The present invention pertains to the field of high power RF, more specifically with high powered dipole structures, and is an improvement over existing fat dipole geometries.
The dipole antenna is the most fundamental and simple radiating structure, and appears in many physical applications. The basic structure in
High power radiation is desired for many applications, including electronic disruption. High powers can be achieved from a fat dipole structure, illustrated in
Generating high voltage resonant energy and efficiently delivering it onto the dipole structure can be very difficult, since high voltage connections are typically large and result in impedance mismatches with the source. This problem can be mitigated by integrating the resonant source within the dipole geometry.
A number of efforts have been made to radiate high powered RF from dipole antennas. The most common geometry has been with a resonant quarter wave transmission line built into a dipole geometry. Staines describes this method through several patents (U.S. Pat. No. 7,215,083 B2, U.S. Pat. No. 6,822,394 B2, U.S. Pat. No. 7,002,300 B2).
The Staines geometry is essentially a sleeve dipole designed for a specific radiation frequency, and uniquely integrates a switched resonant quarter wave, low impedance transmission line into the dipole geometry, as illustrated in
The fat dipole of
The standard fat dipole has some shortcomings, primarily its signal gain, or radiation efficiency.
The application of high voltage to a dipole can be made in a wide variety of methods, but is summarily reduced to two basic geometries: 1) a direct connection, and 2) connection via high voltage coaxial cable. High voltage may also be delivered via direct current for a constant voltage, or via pulse charging methods. The pulse charging method can result in much higher radiated electric field strengths if the pulse risetime is shorter than that of the corresponding center frequency of the antenna, so that much higher voltages can be placed on the capacitor before the spark gap closes.
The present invention uniquely integrates a simple high voltage resonator with a multi-rod dipole arm geometry to produce high power RF radiation. The radiated frequencies of the preferred embodiment extend to hundreds of MHz. Operation of the present invention may be extended to higher frequencies. But at higher frequencies the smaller resonator geometries limit high power operation, and very fast switches must be used. The simple high voltage resonator naturally conforms to the dipole geometry, with a parallel plate geometry providing the primary capacitance, and the dipole's arms providing the secondary capacitance. The parallel plate structure incorporates a centrally-located spark gap that provides the necessary inductance for completion of the resonance condition. A simple LC circuit is realized. The wavelength of the LC circuit should be matched to the round-trip path length of the dipole device.
The dipole structure is implemented as a fat dipole, with arms several inches in diameter and designed to decrease the dipole's impedance via the increased capacitance provided by the increased surface area, thus allowing increased surface current. For this invention, the arms are made of several small, parallel rods placed within the plate perimeter with regular spacing. Each rod simulates the fat dipole geometry, and mitigates unwanted transverse current modes that do not propagate strictly up and down, i.e. along an antenna axis, on the arm structure.
Furthermore, the multiple parallel arms are connected directly to each plate of the resonator, so that outer edges of the individual rods align with the plate edge perimeter so that no conductive shoulder results. This implementation minimizes current path lengths and avoids added inductance that reduces efficiency. Furthermore, an annular end plate terminates the rods and enhances the magnitude of the radiating electric field.
The primary advantage of the present invention is the integration of a simple parallel plate resonator within a multi-rod dipole antenna geometry that provides higher voltage radiation efficiency that can result in very high radiated electric field strengths.
Terminology used herein describes particular embodiments only, and is not intended to be limiting. As used in the specification, including the claims, the singular forms “a”, “an”, and “the” include singular and plural referents unless the content dictates otherwise. Unless defined otherwise, all technical and scientific terms used herein have meanings commonly understood by one of ordinary skill in the relevant art or industry.
The simplified circuit of
The resonator circuit 11 is simply comprised of the common capacitor 14, an inductor 15, and a switch 16. Once the capacitor 14 has been charged, the switch 16 is closed, resulting in resonance between the capacitor 14 and the inductor 15. The resonant frequency is defined by
The switch 16 can be a triggered switch, but the preferred switch 16 is comprised of an over-voltage spark gap switch, since extreme voltages are desired. Furthermore, a self break switch is preferred for better isolation between the resonant circuit 11 and the charging circuit 10, since a triggered switch can create unwanted ground references. The resistors 17 load the resonant circuit 10, bleeding the energy from the circuit. Here the resistors 17 represent the radiation resistance of the dipole arms.
The primary function of the charge circuit 10 is delivery of energy onto the capacitor 14 as quickly as possible (i.e switch closure time shorter than rise time associated with center frequency) and with maximal voltage before the switch 16 closes. A high voltage pulse is delivered via a section of high voltage cable 12, which is isolated from the resonant circuit 11 via the connection inductance provided by the two inductors 13. The connection inductance is necessary for the isolation of the dipole from the cable 12 when the switch 16 closes. Without this isolation the cable 16 may load the resonant circuit thereby diminishing the radiated field.
The basis of this invention is the integration of a simple resonator into the dipole stricture. The simple resonator of
The spark gap switch 19 should be centered within the plate geometry so that current always flows in the radial direction, as illustrated in
The resonator model of
where ε0 is the permittivity of free space, εr is the relative permittivity of the dielectric material between the plates, A is the area of the parallel plates, and d is the distance between the plates. The spark gap inductance is a function of the electrode separation, and contributes to the definition of the plasma channel properties.
The resonant frequency of the simple resonator should match the wavelength of the dipole. The typical dipole geometry is a half wavelength structure, which makes each arm a quarter wavelength.
A variety of insulating dielectric materials can be used between the plates, including vacuum, gases (e.g. dry breathable air, hydrogen and sulfurhexaflouride), liquids (e.g. de-ionized water, flourinert or transformer oil), or solids (e.g. plastics, epoxy, or a ceramic). The insulating method has considerable effect on both the capacitance and the inductance of the circuit, and affects service and switch design considerations.
Vacuum, gas, and liquid insulation methods employ similar geometries. A structure must be designed to provide both mechanical fixturing of the dipole and containment of the insulating medium. A preferred structure, illustrated in
One of the capacitor plates 36 is mounted to the vessel 34, and the second plate 36 is mounted to the coverplate 35. The plates 36 are held to their respective surfaces with bolts 40, countersunk to be flush with the plate surface. The bolts should not protrude through the vessel walls. The spark gap electrodes 37 can be made with bolts that are screwed through the plate, making them adjustable. However, seals must be included to prevent leaking.
The path 41 between the two plates 36 and along the plastic surface should be long enough to prevent an electrical discharge or surface flashover. The inside diameter of the vessel should be larger than the capacitor plates, and the depth of the vessel should be larger than the total of the two plate thicknesses and the plate separation. Additionally, vaulting the plates above the vessel surface 42 mitigates the propagation of charge along the plastic surface.
In the case of vacuum as the insulating material, a vacuum port should be integrated into the chamber. A simple air fitting can be used, since the volume is relatively small. However, a vacuum port is preferred, as shown in
Gas insulated geometries are the easiest to implement. An example containment vessel is illustrated in
Liquid insulated geometries should be identical to the gas geometries. However, the entry 51 and exit ports 52 should be larger, with approximately ½″ diameter tubing providing the conduits. High flow rates may be required for higher repetition rates, since a spark in the fluid results in carbon residues, which can adversely affect the performance of the dipole with self breakdown conditions and sparks forming in inappropriate locations.
Solid material geometries are the most difficult to implement, but might be desirable for applications requiring compactness, especially for lower frequencies requiring large capacitances. It should be obvious that the spark gap switch must have a vacuum, gas, or liquid medium; otherwise the switch would be a single event component, since the dielectric medium would be damaged. Flashover conditions must be avoided, since carbon traces are left on the dielectric surface and lead to subsequent flashovers at lower potentials. A sample geometry for a solid medium is illustrated in
The typical fat dipole arm geometry is described by
The rods (or tubes) can be connected to the plates via threaded rods 61 penetrating the containment vessel, as illustrated in
The arms of the fat dipole can alternatively be implemented with slotted tubes as illustrated in
The ends of the dipole arms can be left open; however, attaching circular discs will enhance the electric field. Solid discs 69, as described by
Annular discs are preferred, as illustrated in
Increasing the outer diameter of the annular disc can result in lowered radiated frequencies, with a frequency change directly related to the change in the diameter. As illustrated in
The preferred driver or source for the dipole is an un-housed pulse generator, as illustrated in
If the capacitance of the pulse generator is substantially greater than the capacitance of the dipole, a resonant charge may occur, resulting in twice the voltage of the pulse generator across the dipole. The final charge magnitude, however, is largely dictated by the characteristics of the spark gap.
A second preferred method for charging the dipole with high voltage is via coaxial cable, illustrated in
A shielded or conductively housed pulse generator can be directly connected to the dipole, but should not continue the dipole arm geometry exactly. The preferred geometry, illustrated in
The electric field generated by the dipole can be directed in a forward direction with a backing reflector. While the primary use of the reflector is narrowing of the torroidal beam to a width in the tens of degrees, the reflector can also increase the electric field of the first half cycle via capacitive coupling, and can also increase the number of cycles in the radiated damped sinusoidal temporal response. One problem associated with the reflector-backed dipole is beam blocking caused by the large diameter dipole. The dipole radiates some amount of energy toward the reflector. The majority of the energy reflects to propagate forward, but some of the energy is blocked by the dipole, and is seen as loss. This invention modifies the reflector to include an inverted reflector so that energy that would normally be blocked by the dipole is instead deflected back into the reflector, but away from the center. The radiated electric field can be increased 10-20% as a result of this design.
The preferred embodiment of
It will be apparent to those with ordinary skill in the relevant art having the benefit of this disclosure that the present invention provides an apparatus for generation of high power RF energy. It is understood that the forms of the invention shown and described in the detailed description and the drawings are to be taken merely as the currently preferred embodiments, and that the invention is limited only by the language of the claims. The drawings and detailed description presented herein are not intended to limit the invention to the particular embodiments disclosed.
While the present invention has been described in terms of two preferred embodiments, it will be apparent to those skilled in the art that form and detail modifications can be made to the described embodiments without departing from the spirit or scope of the invention. For example, reflector geometries other than angled can be used. One alternate embodiment of the reflector is a combination of an angled and a parabolic reflector as shown in
With benefit of this disclosure and accompanying drawings, all methods described herein can be performed without undue experimentation.