1. Technical Field
This application relates to surface electromagnetic wave dispersive delay lines. It relates especially to high bandwidth dispersive delay lines formed in a compact spiral form factor.
2. Background Information
Dispersive delay lines have been used in defense technology for fifty years, first as matched filters for high power chirp radars, and then as an analog element in a Chirp Fourier Transform which is equivalent to an analog Fast Fourier Transform. By a simple factoring of the expression for the Fourier transform it can be shown that a temporal function or signal which is multiplied by a chirp waveform and fed into a dispersive delay line, matched to the multiplying chirp, produces a temporal waveform which is equivalent to the Fourier transform of the input time signal.
These properties allow signal processing of ultra wide band signals, which require upwards of 100 trillion operations per second, to be implemented without a large amount of massively parallel processing elements consuming tremendous electrical power. It is estimated that a cubic foot worth of surface electromagnetic wave dispersive delay lines and associated hardware consuming 10 watts would match the largest supercomputers at 1000 trillion operations per second in applications such as pattern recognition or neuromorphic computing.
Straight linear surface electromagnetic wave dispersive delay lines have been used since the late 1980s. See, for example, U.S. Pat. No. 4,808,950 to Apostolos et al. entitled “Electromagnetic Dispersive Delay Line”, issued Feb. 28, 1989.
A long dispersive delay line is desirable to maximize the time-bandwidth product. The properties of straight linear delay lines are well known. However, it is unclear whether a curved delay line could exhibit the same dispersive properties as a straight delay line. This is especially important in the case of a non-enclosed waveguide where a curvature that is too small would lead to the waveguide radiating and leaking energy.
An electromagnetic dispersive delay line implemented in a spiral or practically spiral configuration provides wideband operation and high dispersion in a relatively compact form factor. In a preferred embodiment, the spiral configuration is shown to retain desired dispersion properties as long as the radius of curvature is constrained. For example, the greatest curvature should be constrained to be somewhat greater than two wavelengths.
In specific implementations, the waveguide may be formed from a suitable dielectric material such as titanium dioxide, barium tetratitanate, or another material exhibiting high dielectric constant.
In order to improve the bandwidth capabilities, the waveguide may be augmented with a transmission line such as a microstrip. In such implementations, the microstrip also follows the same spiral shape as the waveguide.
In an implementation, a microstrip may be disposed on the top surface of the waveguide, separated from the top surface by a spacer layer. In other implementations, a second microstrip may also be deposited on the bottom surface of the same waveguide, also separated by a spacer layer.
In an implementation where a single microstrip is provided on a first surface of the waveguide, the opposite surface of the waveguide is positioned facing a ground plane.
A desired transmission mode for the waveguide, for example, may be an HE 11 transmission mode with the radius of curvature constrained accordingly.
The waveguide and the microstrip may be a continuous fabrication or may be assembled from linear pieces. However, even in the piecewise linear implementation the arrangement of the individual linear slabs should follow the desired radius of curvature that meets the constraints needed to achieve the desired transmission mode.
Feed elements can take any suitable form such as horns or half-horns being fed from below the ground plane if a ground plane is present.
The description below refers to the accompanying drawings, of which:
The radius of the spiral should be chosen so that the curvature of the spiral is compatible with a desired transmission mode. In particular, the radius of the spiral should not be so small as to prevent the waveguide from operating in its desired modes. It is known, for example, that in the case of a long straight waveguide, the electromagnetic wave will propagate approximately the same as in a coaxial cable. In case of a sinusoidal excitation, if the segment is considered to be one wavelength long and keeping the current distribution along the straight wire unchanged, the coaxial cable behaves as a pair of rotating dipoles.
Considering the dipole radiation pattern for this configuration allows one to determine the desired radius of curvature for which radiation modes will develop. The circumference of the hypothetical circular section C=2πR, R is the radius of the circle. Because the segment is being considered to be a single wavelength long, λ=2πR. Solving for R, R=λ/2π. Because it is desired to retain as much of the energy as possible within the waveguide, one should therefore set the radius to be at least equal to but preferably much greater than λ/2π. We call this the small radiation criteria for a free space wavelength λ. In one example, for operation at a maximum frequency of approximately 20 GHz, λmax=1.5 cm and R should be at least greater than or equal to 10λmax/2π, or 3 cm.
The waveguide 102 would preferably be fabricated from a suitable material such as titanium dioxide, barium tetratitanate, or another appropriate dielectric material with a high dielectric constant. Such a continuous spiral shape can be fabricated using, for example, a waterjet cutter. The resulting spiral shaped material can then be affixed to a conducting ground plane (not shown in
The input 104 and output 106 transducers can be implemented as half horns fed from below the ground plane.
The implementation here with both the dielectric waveguide 200 and a microstrip 204 positioned proximate to it provides several advantages. For example, at relatively low frequencies the microstrip 204 is primarily responsible for carrying the radiofrequency energy. As frequencies increase, energy will transfer into the waveguide 200. The structure in
Desired dispersion characteristics can be retained in a spiral configuration as long as the radius of curvature of the spiral is properly constrained. By shaping the dispersive delay line in a spiral, one can reduce the form factor needed for packaging. In other words, a dispersive delay line for a given length can be packaged in a small form factor without compromising its operating characteristics.
It has been realized that in some instances it may not be practical to implement a perfectly continuous spiral. A similar effect can be achieved with a piecewise approximation to a spiral curve shape. Such an implementation is shown in
This application claims the benefit of U.S. Provisional Application No. 61/781,543, filed Mar. 14, 2013, the contents of which are hereby incorporated herein by reference.
Number | Date | Country | |
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61781543 | Mar 2013 | US |