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J-pole antenna

Summary

The J-pole antenna, more properly known as the J antenna,[1] is a vertical omnidirectional transmitting antenna used in the shortwave frequency bands. It was invented by Hans Beggerow in 1909 for use in Zeppelin airships.[2] Trailed behind the airship, it consisted of a single one half wavelength long wire radiator, in series with a quarter-wave parallel transmission line tuning stub that matches the antenna impedance to the feedline. By 1936 this antenna began to be used for land-based transmitters with the radiating element and the matching section mounted vertically, giving it the shape of the letter "J",[3] and by 1943 it was named the J antenna.[1] When the radiating half-wave section is mounted horizontally, at right-angles to the quarter-wave matching stub, the variation is usually called a Zepp antenna.[4]

J-pole antenna fed by coaxial cable (left) and parallel line (right). The right diagram shows the standing waves of voltage (V, red bands) and current (I, blue bands) on the elements.

How it works edit

The J-pole antenna is an end-fed omnidirectional half-wave antenna that is matched to the feedline by a shorted quarter-wave parallel transmission line stub.[5][1][6] For a transmitting antenna to operate efficiently, absorbing all the power provided by its feedline, the antenna must be impedance matched to the line; it must have a resistance equal to the feedline's characteristic impedance. A half-wave antenna fed at one end has a current node at its feedpoint, giving it a very high input impedance of around 1 000–4 000 ohms.[5] This is much higher than the characteristic impedance of transmission lines, so it requires an impedance matching circuit between the antenna and the feedline.

A shorted quarter-wave stub, a transmission line one quarter of the wavelength long with its conductors shorted together at one end, has a similar high impedance node at its open end, making a good match to the antenna. The input impedance seen at a point along the stub varies continuously, decreasing monotonically from this high value to zero at the shorted end. So any value of input impedance can be obtained by connecting the feedline to the proper point along the stub. One arm of the stub is extended a half wavelength to make the antenna. By attaching the antenna's feedline to the proper point along the transmission line, the stub will transform this impedance down to match the lower feedline impedance, allowing the antenna to be fed power efficiently.[6] During construction the proper attachment point for the feed-line is found by sliding the connection of the feedline back and forth along the stub while monitoring the SWR until an impedance match (minimum SWR) is obtained.[1][6] Being a half-wave antenna, it provides a small gain of just under 1 dB over a quarter-wave ground-plane antenna.[7]

Gain and radiation pattern edit

 
E-plane gain measurements of J antenna with respect to reference dipole.

Primarily a dipole, the J-pole antenna exhibits a mostly omnidirectional pattern in the horizontal (H) plane with an average free-space gain near 2.2 dBi (0.1 dBd).[8] Measurements and simulation confirm the quarter-wave stub modifies the circular H-plane pattern shape increasing the gain slightly on the side of the J stub element and reducing the gain slightly on the side opposite the J stub element.[8][9] At right angles to the J-stub, the gain is closer to the overall average: about 2.2 dBi (0.1 dBd).[8] The slight increase over a dipole's 2.15 dBi (0 dBd) gain represents the small contribution to the pattern made by the current imbalance on the matching section.[8] The pattern in the elevation (or E plane) reveals a slight elevation of the pattern in the direction of the J element while the pattern opposite the J element is mostly broadside.[9] The net effect of the perturbation caused by quarter-wave stub is an H-plane approximate gain from 1.5 to 2.6 dBi (-0.6 dBd to 0.5 dBd).[9]

Environment edit

Like all antennas, the J-pole is sensitive to electrically conductive objects in its induction fields[10] (aka reactive near-field region[11]) and should maintain sufficient separation to minimize these near field interactions as part of typical system installation considerations.[12] The quarter wave parallel transmission line stub has an external electromagnetic field with strength and size proportional to the spacing between the parallel conductors.[13] The parallel conductors must be kept free of moisture, snow, ice and should be kept away from other conductors including downspouts, metal window frames, flashing, etc. by a distance of two to three times the spacing between the parallel stub conductors.[4] The J-pole is very sensitive to conductive support structures and will achieve best performance with no electrical bonding between antenna conductors and the mounting structure.[14][15]

Construction edit

The antenna consists of two parallel straight metal conductors, one 3/4 of a wavelength and the other 1/4 of a wavelength long at the operating frequency, shorted together at the bottom.[citation needed] Typical construction materials include metal tubing,[1] ladder line, or twin-lead.[16] Since the matching section must act as a transmission line, the parallel conductors should be no more than .02 wavelength apart.[17]

The J-pole antenna and its variations may be fed with balanced line.[1] A coax feed line may be used if it includes a means to suppress feed-line RF currents.[14][18] The feed-point of the J-pole is somewhere between the closed low-impedance bottom and open high-impedance top of the J stub.[1][3] Between these two extremes a match to any impedance between the low to high impedance points is available.[1][3]

The J-pole design functions well when fed with a balanced feed (via balun, transformer or choke) and no electrical connection exists between its conductors and surrounding supports.[14][15] Historical documentation of the J antenna suggests the lower end of the matching stub is at zero potential with respect to earth and can connect to a grounding wire or mast with no effect on the antenna's operation.[1] Later research confirms the tendency of the mast or grounding wire to draw current from the antenna potentially spoiling the antenna pattern.[19] A common approach extends the conductor below the bottom of the J-pole resulting in additional and undesirable RF currents flowing over every part of the mounting structure.[14] This modifies the far field antenna pattern[19] typically, but not always, raising the primary lobes above the horizon reducing antenna effectiveness for terrestrial service.[15] J-pole antennas with electrical connection to their supports often fare no better, and often much worse, than the simpler monopole antenna.[14] A mast decoupling stub reduces mast currents.[19][20][21][22]

Variations edit

 
J-pole Antenna and variations of same.
 
E-plane gain plots of J antenna variations

Slim Jim antenna edit

A variation of the J-pole is the Slim Jim antenna, also known as G2BCX Slim Jim,[23] that is related to the J-pole in a similar way to how a folded dipole is related to a dipole.[24] The Slim Jim is one of many ways to form a J-Pole.[24] Introduced by Fred Judd (G2BCX) in 1978, the name was derived from its slim construction and the J type matching stub (J Integrated Matching).[23]

The Slim Jim variation of the J-pole antenna has characteristics and performance similar to a simple or folded half-wave antenna and identical to the conventional J-pole construction.[24] Judd reported that the Slim Jim produces a lower takeoff angle and better electrical performance than a 5/8 wavelength ground plane antenna,[23] however others' test and analyses show Slim Jim antennas to have no performance advantage over a conventional, single-wire J-pole antenna.[9][24] Slim Jim antennas made from ladder transmission line use the existing parallel conductor for the folded dipole element,[9] but in the copper pipe variation, the Slim Jim requires almost twice as much material, for which it returns no performance benefit.[9]

The approximate gain in the H-plane of the Slim Jim is from 1.5 to 2.6 dBi (−0.6 dBd to 0.5 dBd).[9]

Super-J antenna edit

The Super-J variation of the J-pole antenna adds another collinear half-wave radiator above the conventional J and connects the two with a phase stub to ensure both vertical half-wave sections radiate in current phase.[25] The phasing stub between the two half-wave sections is often of the Franklin style.[25][26][27]

The Super-J antenna compresses the vertical beamwidth and has more gain than the conventional J-pole design.[28] Both radiating sections have insufficient separation to realize the maximum benefits of collinear arrays, resulting in slightly less than the optimal 3 dB over a conventional J-pole or halfwave antenna.[28][29]

The approximate gain in the H-plane of the Super-J antenna is from 4.6 to 5.2 dBi (2.4 dBd to 3.1 dBd).[29]

Collinear J antenna edit

The collinear J antenna improves the Super-J by separating the two radiating half-wave sections to optimize gain using a phasing coil.[29] The resulting gain is closer to the optimum 3 dB over a conventional J-pole or halfwave antenna.[29]

The approximate gain in the H-plane of the Collinear J antenna is from 4.6 to 5.2 dBi (2.4 dBd to 3.1 dBd).[29]

E-plane gain patterns of the variations edit

The graph compares the E-plane gain of the above three variations to the conventional J antenna.

The conventional J antenna and SlimJIM variation are nearly identical in gain and pattern. The Super-J reveals the benefit of properly phasing and orienting a second radiator above the first. The Collinear J shows slightly higher performance over the Super-J.

Dual-band operation near 3rd harmonic edit

The basic J antenna resonates on the third harmonic of its lowest design frequency.[30] Operating a 3/2 wavelengths this way produces an antenna pattern unfavorable for terrestrial operation.[31]

To address the pattern change a variety of techniques exist to allegedly constrain a J antenna operating at or near the third harmonic so only one half-wave is active in the radiator above the stub. All involve the use of a high impedance choke at the first voltage loop.[31] These methods fall short of the goal as choking a high impedance point with a high impedance allows energy to pass the choke.[31][32]

References edit

  1. ^ a b c d e f g h i "Very-High-Frequency Antennas". Antennas and Antenna Systems (TM 11-314) (PDF). U.S. War Department. 30 November 1943. pp. 163–164. Retrieved 6 May 2016.
  2. ^ Beggerow, Hans (19 September 1909). "German patent 225204" (PDF). Zeppelin Antenna. Retrieved 28 January 2016.
  3. ^ a b c US patent 2124424, Laurance McConnell Leeds, "Antenna System", published 1938-07-19 
  4. ^ a b Hall, Gerald; et al., eds. (1988). The ARRL Antenna Book (15th ed.). Newington, CT: American Radio Relay League. p. 24.25. ISBN 0-87259-206-5.
  5. ^ a b The A.R.R.L. Antenna Book. Radio Amateurs' Library. Vol. Issue 15 (5th ed.). West Hartford, CT / Concord, NH: American Radio Relay League / Rumford Press. 1949. pp. 91–92 – via Google books. {{cite book}}: |volume= has extra text (help)
  6. ^ a b c Brown, George, ed. (July 2001). Radio and Electronics Cookbook. Potters Bar, Herts., UK / Oxford, UK: Radio Society of Great Britain / Newnes. pp. 149–150. ISBN 9780750652148 – via Google books. ISBN 0-7506-5214-4
  7. ^ Huggins, John S. (6 November 2008). "1/4 wave monopole vs. 1/2 wave J-pole EZNEC shootout". Ham Radio: Magnum Experimentum (hamradio.me). Retrieved 30 January 2012.
  8. ^ a b c d Cebik, L.B. "Some J-poles that I have known, Part 1: Why I finally got interested in J-poles, and some cautions in modeling them". Cebik.com. Archived from the original on 22 April 2014. Retrieved 1 October 2015.
  9. ^ a b c d e f g Huggins, John S. (19 August 2015). "Slim-Jim vs. traditional J-pole antenna". Ham Radio: Magnum Experimentum (hamradio.me). Retrieved 28 August 2015.
  10. ^ Griffith, B. Whitfield (1962). Radio-Electronic Transmission Fundamentals. New York, NY: McGraw Hill. pp. 322–323.
  11. ^ Balanis, Constantine (1982). Antenna Theory. Harper & Row. pp. 116–118. ISBN 0-06-040458-2.
  12. ^ Collins, Brian (1984). "VHF and UHF communication antennas". In Johnson, Richard (ed.). Antenna Engineering Handbook (2nd ed.). New York, NY: McGraw-Hill. pp. 27.21–27.22. ISBN 0-07-032291-0.
  13. ^ Griffith, B. Whitfield (1962). Radio-Electronic Transmission Fundamentals. New York, NY: McGraw Hill. pp. 243–244.
  14. ^ a b c d e Huggins, John S. (28 January 2012). "J-pole antenna: Should I ground it?". Ham Radio: Magnum Experimentum (hamradio.me). Retrieved 30 January 2012.
  15. ^ a b c Richardson, Dan (March 1998). "The J-pole revisited" (PDF). CQ Magazine. pp. 34–41. Retrieved 30 January 2012.
  16. ^ Fong, Edison (March 2007). "The DBJ-2: A Portable VHF-UHF Roll-Up J-pole Antenna for Public Service". QST. Newington, CT: ARRL, Inc.
  17. ^ Teeters, Chuck (December 2005). "The trouble with J antennas". The Splatter, December 2005 edition. Amateur Radio Club of Augusta website, Augusta, Georgia. Retrieved 15 November 2021.
  18. ^ A folded-balun, sleeve balun, or common-mode choke will suppress feed-line RF currents. See: Straw, Dean (2007). "26 - Coupling the Line to the Antenna". The ARRL Antenna Book. Newington, CT: The ARRL, Inc. ISBN 978-0-87259-987-1.
  19. ^ a b c Huggins, John S. "Have your J-Pole and ground it too". Retrieved 4 March 2015.
  20. ^ Huggins, John S. "Mast Mountable J-Pole Antenna". Retrieved 17 June 2015.
  21. ^ US patent 10468743, "Antenna", issued 2019-11-05 
  22. ^ US patent D798847, "Antenna", issued 2017-10-03 
  23. ^ a b c Judd, Fred (1978). "Slim Jim - 2 metre aerial". Practical Wireless - Out of Thin Air: 37–39. Retrieved 24 April 2014.
  24. ^ a b c d Cebik, L.B. "What is a Slim Jim?". Cebik.com. Archived from the original on 24 April 2014. Retrieved 30 January 2012 – via net46.net.
  25. ^ a b Steve Cerwin (2007). "Mobile and Maritime Antennas - The Super-J Maritime Antenna". In Straw, Dean (ed.). ARRL Antenna Book (21st ed.). Newington, CT: The American Radio Relay League, Inc. pp. 16.23–16.26. ISBN 978-0-87259-987-1.
  26. ^ Franklin, Charles (1924). "Franklin Antenna" (PDF). Retrieved 28 January 2016.
  27. ^ Collins, Brian (1984). "VHF and UHF Communication Antennas - Base-Station Antennas". In Johnson, Richard; Henry Jasik (eds.). Antenna Engineering Handbook (2nd ed.). New York: McGraw-Hill. p. 27.14. ISBN 0-07-032291-0.
  28. ^ a b Cebik, L.B. "Some J-Poles that I have known, Part 4: Some things we can and cannot do with a J-Pole". Cebik.com. Archived from the original on 22 April 2014. Retrieved 21 April 2014.
  29. ^ a b c d e Huggins, John S. "Improving the Super J-Pole Antenna". Retrieved 21 April 2014.
  30. ^ Huggins, John. "Can a 2m J-Pole be used at 440?". Hamradio.me. Retrieved 12 June 2019.
  31. ^ a b c Huggins, John. "Antenna radiator decoupling stub flub?". Hamradio.me. Retrieved 12 June 2019.
  32. ^ Huggins, John. "Where quarter-wave radiator decoupling stubs work ... and don't work". Hamradio.me. Retrieved 12 June 2019.

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