Today I ran into a problem with precision in Matlab:

```
Tp = a./(3600*sqrt(g)*sqrt(K).*u.*Sd*sqrt(bB))
```

where

a =

```
346751.503002533
```

g =

```
9.81
```

bB =

```
2000
```

Sd =

```
749.158805838953
848.621203222693
282.57250570754
1.69002068665559
529.068503515487
```

u =

```
0.308500000000039
0.291030000000031
0.38996000000005
0.99272999999926
0.271120000000031
```

K =

```
3.80976148470781e-009
3.33620420353532e-009
1.67593037457502e-008
7.22952172629158e-005
9.89028880679124e-009
```

Apparently, due to the calculations of variables of different dimensions, I get a problem with the computer precision:

Tp =

```
48.2045906674902
48.2045906674902
48.2045906674902
48.2045906674902
48.2045906674902
```

Unfortunately, I do not really know how to handle this. I played around with the output format, but this is not the issue. So I assume that it really is the internal computation precision that gets me. However, if I calculte sqrt(K).*u or u.*Sd by itself I do get reasonable values. Only once I multiply all the 3 matrices together I get the same value as a result, although it should vary. I found this thread, but my case is slightly different, because I do not get arbitrary values, but they are all the same for some reason: numerical issue when computing complementary projection

I also thought that scaling all variables like so: Sd = Sd/max(Sd) might help, but since I need a farily accurate and dimensonally correct result, this would not help.

Even when using

```
vpa(a./(3600*sqrt(g)*sqrt(K).*u.*Sd*sqrt(bB)))
```

I get the same value each time, but with more digits. Why is this?

I hope you can help me. Cheers

Edit: Here is more of the code for a better grasp of my problem:

```
Al = 2835000000; % [m^2]
Qp = 3000000; [m^3*s^-1]
% draw 100 uniformally distributed values for s & r
s = 600 + (8000-600).*rand(100,1);
r = 600 + (15000-600).*rand(100,1);
% calculate Sd & Rd
Sd = 680./s;
Rd = 680./r;
figure
subplot(2,1,1)
hist(Sd)
subplot(2,1,2)
hist(Rd)
%% calculate my numerically
% calculate sigma
sig = Sd./Rd;
% define starting parameters for numerical solution
t = -1*ones(size(sig));
u = zeros(size(sig));
f = zeros(size(sig));
% define step
st = 0.00001;
% define break criterion
br = -0.001;
% increase u incrementally by st until t <= br
for i=1:length(sig)
while t(i)<br
while t(i)<-0.1
f(i) = sig(i)*u(i)/sqrt(pi); % calculate f for convenience
ierfc = exp(-f(i)*f(i))/sqrt(pi) - f(i)*erfc(f(i)); % calculate integral of complementary error function
t(i) = (u(i)/sqrt(pi))*erfc(-f(i))*(1+sig(i))-ierfc
u(i) = u(i) + st*1000
end
while t(i)>=-0.1&& t(i)<br
f(i) = sig(i)*u(i)/sqrt(pi); % calculate f for convenience
ierfc = exp(-f(i)*f(i))/sqrt(pi) - f(i)*erfc(f(i)); % calculate integral of complementary error function
t(i) = (u(i)/sqrt(pi))*erfc(-f(i))*(1+sig(i))-ierfc
u(i) = u(i) + st;
end
end
end
figure
hist(u)
%% calculate K from Qp
K = 3/2*pi*(Qp^(2/3)*bB^(1/3))./(g^(1/3)*u.^2.*Sd.^2*Al);
%% calculate Tp
% in hours!
Tp = (3/2*sqrt(6*pi)*sqrt(Al))./(3600*sqrt(g)*sqrt(K).*u.*Sd*sqrt(bB));
```