Several novel phase-modulated fiber optic links for analog or microwave signal

transport up to at least 20 GHz frequency are theoretically developed and

experimentally demonstrated. Each link uses a linearization technique exploiting the

Lithium Niobate modulator's electro-optic anisotropy between orthogonal

crystallographic axes that has not previously been applied to phase-modulated links.

This technique and its variants suppress the dominant third-order distortion product to

extend the sub-octave spur-free dynamic range of the systems, and does so passively

using the modulator instead of with processing at the receiver. Two of the links

incorporate frequency downconversion, with one of them employing a new method to

spectrally filter the local oscillator and signal sidebands together. This both downconverts

the signal to an appropriate intermediate frequency and causes the phase

modulation to appear as intensity modulation for photodetection with a low-speed

detector. This technique does not require a separate optical oscillator source and can

be implemented with commercial hardware.