The present invention relates to a transmit antenna, and in particular to an antenna for transmitting signals for high frequency surface wave radar.
High frequency surface wave radar (HFSWR) systems have been developed to overcome the line-of-sight limitation of microwave radar systems. HFSWR exploits a phenomenon known as a Norton wave propagation, whereby a vertically polarised electromagnetic signal propagates efficiently as a surface wave along a conducting surface. HFSWR systems operate from coastal installations, with the ocean providing the conducting surface. The transmitted signal follows the curved ocean surface, and an HFSWR system can detect objects beyond the visible horizon, with a range of the order of 300 km.
As shown in
The receiver 14 includes a data processing system 24 and a broadside array 20 of vertically polarised antenna doublets. The broadside array 20 is oriented approximately perpendicular to a principal receiving direction 25 for reflected surface wave signals, and, in this case, is approximately parallel to the shore 26. The receiver 14 can also include an endfire array 22 of vertically polarised monopole antenna elements, oriented perpendicular and adjacent to the broadside array 20 to form a two-dimensional (2-D) receiving antenna array.
A standard log-periodic antenna array is suitable for the directional transmission of vertically polarised signals over a wide bandwidth and beam width. However, it is often necessary to transport the antenna to various locations. Log-periodic antenna arrays designed to transmit signals in the appropriate frequency range (5-10 MHz) are large and expensive structures that require considerable effort for disassembly, transportation, site preparation and reassembly. It is desired, therefore, to provide a transmit antenna that alleviates one or more of these difficulties, or at least provides a useful alternative to existing transmit antennas.
In accordance with the present invention, there is provided a transmit antenna for a surface wave radar system, including:
a linear array of active monopole antenna elements for transmitting signals in respective frequency ranges, the relative spacings and the relative heights of successive elements along the array having substantially logarithmic relationships;
impedance matching circuits for the active monopole antenna elements; and
switch means for selecting one of the active antenna elements to transmit a signal in a corresponding frequency range while grounding the remaining active antenna elements.
A preferred embodiment of the present invention is hereinafter described, by way of example only, with reference to the accompanying drawings, wherein:
FIGS. 2 to 4 are schematic diagrams of a preferred embodiment of a transmit antenna of the radar system;
FIGS. 6 to 11 are graphs of the simulated and measured radiation patterns from each antenna element with impedance matching, at frequencies of 5.1, 6.1, 7.1, 8.1 9.1, and 10.2 MHz, respectively.
As shown in
The tallest passive element 40 is a sixteen metre wind-up lattice mast and acts as a reflector at the low frequency end of the antenna's operating frequency range. The other passive element 38 is shorter and acts as a director at the high frequency end of the antenna's operating frequency range. Thus the maximum transmit signal intensity is directed along the array direction 41 leading away from the reflector passive element 40 toward the director passive element 38, and accordingly the transmit antenna 16 is oriented so that this direction 41 points towards the potential objects of interest; i.e., in the arrangement of
A grounded radial wire counterpoise under each antenna element reduces ground losses and stabilises the impedance of each antenna element under varying ground conditions. The configurations of the counterpoises are shown in a plan view of the transmit antenna 16 in
As shown in
The RF switches 58 allow each antenna element to be independently connected to the transmitter electronics 18 via the coaxial cable 76, or shorted to ground potential. When a signal of a particular frequency is transmitted, the antenna element whose allotted frequency range includes that frequency is connected to the transmitter electronics 18, and the three remaining antenna elements are shorted to ground. This switching is performed by remotely controlling the switches 58 to 64 by sending appropriate signals on control cables 80. Specifically, a 24-volt gate pulse signal sent to one of the RE switches 58 to 64 on that switch's control cable activates the RF switch to connect the coaxial cable 76 to the corresponding interface module (e.g., the second interface module 44), and thereby to the corresponding antenna element (e.g., the second antenna element 32). The other antenna elements (e.g., the first, third and fourth antenna elements 30, 34, 36) are shorted to ground and act as additional reflectors or directors.
Table 3 provides details of the values of capacitance and inductance for each of the active antenna element matching networks 50 to 56.
As shown in
FIGS. 6 to 11 are graphs of the measured 701 and simulated 702 azimuthal radiation patterns for the antenna array at frequencies of 5.1, 6.1, 7.1, 8.1 9.1, and 10.2 MHz, respectively. An azimuthal angle of 0 degrees corresponds to the direction 41 leading from the low frequency end of the antenna array towards the high frequency end of the antenna array, and it can be seen that the maximum gain is obtained in this direction. The simulated radiation patterns 702 include antenna and mismatch losses and appear to match the measured patterns closely. Some discrepancies are apparent at the higher frequencies, probably due to factors such as adjacent buildings and structures that affect surface-wave attenuation.
The antenna 16 is designed to have a limited frequency range of 5-10 MHz, but the high-frequency characteristics of the array can be extended by adding one or more active elements to the high-frequency end of the array. This slightly increases the gain of the fourth antenna element 36 without significantly affecting its impedance.
In comparison with a standard log-periodic antenna array, the logarithmic monopole antenna array 16 has a lower gain and broader azimuth and elevation radiation patterns. However, the cost of manufacture is greatly reduced, and the logarithmic monopole antenna is readily transportable.
Many modifications will be apparent to those skilled in the art without departing from the scope of the present invention as herein described with reference to the accompanying drawings.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2002952531 | Nov 2002 | AU | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/AU03/01465 | 11/6/2003 | WO | 2/28/2006 |