Waveguide Slot Antenna Arrays
9.1 INTRODUCTION. Geometric simplicity, efficiency, polarization purity, conformal installation, and ability to radiate broadside beams and vertically polarized E-plane beams at very near grazing angle above a ground plane make slot-antenna arrays ideal solutions for many radar, communications, and navigation applications. Slot antennas are usually used at UHF and microwave frequencies at which wavelengths are small enough that the plate and slot are conveniently small. At these frequencies, the radio waves are often conducted by a waveguide, and the antenna consists of slots in the waveguide; this is called a slotted waveguide antenna. The procedure to design a waveguide slot array antenna is explained, and also the analysis model to design the element is discussed as well as the scattering matrix in connecting the equivalent circuit with a transmission line. Finally, the design examples for one-dimensional and two-dimensional arrays of the waveguide slot antennas are explained. DESIGN SUBSTRATE INTEGRATED WAVEGUIDE SLOT ARRAY ANTENNA AT X-BAND ABSTRACT Substrate integrated waveguide (SIW) is a rectangular dielectric-filled waveguide, which is synthesized in a planar substrate with arrays of metallic vias to realize bilateral side walls and its transitions with planar structures.
A slot antenna consists of a metal surface, usually a flat plate, with one or more holes or slots cut out. When the plate is driven as an antenna by an applied radio frequency current, the slot radiates electromagnetic waves in a way similar to a dipole antenna. The shape and size of the slot, as well as the driving frequency, determine the radiation pattern. Slot antennas are usually used at UHF and microwave frequencies at which wavelengths are small enough that the plate and slot are conveniently small. At these frequencies, the radio waves are often conducted by a waveguide, and the antenna consists of slots in the waveguide; this is called a slotted waveguide antenna. Multiple slots act as a directivearray antenna and can emit a narrow fan-shaped beam of microwaves. They are used in standard laboratory microwave sources used for research, UHF television transmitting antennas, antennas on missiles and aircraft, sector antennas for cellular base stations, and particularly marine radar antennas. A slot antenna's main advantages are its size, design simplicity, and convenient adaptation to mass production using either waveguide or PC board technology.
Structure[edit]
As shown by H. G. Booker in 1946, from Babinet's principle in optics a slot in a metal plate or waveguide has the same radiation pattern as a driven rod antenna whose rod is the same shape as the slot, with the exception that the electric field and magnetic field directions are interchanged; the antenna is a magnetic dipole instead of an electric dipole; the magnetic field is parallel to the long axis of the slot and the electric field is perpendicular. Thus the radiation pattern of a slot can be calculated by the same well-known equations used for rod element antennas like the dipole. The waves are linearly polarized perpendicular to the slot axis. Slots up to a wavelength long have a single main lobe with maximum radiation perpendicular to the surface.
Antennas consisting of multiple parallel slots in a waveguide are widely used array antennas. They have a radiation pattern similar to a corresponding linear array of dipole antennas, with the exception that the slot can only radiate into the space on one side of the waveguide surface, 180° of the surrounding space. There are two widely used types:
- Longitudinal slotted waveguide antenna - The slots' axis is parallel to the axis of the waveguide. This has a radiation pattern similar to a collinear dipole antenna, and is usually mounted vertically. The radiation pattern is almost omnidirectional in the horizontal plane perpendicular to the antenna over the 180° azimuth in front of the slot, but narrow in the vertical plane, with the vertical gain increasing approximately 3 dB with each doubling of the number of slots. The radiation is horizontally polarized. It is used for vertical omnidirectional transmitting antennas for UHF television stations. For broadcasting, a cylindrical or semicircular waveguide is sometimes used with several columns of slots cut in different sides to give an omnidirectional 360° radiation pattern.
- Transverse slotted waveguide antenna - The slots are almost perpendicular to the axis of the waveguide but skewed at a small angle, with alternate slots skewed at opposite angles. This radiates a dipole pattern in the plane perpendicular to the antenna, and a very sharp beam in the plane of the antenna. Its largest use is for microwave marine radar antennas. The antenna is mounted horizontally on a mechanical drive that rotates the antenna about a vertical axis, scanning the antenna's vertical fan-shaped beam 360° around the water surface surrounding the ship out to the horizon with each revolution. The wide vertical spread of the beam ensures that even in bad weather when the ship and the antenna axis is being rocked over a wide angle by waves the radar beam will not miss the surface.
History[edit]
The slot antenna was invented in 1938 by Alan Blumlein, while working for EMI. He invented it in order to produce a practical type of antenna for VHF television broadcasting that would have horizontal polarization, an omnidirectional horizontal radiation pattern and a narrow vertical radiation pattern.[1][2]
Prior to its use in surface search radar, such systems used a parabolic segment reflector, or 'cheese antenna'. The slotted waveguide antenna was the result of collaborative radar research carried on by McGill University and the National Research Council of Canada during World War II.[3] The co-inventors, W.H. Watson and E.W. Guptill of McGill, were granted a United States patent for the device, described as a 'directive antenna for microwaves', in 1951.[4]
Other uses[edit]
In a related application, so-called leaky waveguides are also used in the determination of railcar positions in certain rapid transit applications. They are used primarily to determine the precise position of the train when it is being brought to a halt at a station, so that the doorway positions will align correctly with queuing points on the platform or with a second set of safety doors should such be provided.
See also[edit]
- Microwave Radiometer (Juno) (has a slot array antenna)
- RIMFAX (radar for Mars rover has slot antenna design)
Waveguide Slot Antenna Arrays Ham Radio
References[edit]
- ^Blumlein, Alan (1938-03-07), 'Improvements in or relating to high frequency electrical conductors or radiators', British patent no. 515684
- ^Burns, Russell (2000). The life and times of A.D. Blumlein. Institution of Engineering and Technology. ISBN0-85296-773-X.
- ^Covington, Arthur E. (1991). 'Some recollections of the radio and electrical engineering division of the National Research Council of Canada, 1946-1977'. Scientia Canadensis: Canadian Journal of the HIstory of Science, Technology and Medicine. 15 (2): 155–175. doi:10.7202/800334ar.
- ^Watson, William Heriot; Guptill, Ernest Wilmot (6 November 1951), Directive Antenna for Microwaves, retrieved 20 December 2016
External links[edit]
Waveguide-slot Array Antenna Designs For Low-average-sidelobe Specifications
- 'Slot Antennas'. Antenna Theory.
- Slotted Waveguide Antennas Antenna-Theory.com
Waveguide Slot Array Antenna Design
- Elliott RS (1983) An improved design procedure for small arrays of shunt slots. IEEE Trans Antennas Propag 31:48–53CrossRefGoogle Scholar
- Elliott RS, Kurtz LA (1978) The design of small slot arrays. IEEE Trans Antennas Propag 26:214–219CrossRefGoogle Scholar
- Josefsson LG (1987) Analysis of longitudinal slots in rectangular waveguide. IEEE Trans Antennas Propag 35:1351–1357CrossRefGoogle Scholar
- Khac TV, Carson CT (1973) Impedance properties of a longitudinal slot antenna in the broad face of a rectangular waveguide. IEEE Trans Antennas Propag 21:708–710CrossRefGoogle Scholar
- Kurtz LA, Yee JS (1957) Second-order beams of two-dimensional slot arrays. IRE Trans Antennas Propag 5:356–362CrossRefGoogle Scholar
- Lyon RW, Sangster AJ (1981) Efficient moment method analysis of radiating slots in a thick-walled rectangular waveguide. IEE Proc 128(pt.H):197–205Google Scholar
- Maxum BJ (1960) Resonant slots with independent control of amplitude and phase. IRE Trans Antennas Propag 8:383–388CrossRefGoogle Scholar
- Oliner AA (1957) The impedance properties of narrow radiating slots in the broad wall of rectangular waveguide. IRE Trans Antennas Propag 5:1–20CrossRefGoogle Scholar
- Park SH, Hirokawa J, Ando M (2003) Simple analysis of a slot with a reflection-canceling post in a rectangular waveguide using only the axial uniform currents on the post surface. IEICE Trans Commun 86(8):2482–2487Google Scholar
- Rangarajan SR (1989) Compound radiating slots in a broad wall of a rectangular waveguide. IEEE Trans Antennas Propag 37:1116–1123CrossRefGoogle Scholar
- Sakakibara K, Hirokawa J, Ando M, Goto N (1994) A linearly-polarized slotted waveguide array using reflection-canceling slot pairs. IEICE Trans Commun 77:511–518Google Scholar
- Sakakibara K, Hirokawa J, Ando M, Goto N (1996) Periodic boundary condition for evaluation of external mutual coupling in a slotted waveguide arrays. IEICE Trans Commun 79:1156–1164Google Scholar
- Sakakibara K, Kimura Y, Akiyama A, Hirokawa J, Ando M, Goto N (1997) Alternating phase-fed waveguide slot arrays with a single-layer multiple-way power divider. IEE Proc Microw Antennas Propag 144:425–430CrossRefGoogle Scholar
- Seki H, Goto N (1981) Synthesis of circular polarization with non resonant slots in the narrow wall of a rectangular waveguide. Trans IECE 64(pt.B):1000–1007Google Scholar
- Stegen RJ (1971) Longitudinal shunt slot characteristics, Technical report 261, Hughes technical memorandumGoogle Scholar
- Stern GJ, Elliott RS (1985) Resonant length of longitudinal slots and validity of circuit representation: theory and experiment. IEEE Trans Antennas Propag 33:1264–1271CrossRefGoogle Scholar
- Stevenson AF (1948) Theory of slots in rectangular waveguides. J Appl Phys 19:24–38MathSciNetCrossRefGoogle Scholar
- Watson WH (1946) Resonant slots. IEE J 93(pt.3A):747–777Google Scholar
- Watson WH (1947) The physical principles of wave guide transmission and antenna system. Oxford University PressGoogle Scholar
- Yee HY (1974) Impedance of a narrow longitudinal shunt slot in a slotted waveguide array. IEEE Trans Antennas Propag 22:589–592CrossRefGoogle Scholar
- Zhang M, Hirokawa J, Ando M (2011) Full-wave design considering slot admittance in 2-D waveguide slot arrays with perfect input matching. IEICE Trans Commun 94:725–734CrossRefGoogle Scholar