Analysis of Analog Photonic Links Employing Multiple-Channel (Arrayed) Receivers

Naval Research Laboratory, Washington, DC

Tuesday, December 01 2009

This technique develops high-fidelity arrayed receivers for fiber-based or free-space applications.

Analog optical links are finding increased application in commercial and military systems ranging from radio-over-fiber applications, antenna remoting, and optical signal processing. As the performance of an analog link improves with received photocurrent, optical amplifiers — predominantly erbium-doped fiber amplifiers (EDFAs) — have been readily incorporated into a variety of systems. It is known that the addition of an optical amplifier (EDFA) raises the electrical noise floor in both digital and analog applications due to the presence of amplified spontaneous emission (optical) noise. To mitigate this additional noise in systems employing EDFAs prior to modulation, dualoutput optical modulators and balanced detection are frequently employed. This technique has been utilized alone to achieve the first multi-gigahertz bandwidth analog optical link with a noise figure <10 dB and in concert with other techniques to achieve an RF noise figure approaching 3 dB.

While pre-modulation amplification and balanced detection may be utilized to approach shot noise-limited performance in an analog link, other techniques may be applied to increase the link gain (increase the received photocurrent), while also decreasing the effect of noise from the EDFA; in particular, arrayed receivers — those employing multiple optical paths post-modulation and multiple photodiodes.

In these architectures, the desired output RF photocurrent is recovered from each photodiode individually; the individual photocurrents are then coherently combined in the electrical domain. Conceptually, the operation of these receivers is analogous to a phased-array antenna operating in receive mode, where the outputs of multiple antenna elements are combined in-phase to increase the signal-to-noise ratio of the received signal as compared to that from a single element. These phased receivers (with no intentional filtering) could find widespread application in analog systems utilizing freespace optical links.

The performance of arrayed receivers in which each optical (receiver) path employs an EDFA is analyzed. The analysis derives general expressions for two of the primary RF performance metrics — gain and noise figure — of an analog link utilizing the arrayed receiver concept. This analysis links the performance of the EDFAs utilized in the system to the RF noise figure. Specifically, this is achieved by extending the concept of the noise penalty associated with an EDFA — defined for a highly compressed amplifier — to all regimes of amplifier operation; in particular, the linear amplification regime.