Ouch! OUCH! Let me just jump right in there and interrupt you before you continue down this path!

I know you're not a programmer, but at some point in life (apparently, this is yours!), you have to face the facts and become one, however momentarily. So know that programming is not really a science, it's an art, a craftsmanship if you will, and one that is all too easy to get wrong. Know also that there have been millions upon millions of programmers before you, who paved the way for you and found out which methods work best, and which methods lead to certain disaster.

I will describe six of these "roads-to-certain-doom" that are present in your code.

**First** on the list, is the use of `global`

. *DON'T USE GLOBAL VARIABLES!!* Sure, they are all-right for small, simple things, but the better, much more manageable, more durable, robust, much less error-prone way of passing data around is to do it *manually*. As a rule of thumb, create all top-level functions with as little dependencies to other functions/variables as possible. This is because global variables create a tight coupling between a program's state and a function's output, which makes reproducing any errors hard, if not impossible, and debugging (which is actually what any programmer spends most of his/her time on) a complete nightmare. Also, any function other than the one running can change them, so that

```
function testMe
global a;
a = 5*rand;
someFunction;
b = 4*a; % ERROR! or...will it?
function someFunction
global a;
a = a/5;
if a < 0.5
someOtherFunction; end
function someOtherFunction;
global a;
a = {'my string'};
```

will *sometimes* work, and *sometimes* fail. An example of something worse that can happen:

```
function testMe
global a, b;
a = 5; b = 6;
result = someCalculation;
result = a*b*result;
function someFunction
global a;
a = sin(pi/rand); % INTENTIONAL
% do LOTS of stuff here
for a = 1:10 % OOPS! unintentional use of variable name
% do stuff
if (some weird condition)
break; end
end
```

There will be no error, no warning, nothing, but your results will still be garbage. And as your functions grow larger (and they WILL, usually), this error gets harder and harder *and harder* to find. It's not uncommon to spend a good few days on finding this sort of mistake.

In your code, you also change the global variables `a`

and `b`

inside the loops. This means that any function/script that uses `a`

and `b`

, that gets called *after* this one completes, will see `a=10`

and `b=10`

. Now suppose you call a function *inside* those loops, that changes the value of `a`

. What will the value of `a`

be on the next iteration of the `a`

-loop? Suppose also you get erroneous results. How would you go about finding that error?

Code like this is usually called "spaghetti code", for obvious reasons. Perhaps it will work, and is easy to code, but in the end it will always slow you down tremendously (not to mention the one who inherits your code).

A much better approach that prevents most of this is to collect data in larger containers, and explicitly pass them around. Say we use a `struct`

for the data `a-l`

:

```
data = struct(...
'a', a,...
'b', b,...
'c', c,...
'd', d,...
'e', e,...
'f', f,...
'g', g,...
'h', h,...
'l', l);
```

So that you can say

```
result = myFunction(data);
```

Accessing data inside `myFunction`

goes like this: `data.a`

to get the value for `a`

, or `data.f`

for the value of `f`

, etc. Saying `data.k = 5;`

in `myFunction`

*will not change* the `result`

, or the original `data`

passed to the function -- you have broken the tight coupling and prevented all the aforementioned problems.

Type `help struct`

or `help cell`

in the Matlab command window to learn about these sorts of generic containers.

**Second** on the list is using the variable name `l`

. It's somewhat silly, and I can be short about this: don't do that :) Contrary to what most people (and even some programmers) believe, you *write* a line of code only once, but you *read* it hundreds, if not thousands of times. The best practice is to make the *reading* as easy as possible, not the *writing*. The `l`

just looks like the `1`

, doesn't it? The bug `k=1`

vs `k=l`

is simply harder to spot than `k=m`

vs `k=1`

.

**Third** on the list is the keyword `transpose`

. It's kinda verbose, isn't it? In math, you would use A^{T}, which is much easier on the eyes than writing the full definition all of the time:

B = { A_{ij} ➝ A_{ji} ∀ i < m ⋏ j < n

you normally just say B = A^{T}. Same in Matlab. The `transpose`

of a matrix can be accomplished like so:

```
Actrans = A' ; % conjugate transpose
Atrans = A.'; % regular transpose
```

which reduces your code to the much less verbose

```
A = [1 3;3 2];
B = [a 0;0 b];
C = [d 0;e f];
D = [sqrt(d) 0;0 sqrt(f)];
E = C.'/D;
K = A+E;
M = E*D*E.';
```

**Fourth** on the list is the equality `K==M`

. As it stands here, `K`

and `M`

are *matrices*. The expression `K==M`

is evaluated *element-wise*, for reasons that will become obvious later in your programming career :) This means that `K==M`

will be again a matrix, the same size as `K`

and `M`

, containing `0`

if corresponding elements in `K`

and `M`

are not equal, and `1`

if these elements are equal. So, what will an `if`

-statement do with such a matrix? In Matlab, it will be `true`

whenever the *first* element is true (in my opinion, it should throw an error, but oh well).

This is obviously not what you want. what I think you want is that *all* elements in both matrices are equal. It's best you use this:

```
if all( abs(K(:)-M(:)) < eps )
```

where the `(:)`

-notation means that the matrix `K`

and `M`

should be expanded to column-vectors prior to the comparison. This is because `all()`

works down a single dimension, so `all(K==M)`

would *still* be a matrix (vector, actually, but that's a different name for a special case of the same thing). Notice that I don't use equality (`==`

), but rather check whether their difference is smaller than some tiny value (`eps`

). This is because in floating-point arithmetic (which all computers use), operations like multiplication and square root usually suffer from things like round-off error and approximation/interpolation error. An *equality* is a very tough demand, too tough to evaluate to `true`

in most cases where it mathematically speaking should. You can prevent this failure to detect the equality by comparing the *difference* of the two to a tiny value that's related to round-off error (`eps`

).

**Fifth** on the list is the way you print things. The `print`

statement, by itself, will send a figure to the system's default printer, you know, that moody machine that spits out paper with ink on it if it feels like cooperating today :) Now, I assume you were trying to *display* things on the screen. Doing it like the way you set out to display things is not the best way: you'll get a dozen times this list of unnamed, unstructured values:

```
1 % which would be the value of 'a'
1 % which would be the value of 'b'
3 % which would be the value of 'd'
4 % which would be the value of 'e'
5 % which would be the value of 'f'
...
```

Seeing only the values appear makes reading and interpreting what's going on rather tedious. Better use something more descriptive:

```
if all( abs(K(:)-M(:)) < eps )
% option 1
a
b
d % NOTE: not terminating with semicolon
e
f
% option 2
fprintf(...
'a: %d\n, b: %d\n, d: %d\n, e: %d\n, f: %d\n\n', a,b,d,e,f);
end
```

Option 1 will just show

```
a =
1
b =
1
etc.
```

which at least also shows the variable's name alongside its value. Option 2 is the nicer one:

```
a: 1
b: 1
d: 3
e: 4
f: 5
a: 1
b: 2
d: 3
e: 4
f: 5
etc.
```

(As an aside, the values `a,b,d,e,f`

*never change* in the loops, so why would you want to show them in the first place?)

**Sixth** (and last!) on the list, is one that is specific to Matlab: `for`

-loops. Matlab is an interpreted, matrix-based language. Its matrix nature simply means that every variable is in essence, a matrix. Interpreted means that your code will not *directly* be seen by the computer's processor, it will have to go through a series of interpretations and translations before anything gets calculated. This coin has two sides:

- it can speed things up (like coding, or doing "trivial" things like solving linear systems, FFT, comparisons of matrices, etc.)
- it can slow things down (like repeated execution of statements, like in a loop)

In light of performance, the `for`

-loop is notorious in Matlab for bringing operations to a crawl. The way to go in Matlab is usually *vectorized* code, e.g., use the fact that all variables are matrices, and use matrix/tensor operations on them instead of loops. This is not a very common approach in most programming languages (and you'll see a lot of strong, heated resistance to it in programmers not accustomed to it), but in a mathematical context it makes a whole lot of sense. Always try to use matrix/tensor operations as a first line of attack (and Matlab has *a lot* of them, mind you!) before resorting to for-loops.

So, *that's* what's wrong with your code :) Oh yeah, and as Andreas Hangauer already mentioned, place the statements referring to `a`

through `l`

, and all that needs to be re-calculated accordinly, inside the loop, and you'll be fine.