It depends on the unit of your timeseries. Often we think of this as just "amplitude", but if your timeseries is a series of voltage amplitude vs. time, then your PSD estimate will be `Volts^2/Hz`

. This is because the PSD is the Fourier Transform of the autocorrelation of your original signal: The autocorrelation has units of `Volts^2`

, and running it through the Fourier Transform decomposes these units over frequency, instead of time, resulting in units of `Volts^2/Hz`

. This is commonly referred to as `Watts/Hz`

, but the conversion from `Volts^2`

to `Watts`

is not very physically meaningful, as `W = V^2/R`

.

`10*log10(power)`

will result in a unit of `dB/Hz`

, but remember that decibels are always a comparison between two power levels; you are quantifying a ratio of powers. A better definition of decibels is `10*log10(P1/P0)`

, as explained here. If you simply plug a PSD bin estimate into this equation, you are setting your PSD bin to `P1`

and implicitly comparing it to a `P0`

value of 1. This may be what you want, and it may not be. For visualization purposes, this is fairly typical, but if you have a standard reference power you should be comparing to, you should use that for `P0`

instead.

Assuming that you are attempting to plot a dB Power Spectral Density estimate, to convert from `Hz`

to `MHz`

, you simple rescale the x-axis of your frequency graph. Remember that a MHz is just 1 million Hz, so the only difference is that `240000Hz`

= `0.24MHz`

**EDIT**
The point brought up by mtrw is a very valid one; if you are dealing with large amounts of data and are averaging FFT vectors, I highly suggest the Multitaper method; it's a much more statistically sound method of sacrificing frequency resolution for greater confidence on your PSD estimate.