## Computing DWT

This is actually straightforward. Use `dwt`

to obtain the approximation and detail coefficients. For instance, a DWT using a daubechies 4-tap wavelet would be:

```
[cA, cD] = dwt(X, 'db4')
```

where `X`

is your data.

If each sample in `X`

has several fields, and you want to apply the DWT just on a certain field, say `X.closing_price`

, add square brackets:

```
[cA, cD] = dwt([X.closing_price], 'db4')
```

Note that this solution assumes that the data samples are taken at **constant time intervals**.

To plot the data, you need to prepare another vector, which corresponds to the day number:

```
t = 1:2:length(X);
```

The x-axis values skips every other day because the approximation and detail coefficients vectors each have half of the samples of `X`

.

## Demo code

The following code generates random data and puts it into an array of structs, each element having two fields: `date`

and `closing_price`

:

```
%# Generate some random data
C = cell(31, 2);
C(:, 1) = arrayfun(@(z)[num2str(z), '-Oct-03'], 1:length(C), 'Un', 0);
C(:, 2) = num2cell(100 * randn(1, length(C)));
X = cell2struct(C, {'date', 'closing_price'}, 2);
```

Now, to business:

```
%# Apply DWT
[cA, cD] = dwt([X.closing_price], 'db4');
%# Prepare x-axis values
t = 1:2:length(X);
%# Plot result with respect to date
figure
subplot(2, 1, 1), plot(t, cA)
title('Approximation coefficients'), xlabel('day'), ylabel('C_A')
subplot(2, 1, 2), plot(t, cD)
title('Detail coefficients'), xlabel('day'), ylabel('C_D')
```

This is what you should get:

Hope that helps!