Single-wire transmission line


A single-wire transmission line is a method of transmitting electrical power or signals using only a single electrical conductor. This is in contrast to the usual use of a pair of wires providing a complete circuit, or an electrical cable likewise containing two conductors for that purpose.
The single-wire transmission line is not the same as the single-wire earth return system, which is not covered in this article. The latter system relies on a return current through the ground, using the earth as a second conductor between ground terminal electrodes. Thus, the earth effectively forms a second conductor. In a single-wire transmission line there is no second conductor of any form.

History

As early as the 1780s Luigi Galvani first observed the effect of static electricity in causing the legs of a frog to twitch, and observed the same effect produced just due to certain metallic contacts with the frog involving a complete circuit. The latter effect was correctly understood by Alessandro Volta as an electric current inadvertently produced by what would become known as a voltaic cell. He understood that such a current required a complete circuit to conduct the electricity, even though the actual nature of electric currents was not at all understood. All subsequent development of electrical motors, lights, etc. relied on the principle of a complete circuit, generally involving a pair of wires, but sometimes using the ground as the second conductor.
At the end of the 19th century, Nikola Tesla demonstrated that by using an electrical network tuned to resonance it was possible to transmit electric power using only a single conductor, with no need for a return wire. This was spoken of as the "transmission of electrical energy through one wire without return".
In 1891, 1892, and 1893 demonstration lectures with electrical oscillators before the AIEE at Columbia College, N.Y.C., the IEE, London, the Franklin Institute, Philadelphia, and National Electric Light Association, St. Louis, it was shown that electric motors and single-terminal incandescent lamps can be operated through a single conductor without a return wire. Although apparently lacking a complete circuit, such a topology effectively obtains a return circuit by virtue of the load's self-capacitance and parasitic capacitance.
The final reference to "burning out" a machine was to emphasize the ability of such a system to transmit a large power given a proper impedance match, as can be obtained through electrical resonance.

Theory

This observation has been rediscovered several times, and described, for instance, in a 1993 patent. Single-wire transmission in this sense is not possible using direct current and totally impractical for low frequency alternating currents such as the standard 50–60 Hz power line frequencies. At much higher frequencies, however, it is possible for the return circuit to utilize the self- and parasitic capacitance of a large conductive object, perhaps the housing of the load itself. Although the self-capacitance of even large objects is rather small in ordinary terms, as Tesla himself appreciated it is possible to resonate that capacitance using a sufficiently large inductor, in which case the large reactance of that capacitance is cancelled out. This allows a large current to flow without requiring an extremely high voltage source. Although this method of power transmission has long been understood, it is not clear whether there has been any commercial application of this principle for power transmission.

Single conductor waveguides

As early as 1899, Arnold Sommerfeld published a paper predicting the use of a single cylindrical conductor to propagate radio frequency energy as a surface wave. Sommerfeld's "wire wave" was of theoretical interest as a propagating mode, but this was decades before technology existed for the generation of sufficiently high radio frequencies for any such experimentation, let alone practical applications. What's more, the solution described an infinite transmission line without consideration of coupling energy into it.
Of particular practical interest, though, was the prediction of a substantially lower signal attenuation compared to using the same wire as the center conductor of a coaxial cable. Contrary to the previous explanation of the full transmitted power being due to a classical current through a wire, in this case the currents in the conductor itself are much smaller, with the energy transmitted in the form of an electromagnetic wave. But in this case, the presence of the wire acts to guide that wave toward the load, rather than radiating away.
The reduction of ohmic losses compared to using coax is especially an advantage at higher frequencies where these losses become very large. Practically speaking, use of this transmission mode below microwave frequencies is very problematic due to the very extended field patterns around the wire. The fields associated with the surface wave along the conductor are significant out to many conductor diameters, therefore metallic or even dielectric materials inadvertently present in these regions will distort the propagation of the mode and typically will increase propagation loss. Although there is no wavelength dependence to this dimension in the transverse direction, in the direction of propagation it is necessary to have a minimum of one half wave of conductor length to full support the propagating mode. For these reasons, and at frequencies available prior to about 1950, the practical disadvantages of such transmission completely outweighed the reduced loss due to the wire's finite conductivity.

Goubau line

In 1950 Georg Goubau revisited Sommerfeld's discovery of a surface wave mode along a wire, but with the intent of increasing its practicality. One major goal was to reduce the extent of the fields surrounding the conductor so that such a wire would not require an unreasonably large clearance. Another problem was that Sommerfeld's wave propagated exactly at the speed of light. That meant that there would be radiation losses. The straight wire acts as a long wire antenna, robbing the radiated power from the guided mode. If the propagation velocity can be reduced below the speed of light then the surrounding fields become evanescent, and are thus unable to propagate energy away from the area surrounding the wire.
Goubau investigated the beneficial effect of a wire whose surface is structured such as would be obtained using a threaded wire. More significantly, Goubau proposed the application of a dielectric layer surrounding the wire. Even a rather thin layer of a dielectric will reduce the propagation velocity sufficiently below the speed of light, eliminating radiation loss from a surface wave along the surface of a long straight wire. This modification also had the effect of greatly reducing the footprint of the electromagnetic fields surrounding the wire, addressing the other practical concern.
Finally, Goubau invented a method for launching electrical energy from such a transmission line. The patented Goubau line consists of a single conductor coated with dielectric material. At each end is a wide disk with a hole in the center through which the transmission line passes. The disk may be the base of a cone, with its narrow end connected typically to the shield of coaxial feed line, and the transmission line itself connecting to the center conductor of the coax.
Even with the reduced extent of the surrounding fields in Goubau's design, such a device only becomes practical at UHF frequencies and above. With technological development at terahertz frequencies, where metallic losses are yet greater, the use of transmission using surface waves and Goubau lines appears promising.

E-Line

From 2003 through 2008 patents were filed for a system using Sommerfeld's original bare wire, but employing a launcher similar to that developed by Goubau. It was promoted under the name "E-Line" through 2009. Thus the resulting wave velocity is not reduced by a dielectric coating or special conditioning of the conductor as prescribed as necessary for non-radiation by Goubau for G-Line. This line is claimed to be completely non-radiating, propagating energy by way of a previously unrecognized transverse-magnetic wave. The intended application in this case is particularly for creating high information rate channels using existing power lines for communications purposes. This has been proposed for transmission of frequencies from below 50 MHz to above 20 GHz using pre-existing single or multistrand overhead power conductors.
While Goubau-Line, which requires a conductor having an outer dielectric or special surface conditioning provided to reduce the velocity of the wave on the conductor, has long been known, this more general transverse-magnetic mode does not have this limitation. E-Line is similar to the Goubau-Line in its use of launchers to couple to and from a radially symmetric wave propagating in the space around a single conductor but different in that it can operate on insulation-free conductors, including those that are polished and completely unfeatured. The propagation velocity of the wave is not reduced and is essentially that of a wave traveling in the same medium in the absence of any conductor at all. Furthermore, practical launchers need not have a cross-section that is a large portion of a wavelength. Energy associated with the wave is confined to a region determined by the diameter and geometry of the conductor rather than the wavelength of the propagating signal. The Launcher has a low frequency cutoff limited by launcher length along the conductor.
The behavior of such a system is independent of the operating frequency, but is dependent upon details of the power conductor and its environment. "A nearby conductor other than the line itself may provide a termination point and thereby reduce energy coupled into the TM wave". As for any transmission line, at very high frequencies, the increased losses of the metal conductor, despite the advantage obtained using the surface wave mode, are increased, however because conductor losses are inversely proportional to the square of line impedance, this mode can achieve much lower losses, no more than a few percent of a 50 ohm coaxial line having the same center conductor. The effects of line taps, bends, insulators and other impairments normally found on power distribution systems have been described as "predictable and manageable". Depending on these factors, the resulting insertion loss, along with the transmitted power and receiver sensitivity, will determine the maximum distance attained by such a system. Like CATV systems, an increased end-to-end communications path can be obtained through the use of repeaters.
To take advantage of existing lines, the conical launcher elements are built with a slot through the cone, so that they can be easily fitted over an existing power line. Systems can employ a launch device of only 15–20 cm in diameter from upper HF through millimeter wavelengths as long as the launch has sufficient length along the conductor. Generally structures at least one quarter wavelength long are required. A one meter long launcher with a 10 cm opening can provide under 2 dB of insertion loss from 130 MHz through many GHz.
Systems built in this manner can provide both significant energy transfer e. g. providing motive power for electric helicopters acting as aerostats, at the same time they provide low loss transmission line connection to light weight, high altitude antennas.