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The New 630m Amateur Band

The New 630m Amateur Band. Rudy Severns N6LF, WD2XSH/20 n6lf@arrl.net , www.antennasbyn6lf.com. A New Amateur Band. After many years on the air using experimental licenses and intense politicking, at the 2012 World Radio Conference (WRC) amateurs were allocated a new MF band: 472-479 kHz.

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The New 630m Amateur Band

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  1. The New 630m Amateur Band Rudy Severns N6LF, WD2XSH/20 n6lf@arrl.net, www.antennasbyn6lf.com

  2. A New Amateur Band After many years on the air using experimental licenses and intense politicking, at the 2012 World Radio Conference (WRC) amateurs were allocated a new MF band: 472-479 kHz. Telecom authorities in various countries are now in the process of authorizing their amateurs to use the band. Many Europeans, VE, VK, ZL and even XV are on the air and we’re bugging the FCC to move!

  3. 630 m Band 472-479 kHz. Emissions: CW and digital modes Radiated power limited to 5W EIRP (Effective Isotropic Radiated Power) No limitations on transmitter power or antenna size. i.e. you can use a small transmitter with a large antenna or a high power transmitter with a small antenna.

  4. Common Perceptions! A 7 kHz band is too narrow to be of use! The QRM will kill you! At such a low frequency with only 5W you can’t be heard down the block! The manmade and natural noise levels are so high you can’t hear anything! It’s impossible for amateurs on city lots to erect an effective antenna. No amateur equipment transmits on 630m. None of this is true!

  5. Why go to 630m? • If you’re a bit tired of the same old stuff 630m is a fresh challenge: • Very different propagation • New very narrow digital modes • But also the oldest mode – CW • Station-computer integration • Receiving and transmitting equipment • Antennas • Boat anchor resurrection

  6. Acknowledgements Much of the material presented here has been excerpted from the presentations of other amateurs: Fritz Raab W1FR, WD2XSH/14 John Langridge KB5NJD, WG2XIQ Neil Klagge, W0YSE,WG2XSV

  7. 500 kHz History Maritime CW calling/distress frequency since 1906 415-495 kHz commercial ship-ship and ship-shore working frequencies also Navy Rich traditions and history Amateurs banned for >100 years! Automated satellite reporting adopted in 1980s CW and monitoring of 500 kHz ceased in 1990s 500 kHz now unused except by museum stations

  8. The spectrum below the BC band Navigational telex

  9. ARRL experimental group First operation September 2006, W1FR experiment coordinator Originally 23 stations were licensed (WD2XSH/1 thru WD2XSH/23) Frequency allocation: 495-510 kHz, 20W ERP Ultimately it was expanded to 45 licensees with added frequencies: 461-478 kHz This operation and that of many others provided the ammunition for the WRC allocation battle!

  10. ARRL experimental stations

  11. WD2XSH CW QSO’s

  12. CW DX reception reports V73

  13. CW beacon reception reports /20

  14. WD2XSH/14 (W1FR)

  15. Original WD2XSH/20 (N6LF)

  16. Latest WD2XSH/20 (N6LF)

  17. Latest WD2XSH/20 (N6LF)

  18. Filters!

  19. Boat anchors at N6LF

  20. WD2XSH/5 (KW1I) RBA receiver and an ART13 transmitter

  21. WD2XSH/9 (W2ILA) Maritime reserve XMTR

  22. WD2XSH/12 (AI8Z) HB pair 6146’s

  23. WD2XSH /15 (W5OR) SAC H-25 NDB XMTR

  24. Nice but you don’t have to have it!

  25. MF antenna basics! Succinct summary of LF/MF antennas by Woodrow Smith some 65 years ago: "the main object in the design of low frequency transmitting antenna systems can be summarized briefly by saying that the general idea is to get as much wire as possible as high in the air as possible and to use excellent insulation and an extensive ground system.”

  26. In order of priority Make the vertical as tall as you can. Use as much capacitive top-loading as practical. Use loading coils with as high a Q as possible. Put a lot of effort into the ground system, making the radial density high near the base of the vertical and under the top-loading hat. Try to minimize conductor losses by using multiple wires and/or large diameter conductors (tubing!) Use high quality insulators, both at the base and at wire ends.

  27. T and L antennas

  28. Use the available supports

  29. Umbrella vertical 1

  30. Umbrella vertical 2

  31. WD2XSH/14

  32. WD2XSH/13 antenna

  33. WD2XSH/19 antenna

  34. WD2XSH/6 (W5THT) antenna

  35. ATU box

  36. Inside the ATU

  37. Tuning the ATU

  38. WD2XSH/20 antenna

  39. Latest antenna at N6LF 95’ high, 240’ across, 128 150’ radials on the ground There’s a very extensive discussion of MF antennas at: www.antennasbyn6lf.com

  40. Antenna poles at N6LF

  41. Base tuning box

  42. Tuning-matching inductor

  43. Poles assembled on the ground

  44. Pole erected with a crane

  45. Propagation • Daytime – ground wave • WG2XIQ range at 1W ERP = about 225 miles on a quiet day for a typically equipped receive station • Nighttime – sky wave dominates plus some ground wave • Sky wave can extend thousands of miles • Behavior similar to bottom of the BC band at 630-meters • Sometimes there are surprises

  46. Start by listening…

  47. Transmission modes CW QRSS – ultra slow CW WSPR-2 & -15 (weak signal propagation reporter). SNR down to -30 dB or lower! 2-way digital modes: BPSK31, JT9, JT65, RTTY, hellschriber and a wide variety of new modes being created and tested almost daily!

  48. WSPR –K1JTWWW.physics.princeton.edu/pulsar/K1JT/wsjt.html WSPR-2 and -15 is a tool for quantitatively testing propagation between a transmitting station and a receiving station. Typically the WSPR signals are transmitted periodically over a period of many hours with the receiving station recording the decodes and forwarding them on to WSPRnet.org where they are available in the database. Example:

  49. WSPR Mapping

  50. WSPR Data

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