Well, it's not trivial for me either but this is how i understand it. If i've over simplified it is purely for my benefit, i don't mean to be patronising.

*Zeroing the result corresponding to the Nyquist frequency:*

I'm going to suppose we are computing the forward FFT of 1024 input samples. At 44100hz input this is usually true in my case (but isn't what AurioTouch is doing, which i find a bit weird, but i'm no expert). It's easier for me to understand with specific values.

Given 1024 (n) input samples, arranged as needed (even indexes' first then odd indexes' { in[0], in[2], in[4], …, in1, in[3], in[5], … }) (use `vDSP_ctoz()`

to order your input)

The output of FFT **1024** (n) input samples is **513** ((n/2)+1) complex values. ie **513 real** components and **513 imaginary** components, a total of **1026** values.

However, **imaginary[0]** and **imaginary[512]** (n/2) are always, necessarily, **zero**. So by placing **real[512]** (the real component of the Nyquist frequency bin) at **imaginary[0]** and forgetting **imaginary[512]** - which is always zero and can be inferred, the results are packed into an **1024** (n) length buffer.

So, for the returned results to be valid you must at least set **imaginary[0]** back to zero. If you require all **513** ((n/2)+1) frequency bins you need to append another complex value to the result and set it thus..

```
unpackedVal = imaginary[0]
real[512]=unpackedVal, imaginary[512]=0
imaginary[0] = 0
```

In AurioTouch i always supposed they just don't bother. n/2 results is obviously more convenient to work with and you can hardly tell from the visualizer:- "*Oh look, it's missing one magnitude at the Nyquist frequency*"

The UsingFourierTransforms docs explain the packing

**NB the specific values 1024, 513, 512, etc. are examples not the actual values of n, (n/2)+1, n/2 from AurioTouch.**

*They scale everything down by -128db*

Not quite, the range of the output values is *relative to the number of input samples* so it has to be normalised. The scale is 1.0/(2*inNumberFrames).

After scaling the range is **-1.0 –> +1.0**. The magnitude of the complex vector is then taken (the phase is ignored) giving a Scalar value for each frequency bin between **0 and 1.0**

This value is then interpreted as a decibel value between **-128 and 0**

The drawing stuff… +80 / 64. …*120… …i'm not sure. I may be completely wrong or it may be …artistic license?