In the paper "The Riemann Hypothesis" by J. Brian Conrey in figure 6 there is a plot of the Fourier transform of the error term in the prime number theorem. See the plot to the left in the image below:

In a blog post called Primes out of Thin Air written by Chris King there is a Matlab program that plots the spectrum. See the plot to the right at the beginning of the post. A translation into Mathematica is possible:

Mathematica:

```
scale = 10^6;
start = 1;
fin = 50;
its = 490;
xres = 600;
y = N[Accumulate[Table[MangoldtLambda[i], {i, 1, scale}]], 10];
x = scale;
a = 1;
myspan = 800;
xres = 4000;
xx = N[Range[a, myspan, (myspan - a)/(xres - 1)]];
stpval = 10^4;
F = Range[1, xres]*0;
For[t = 1, t <= xres, t++,
For[yy=0, yy<=Log[x], yy+=1/stpval,
F[[t]] =
F[[t]] +
Sin[t*myspan/xres*yy]*(y[[Floor[Exp[yy]]]] - Exp[yy])/Exp[yy/2];
]
]
F = F/Log[x];
ListLinePlot[F]
```

However, this is as I understand it the matrix formulation of the Fourier sine transform and it is therefore very costly to compute. I do NOT recommend running it because it already crashed my computer once.

Is there a way in Mathematica utilising the Fast Fourier Transform, to plot the spectrum with spikes at x-values equal to imaginary part of Riemann zeta zeros?

I have tried the commands `FourierDST`

and `Fourier`

without success. The problem seems to be that the variable `yy`

in the code is included in both `Sin[t*myspan/xres*yy]`

and `(y[[Floor[Exp[yy]]]] - Exp[yy])/Exp[yy/2]`

.

EDIT: 20.1.2012, I changed the line:

`For[yy = 0, yy <= Log[x], 1/stpval++,`

into the following:

`For[yy = 0, yy/stpval <= Log[x], yy++,`

EDIT: 22.1.2012, From Heike's comment, changed:

`For[yy = 0, yy/stpval <= Log[x], yy++,`

into:

`For[yy=0, yy<=Log[x], yy+=1/stpval,`

`For`

loop is stuck at`yy=0`

. You probably need to increment`yy`

rather than`stepval`

in the third argument of the`For`

loop. – kguler Jan 20 '12 at 2:31`yy`

runs from`0`

to`log(X)`

with increments of`1/stpval`

whereas in your code`yy`

runs from`0`

to`stpval Log[x]`

with increments of`1`

. You probably want to do something like`For[yy=0, yy<=Log[x], yy+=1/stpval, ... ]`

. – Heike Jan 20 '12 at 17:42