the optical carrier so the recovere

the optical carrier so the recovered RF signal, now processed
(as shown in point 4), is ready to be sent to an RF receiver or to
be reradiated. The overall electrical transfer function
is also shown and must not be confused with the optical field
transfer function of the auxiliary optical system.
The concept of signal processing is pervasive in MWP, as
shown by some examples in Fig. 2. For instance, it appears in
radio-over-fiber multipoint wavelength division multiplexing
networks, where each central station source/base station de-
tector pair defines an MWP filter. It also appears in more
specialized subsystems such as optoelectronic oscillators,
photonic analog-to-digital converters, arbitrary waveform
generators, and frequency measurement subsystems. It is also
present in optical beam-steering application, where spatial
diversity defines an individual MWP filtering channel between
the source and each radiating element. For each particular
application, a different spectral configuration is required, but
the underlying concept remains the same.
The most versatile approach toward the implementation of
MWP filters is based on discrete-time signal processing [4],
where a number of weighted and delayed samples of the RF
signal to be processed are produced in the optical domain and
combined upon detection. In particular, finite impulse response
(FIR) [7] filters combine at their output a finite set of delayed
and weighted replicas or taps of the input optical signal, while
Fig. 3. General scheme of a discrete-time FIR MWP. (a) Traditional approach
based on a single optical source in combination with multiple delay lines.
(b) More compact approach based on a multiwavelength optical source
combined with a single dispersive element.
infinite impulse response (IIR) filters [7] are based on recir-
culating cavities to provide an infinite number of weighted
and delayed replicas of the input optical signal. For instance,
and taking as an example an FIR configuration, the electronic
transfer function is given by
(1)
where represents the weight of the th sample,
and is the time delay between consecutive samples. Note that
(1) implies that the filter is periodic in the frequency domain.
The period, known as the free spectral range (FSR), is given by
. The usual implementation of this concept in the
context of MWP can follow two approaches, as shown in Fig. 3.
In the first one [see Fig. 3(a)], the delays between consecutive
samples are obtained, for instance, by means of a set of optical
fibers or waveguides where the length of the fiber/waveguide in
the th tap is , being and the light velocity in
the vacuum and the refractive index, respectively. This simple
scheme does not allow tuning, as this would require changing
the value of . An alternative approach [see Fig. 3(b)] is based
on the combination of a dispersive delay line and different op-
tical carriers where the value of the basic delay is changed by
tuning the wavelength separation among the carriers, thereby
allowing tunability [5], [6]. While in the first case the weight of
the th tap can be changed by inserting loss/gain devices in the
fiber coils, the second approach allows to readily adjust by
changing the optical power emitted by the optical sources [5].
MWP filters can operate under incoherent regime, where
sample coefficients in (1) correspond to optical intensities and
are thus positive or under coherent regime, where the taps in
(1) can be complex-valued in general. In the first case, the
basic delay is much greater than the coherence time of the
optical source that feeds the filter, while in the second one