Diffraction, Fourier Optics and Imaging

Chapter 19.3 - Method Of Irregularly Sampled Zero-Crossings (MISZC)

19.3   METHOD OF IRREGULARLY SAMPLED ZERO-CROSSINGS (MISZC)

In this method, the design of a DWDM device is undertaken such that there is only
one image per wavelength so that the number of channels is not restricted due to the
distance between successive orders as discussed with Eq. (19.2-6) above


Figure 19.2. A 180 channel regular AWG layout designed with BeamPROP [Lu and Ersoy et al., 2003].


Figure 19.3. The output of a 16-channel PHASAR at a center wavelength of 1.550 m, and channel spacing of 0.8 m [Lu, Ersoy].


Figure 19.4. The output of a 64-channel PHASAR at a center wavelength of 1.550 m, and channel spacing of 0.8 m [Lu, Ersoy].


[Lu, Ersoy], [Ersoy, 2005]. The beams at their focal points will be referred to as
images. We will in particular discuss how to achieve the design in the presence of
phase modulation corresponding to a combination of a linear and a spherical
reference wave. Figure 19.5 shows a visualization of the reference waves and
geometry involved with two wavelengths.


Figure 19.5. A visualization of the reference waves and geometry involved with two wavelengths in MISZC.


Once the required phase is computed, its implementation in the case of a AWG
can be done by choosing the length of each waveguide to yield the required phase.
This is the way it is already done with the regular PHASAR devices with only the
linear grating phase modulation in confocal or Rowland geometries. The method is
first discussed below for illustration purposes with respect to a planar geometry,
meaning that the phased array apertures are placed on a plane (line for the 2-D case).
Generalizations of the results to confocal, Rowland and 3-D geometries are given in
the subsequent sections.

The method is based on first randomly choosing the locations of the centers of
radiating apertures and then either by creating the negative phase of the phasefront
(possibly plus a constant) at the chosen locations so that the overall phase is zero (or
a constant), or slightly adjusting locations of the centers of radiating apertures such
that the total phase shift from such a center to the desired image point equals a
constant value, say, zero modulo 2π. In both approaches, such points will be referred
to as zero-crossings. In the second approach, they will be referred to as automatic
zero-crossings. In practice, the sampling points are chosen semi-irregularly as
discussed below.

The total number of zero-crossings can be a very large number, especially
in the presence of linear and spherical phase modulation. Practical implementations
allow only a small number of apertures, for example, 300 being a
typical number in the case of PHASARS. In order to avoid the problem of too
many apertures, and to avoid harmonics generated due to regular sampling
[Ishimaru, 1962], [Lao, 1964], we choose irregularly sampled sparse number of
apertures. One way to determine zero-crossing locations is given below as a
procedure.

Step 1: The aperture points are initialized by choosing one point at a time randomly
along the phased array surface. In order to achieve this systematically on the total
surface of the phased array, the following approach can be used:

Initial point locations = uniformly spaced point locations + small random shifts

Step 2(a): If the method of creating the negative phase of the phasefront at the
chosen locations is used, the said phase is created physically, for example,
by correctly choosing the lengths of the waveguides in the case of PHASAR
devices.

Step 2(b): If the method of automatic zero-crossings is used, correction values are
calculated for each of the initial points generated in step 1 to find the nearest zero-
crossing points as

Final locations of zero-crossings = Initial point locations from step 1+ correction
terms

The two approaches work similarly. Below one algorithm to calculate the correction
terms to generate the automatic zero-crossings is discussed.

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