## EDIT:

Thank you @yoda and @morispaa. You are both right and @morispaa's solution works, i.e. my processing of the transformed coefficients, which is based on assumptions about the space spanned by **Z**, and the **order** and **"orientation"** of the **Z** vectors, renders the correct result if I update the sign of the columns of **Q** so that the diagonal of **R** has positive elements.

For more details about the transformation I am working on you can read this; **Z** below = sampled Zernike polynomials, which are known for **not** being orthogonal nor complete on the discrete case (our case).

### Intuition on why the solution proposed by @morispaa works. I would love to hear your input about it:

My intuition is that somehow enforcing **real non-negative diagonals** in **R** renders a basis **Q** that "**aligns**" better with the vectors in **Z** (which, as I said earlier, is non-unitary), and therefore the Options 1 and 2 below, even though they represent different transformations, output coefficients probably in a similar space.

More specifically, I think **Z** is "almost" unitary, and maybe this leads the **QR** decomposition to return a basis that is close enough to **Z**? Only then I can imagine that my processing of the transformed coefficients, which is based on assumptions about the specifics of the vectors in **Z**, work when the diagonal of **Q** is fully positive, but not when it has negative entries. What do you think?

## Background

I have both MATLAB **R2011a** and **R2010b** installed on my machine.

One of the changes from **R2010b** to **R2011a** affects the implementation of `qr()`

(see the release notes about this particular change here).

An important part of one my projects uses `qr()`

to estimate an orthogonal basis for a direct and inverse transformation. My code applies this transformation to an input signal, processes the transformed coefficients and returns back the processed signal. In other words, the changes made in **R2011a** to `qr()`

made the block that process the coefficients of this transformation to stop working (the inverse transformation does not return the expected inverse transformation of the processed signal).

Somehow the **Q** matrix that is now returned from `qr()`

is different from the older version in a way that prevents the processing of the transformed coefficients from working properly.

## First question

In light of the above, is it possible to tell **R2011a** to use `qr()`

from **R2010b**?

## Second question

I use **Q** and **Q'** to compute the direct and inverse transformation; you can see more details **here**. More specifically, I use **y = Q * x** and **x = Q' * y** to compute the direct and inverse transformation respectively. A different way to compute the direct transform is using least squares. In other words we have two options:

**Option 1: Direct and inverse transform using QR factorization:**

```
% Direct:
[Q R] = qr(Z);
y = Q' * x;
% Some processing of the y coefficients
% ...
% Inverse:
x = Q*y;
```

**Option 2: Direct and inverse transform via least squares fitting**

```
% Direct:
y = Z \ x;
% Some processing of the y coefficients
% ...
% Inverse:
x = Z*y;
```

where our variables are:

```
% x = Input vector
% y = Direct transformation of x
% Z = Matrix with sampled basis
```

In **R2011a** the Option 1 above **stopped working** (it works in **R2010b**). I really like the idea of using `qr()`

for the direct and inverse transform (it's much faster than computing least-squares for every new vector). If I wanted to use the new `qr()`

for my project, does anybody know how to make my transformation work again with the new **Q**?

`qr()`

differ? Is it completely broken? Or is it simply tiny numerical discrepancies that could be attributed to standard floating-point issues? It it's the latter, if your entire application is breaking, it's probably a sign that your algorithm is not numerically stable. (I appreciate that this is not a very helpful response to your question...) – Oliver Charlesworth May 2 '11 at 19:04Qmatrices returned by the new and old version (I think the`QR`

factorization is not unique). The new`qr()`

is probably correct, but the new factorization does not satisfy the same properties that the old one did. I think the problem comes from the non-negativity of the diagonal of theRmatrix, a property that was guaranteed in the previous version, but not in the new one, and that somehow affects the matrixQas well. – Amelio Vazquez-Reina May 2 '11 at 19:18