Transequatorial VHF-UHF Propagation

Similar documents
1. Terrestrial propagation

TRANSEQUATORIAL RADIO PROPAGATION

AN INTRODUCTION TO VHF/ UHF PROPAGATION. Paul Wilton, M1CNK

Global Maps with Contoured Ionosphere Properties Some F-Layer Anomalies Revealed By Marcel H. De Canck, ON5AU. E Layer Critical Frequencies Maps

Reading 28 PROPAGATION THE IONOSPHERE

Chapter 7 HF Propagation. Ionosphere Solar Effects Scatter and NVIS

New applications of the portable heater. Gennady Milikh, UMD-SPP group

Topics in Propagation

4/29/2012. General Class Element 3 Course Presentation. Radio Wave Propagation. Radio Wave Propagation. Radio Wave Propagation.

Chapter 6 Propagation

Space Weather and Propagation JANUARY 14, 2017

On sporadic E VHF propagation and solving a mystery about maximum usable frequencies Part 1

Storms in Earth s ionosphere

50 MHz F 2 Propagation Mechanisms

Antennas and Propagation Chapters T4, G7, G8 Antenna Fundamentals, More Antenna Types, Feed lines and Measurements, Propagation

Propagation During Solar Cycle 24. Frank Donovan W3LPL

2 Propagation mechanisms responsible for propagation at frequencies above the basic MUF

4/18/2012. Supplement T3. 3 Exam Questions, 3 Groups. Amateur Radio Technician Class

Introduction To The Ionosphere

Satellite Navigation Science and Technology for Africa. 23 March - 9 April, The African Ionosphere

Emergency Antennas VHF / UHF - FM. HF Voice, CW, or Digital

Ionospheric Impacts on UHF Space Surveillance. James C. Jones Darvy Ceron-Gomez Dr. Gregory P. Richards Northrop Grumman

Radio Frequency Propagation: A General Overview from LF to VHF.

RF Propagation. By Tim Kuhlman, PE KD7RUS

Currents, Electrojets and Instabilities. John D Sahr Electrical Engineering University of Washington 19 June 2016

Technician License Course Chapter 4

Special Thanks: M. Magoun, M. Moldwin, E. Zesta, C. Valladares, and AMBER, SCINDA, & C/NOFS teams

VHF and L-band scintillation characteristics over an Indian low latitude station, Waltair (17.7 N, 83.3 E)

Ionospheric Propagation

14. COMMUNICATION SYSTEM

Ionospheric Sounders What are they? How can you use them?

RECOMMENDATION ITU-R P Method for the prediction of the performance of HF circuits *, **

Recent progress of NICT ionospheric observations in Japan

OBJECTIVES: PROPAGATION INTRO RADIO WAVES POLARIZATION LINE OF SIGHT, GROUND WAVE, SKY WAVE IONOSPHERE REGIONS PROPAGATION, HOPS, SKIPS ZONES THE

VHF and Microwave Propagation Characteristics of Ducts

Ionospheric Propagation

The Significance of GNSS for Radio Science

RECOMMENDATION ITU-R P Guide to the application of the propagation methods of Radiocommunication Study Group 3

RECOMMENDATION ITU-R P HF propagation prediction method *

Regional and Long Distance Skywave Communications

RF Propagation. By Tim Kuhlman, PE KD7RUS

Time of flight and direction of arrival of HF radio signals received over a path along the midlatitude trough: Theoretical considerations

right during the VE Session Have fun Bob, KA9BH Eric, K9VIC

Sw earth Dw Direct wave GRw Ground reflected wave Sw Surface wave

EFFECTS OF SCINTILLATIONS IN GNSS OPERATION

Lesson 12: Signal Propagation

Using the Radio Spectrum to Understand Space Weather

UNIT Derive the fundamental equation for free space propagation?

Impact of the low latitude ionosphere disturbances on GNSS studied with a three-dimensional ionosphere model

High Frequency Propagation (and a little about NVIS)

Maximum Usable Frequency

Technical and operational characteristics of land mobile MF/HF systems

Dartmouth College SuperDARN Radars

MWA Ionospheric Science Opportunities Space Weather Storms & Irregularities (location location location) John Foster MIT Haystack Observatory

RECOMMENDATION ITU-R P HF PROPAGATION PREDICTION METHOD* (Question ITU-R 223/3)

A first study into the propagation of 5 MHz (60 m) signals using the South African ionosonde network

Radio tomography based on satellite beacon experiment and FORMOSAT- 3/COSMIC radio occultation

F-Region Propagation and the Equatorial Ionospheric Anomaly Jim Kennedy K6MIO/KH6 Hilo HI

CRITICAL FREQUENCY By Marcel H. De Canck, ON5AU

Ionospheric sounding at the RMI Geophysical Centre in Dourbes: digital ionosonde performance and ionospheric monitoring service applications

50 MHz Long-Path Propagation Jim Kennedy KH6/K6MIO

Vertical E B drift velocity variations and associated low-latitude ionospheric irregularities investigated with the TOPEX and GPS satellite data

Measurements of doppler shifts during recent auroral backscatter events.

Nighttime sporadic E measurements on an oblique path along the midlatitude trough

Modelling the Ionosphere

RADIO WAVES PROPAGATION

Three-dimensional and numerical ray tracing on a phenomenological ionospheric model

Terry G. Glagowski W1TR / AFA1DI

Data and Computer Communications Chapter 4 Transmission Media

General Classs Chapter 7

RECOMMENDATION ITU-R P Prediction of sky-wave field strength at frequencies between about 150 and khz

Section 1 Wireless Transmission

Ionospheric Raytracing in a Time-dependent Mesoscale Ionospheric Model

A Review of WICEN HF Communications Capability

Radio Communication. Presentation created by: András Balogh

Chapter 3. Mobile Radio Propagation

PART 1 RECOMMENDATION ITU-R P.1144 GUIDE TO THE APPLICATION OF THE PROPAGATION METHODS OF RADIOCOMMUNICATION STUDY GROUP 3

3 Methods of radiocommunication

3-2-2 Effects of Transequatorial Thermospheric Wind on Plasma Bubble Occurrences

SuperDARN (Super Dual Auroral Radar Network)

Antennas and Propagation. Prelude to Chapter 4 Propagation

VHF Propagation Overview 5-Oct-2016

Evolution of the WSJT Digital Modes

Antennas and Propagation. Chapter 5

Observation of Scintillation Events from GPS and NavIC (IRNSS) Measurements at Bangalore Region

Antennas and Propagation. Chapter 5

Near real-time input to an HF propagation model for nowcasting of HF communications with aircraft on polar routes

Terrestrial Propagation at LWA Frequencies

Daytime modelling of VLF radio waves over land and sea, comparison with data from DEMETER Satellite

Effects of magnetic storms on GPS signals

Investigation of height gradient in vertical plasma drift at equatorial ionosphere using multifrequency HF Doppler radar

CHAPTER 6. Propagation

EISCAT Experiments. Anders Tjulin EISCAT Scientific Association 2nd March 2017

Summer VHF-UHF Field Day 2016: fun in the sun!

Monitoring the polar cap/ auroral ionosphere: Industrial applications. P. T. Jayachandran Physics Department University of New Brunswick Fredericton

imaging of the ionosphere and its applications to radio propagation Fundamentals of tomographic Ionospheric Tomography I: Ionospheric Tomography I:

Chapter 2 Analysis of Polar Ionospheric Scintillation Characteristics Based on GPS Data

Broad Principles of Propagation 4C4

Session2 Antennas and Propagation

Propagation Software Review rev 1

Transcription:

Transequatorial VHF-UHF Propagation the next challenges for VK Roger Harrison VK2ZRH GippsTech Conference 2007 Churchill, Victoria Australia 1

A Rayleigh-Taylor production There are holes in the sky Where the ions don t run Those holes are long and large That s why T-E-P is fun! - with due acknowledgement to Spike Milligan Copyright Roger Harrison VK2ZRH 2007, 2008 1 st Australian serial rights granted to the Eastern Zone Amateur Radio Club, Victoria, for publication in Proceedings of the GippsTech Conference 2007 2

TEP defined Transequatorial propagation (TEP) involves the reliable reception of signals or the making of two-way contacts over very long paths that cross the geomagnetic equator on frequencies well beyond the usual MUFs often at unexpectedly high signal strengths. 3

Two modes of TEP Afternoon-type experienced predominantly between 1400 and 1900 LMT (relative to the path mid-point) Evening-type predominantly occurs between 2000 and 2300 LMT (relative to the path mid-point) Each is now referred to by its mode of propagation 4

Two modes of TEP Afternoon-type is called super mode TEP propagation involves two F-layer reflections north and south of the geomagnetic equator without an intermediate ground reflection ( chordal hop ) MOFs typically 40-55 MHz, up to 60-70 MHz sometimes path lengths range typically from 4000 km to 10,000+ km often strong, steady signals only small Doppler shift peak seasonal occurrence is equinoctial occurrence rate follows the solar cycle 5

Two modes of TEP Evening-type is called ducted mode TEP propagation is via ducting or guiding through equatorial plasma bubbles field-aligned bubbles or tubes of depleted ionisation which thread the nighttime equatorial ionosphere, extending symmetrically north and south of the geomagnetic equator MOFs often extend to 144 MHz some 432 MHz This is where the next challenges are for VK 6

Ducted mode TEP in detail From how we experience it, to the mechanics of how it happens 7

Times and durations of openings predominant occurrence between 2000-2300 LMT may start earlier, occasionally extends past 2400 openings typically last 20-40 minutes, sometimes less a series of openings often occurs, from seemingly continuous (overlapping), or up to 30 mins or so apart duration of openings decreases at the higher frequencies 8

Times and durations of openings 9

Seasonal characteristics peak occurrence during the equinox months: Mar-April / Sept-Oct the higher frequencies have shorter seasons, fewer openings on low VHF, openings still occur thru the solstice months 10

Solar cycle dependency occurrence rate of openings maximises during solar maximum years openings never disappear during solar minimum years MOFs are greater during solar maximum years however,144 MHz openings have been reported during the 2006 and 2007 equinoctial seasons as we pass across solar minimum 11

Paths are bisected by the geomagnetic equator cross the geomagnetic equator within a small range of angles close to 90 degrees the path terminals commonly lie in a zone between about 10 and 30 degrees geomagnetic latitude (ie. near magnetic conjugate) paths having an obliquity of 15 degrees or more to the orthogonal experience far fewer openings The higher the frequency, the closer to orthognal with the magnetic equator the path needs to be 12

Paths: global sectors 13

Paths: VK-Asia the paths predominantly worked on 50 MHz and 144 MHz via ducted mode TEP note how the path terminals are near conjugate areas curiously, off-path signals have been recorded: note the ---- line between Singapore and the Darwin-JA path 14

Signal characteristics Distinctive, rapid flutter fading over long-term peaks and troughs; occasional drop-outs. Signal strengths can range from S1 to S9+; S3 to S7 are more usual; decline with increasing frequency. The strongest signals can exceed free-space levels for the distances involved. Doppler shifts ranging from +/ 20 Hz at low VHF (50 MHz) to excursions of 400 Hz on 144 MHz. Doppler smearing of 100s of Hz up to 1-2 khz. Voice modulation (SSB, FM, AM) can suffer severe distortion. 15

Signal characteristics Doppler shift of 144 MHz signals on the Africa-Greece path, measured by SV1DH Fimerelis.and Uzunoglu 1981/1 16

About those bubbles As promised we come to the mechanics when the sun sets on the equatorial ionosphere (about 1900 LMT), the base rises in altitude the more viscous F-layer flows over the less viscous neutral atmosphere this sets up a Rayleigh-Taylor instability ripples form in the base of the F-layer the top of a ripple, having little ionisation, rises into the F-layer this forms a bubble that swiftly elongates north-south along the geomagnetic field lines 17

Equatorial plasma bubbles Simulation of the dramatic development of an equatorial plasma bubble (Huba and Joyce 2007) 18

Equatorial plasma bubbles rise at speeds of typically 125-350 m/s drift eastwards at speeds of 25-125 m/s some bubbles have been recording rising at >2 km/s! reach peak heights of 1500+ km at the geomag. equator the feet can extend to >25 0 geomag. latitude 40-350 km in diameter, spaced 40-100 km apart may be bifurcated (think elephant s trunk!) 19

Equatorial plasma bubbles seasonal occur most often around the equinoxes (it s geometry!) greater occurrence during solar maximum years still occur through years of solar minimum first 144 MHz contacts 1977 year after Cycle 21 mimimum! manifest as spread-f on ionograms from equat. ionosonde stations cause off-great circle/multi-path fading and distortion on HF signals bubble walls are known to be leaky 20

Ducted mode TEP The path geometry in detail 21

A real life path South Africa to Athens 1980s (After Uzunoglu and Fimerelis 1988) 22

Path geometry Entering and exiting a bubble ray path tangent to field line at height of entering bubble elevation angles range from ~2 0 to ~20 0 a cone of acceptance a communications zone on the ground radius of this zone given by: r o = 1.42 x 10 14 /f 144 = 987 km; 432 = 329 km - after Heron and McNamara 1979 23

Path terminals VK-JA dashed ellipse call areas most often worked from Darwin on 2m reported 2m contacts from VK4-JA cover call areas 0,1,2,3 & 7 areas are close to conjugacy paths cross geomagnetic equator at or very close to 90 0 THE NEXT CHALLENGES? 24

The next challenges for VK 1/ bridge VK-JA on 432 MHz 2/ extend the world VHF-UHF TEP DX record ~8000 km * 3/ extend VHF ducted mode TEP via meteor scatter * VK4BFO holds the 144 MHz VK record 6763 km to JI7DMB, 15/04/91 25

Planning for the challenges location: optimise the conjugate communications zones plan around the path loss arrange skeds choose times around when the sunset line is 90 O to the geomag. equator know when bubbles appear HF multipath, Vanimo ionograms 26

Planning for the challenges plan to hit those bubbles tangent to a field line - after McNamara 2005 27

Planning for the challenges follow that bubble! from west to east, low to high elevation - after Heron 1979 28

Extend TEP via meteor scatter Consider this: 29

Ducted mode TEP Between the idea And the reality Between the motion And the act Falls the shadow - T.S. Eliot, "The Hollow Man" 30

2024 © hobbydocbox.com Privacy Policy | Terms of Service | Feedback