part failures.

	%--- Compile data from Challenger O-ring file -----------
	challenger = [53,1;57,1;58,1;63,1;66,0;66.8,0;67,0;67.2,0;68,0;69,0;69.8,1;69.8,0;70.2,0;70.2,0;72,0;73,0;75,0;75,1;75.8,0;76.2,0;78,0;79,0;81,0];
	x = challenger(:,1); % Independent variable x assigned to temperature
	y = challenger(:,2); % Dependent variable y assigned to status

	% Set options for fminunc
	options = optimset('GradObj', 'on', 'MaxIter', 400);
	% Run fminunc to obtain the optimal theta
	% This function will return theta and the cost
	[theta, cost] = fminunc(@(a)(cost_logisticV3(a, x,y)), [20 -3]); %Output the cost and gradient of data and graph and values of theta.
	```
	### 2b ###
	theta = [a0,a1] = [16.9868,-0.2659]

	### 2c ###
	![Price of Tea in China] (Price of Tea in China.png)

	# 3 #

	### 3a ###
	```
	function sigma_z=boussinesq_lookup(q,a,b,z)
	% function that determines stress under corner of an a by b rectangular platform
	% z-meters below the platform. The calculated solutions are in the fmn data
	% m=fmn(:,1)
	% in column 2, fmn(:,2), n=1.2
	% in column 3, fmn(:,2), n=1.4
	% in column 4, fmn(:,2), n=1.6

	fmn= [0.1,0.02926,0.03007,0.03058 %provided data
	0.2,0.05733,0.05894,0.05994
	0.3,0.08323,0.08561,0.08709
	0.4,0.10631,0.10941,0.11135
	0.5,0.12626,0.13003,0.13241
	0.6,0.14309,0.14749,0.15027
	0.7,0.15703,0.16199,0.16515
	0.8,0.16843,0.17389,0.17739];

	m=a/z; %backslash operator to solve m
	n=b/z; %backslash for n

	%------------- Building indices ---------------------------------------
	%Two loops designed to isolate the idices in the matrix that will be
	%interpolated between in the future
	mindex = [];
	b = sort(abs(fmn(:,1)-m));
	close2m = b(1:4);
	%Build indices for m values
	for j=1:4
	for i=1:8
	if close2m(j) == abs(fmn(i,1)-m)
	mindex=[mindex;i];
	end
	end
	end
	%Build indices for desired n values
	if n<1.2
	n=2;
	elseif n>1.6
	n=4;
	else
	n=int8((round(n*5)/5-1)/0.2+1);
	end
	%----------Value organization --------------------------------------
	%reference values of the previously found indices for n & m
	c=zeros(4,1);
	close2mtrue=zeros(4,1);
	for i=1:4 %organize values from the matrix
	close2mtrue(i) = fmn(mindex(i),1);
	c(i) = fmn(mindex(i),n);
	end

	sigma_z = q*ppval(interp1(close2mtrue,c,'cubic','pp'),m); %interpolation between the closest n & m values

	end
	```
	### 3b ###
	```
	function sigma_z=boussinesq_splineV2(q,a,b,z)
	% function that determines stress under corner of an a by b rectangular platform
	% z-meters below the platform. The calculated solutions are in the fmn data
	% m=fmn(:,1)
	% in column 2, fmn(:,2), n=1.2
	% in column 3, fmn(:,2), n=1.4
	% in column 4, fmn(:,2), n=1.6

	fmn= [0.1,0.02926,0.03007,0.03058 %provided data
	0.2,0.05733,0.05894,0.05994
	0.3,0.08323,0.08561,0.08709
	0.4,0.10631,0.10941,0.11135
	0.5,0.12626,0.13003,0.13241
	0.6,0.14309,0.14749,0.15027
	0.7,0.15703,0.16199,0.16515
	0.8,0.16843,0.17389,0.17739];

	m=a/z; %backslash operator to solve m
	n=b/z; %backslash for n

	m1 = ppval(spline(fmn(:,1),fmn(:,2)),m); % int. wrt to column 2
	m2 = ppval(spline(fmn(:,1),fmn(:,3)),m); % int. wrt to column 3
	m3 = ppval(spline(fmn(:,1),fmn(:,4)),m); % interpolate wrt column 4
	sigma_z = q*ppval(spline([1.2;1.4;1.6],[m1;m2;m3]),n); %interpolates across all previous interpolations
	end
	```