This paper proposes a class of power-of-two FFT (Fast Fourier Transform)
algorithms, called AM-QFT algorithms, that contains the improved QFT (Quick
Fourier Transform), an algorithm recently published, as a special case. The
main idea is to apply the Amplitude Modulation Double Sideband - Suppressed
Carrier (AM DSB-SC) to convert odd-indices signals into even-indices signals,
and to insert this elaboration into the improved QFT algorithm, substituting
the multiplication by secant function. The 8 variants of this class are
obtained by re-elaboration of the AM DSB-SC idea, and by means of duality. As a
result the 8 variants have both the same computational cost and the same memory
requirements than improved QFT. Differently, comparing this class of 8 variants
of AM-QFT algorithm with the split-radix 3add/3mul (one of the most performing
FFT approach appeared in the literature), we obtain the same number of
additions and multiplications, but employing half of the trigonometric
constants. This makes the proposed FFT algorithms interesting and useful for
fixed-point implementations. Some of these variants show advantages versus the
improved QFT. In fact one of this variant slightly enhances the numerical
accuracy of improved QFT, while other four variants use trigonometric constants
that are faster to compute in `on the fly' implementations