General/Chapter 8 Study Guide: Difference between revisions
From charlesreid1
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* Absorption increases with sunlight, ionization, more UV, and lower frequencies | * Absorption increases with sunlight, ionization, more UV, and lower frequencies | ||
Sky-wave and ground-wave propagation | |||
* Reflection by ionosphere is called '''hop''' | |||
* Signals received via waves bouncing off of ionosphere called '''sky-wave propagation''' | |||
* Propagation via ionosphere called '''skip''' | |||
** Skip via higher ionosphere layers travel further | |||
** F2 layer skip travels up to 2,500 miles | |||
** E layer skip travels up to 1,200 miles | |||
** Sky wave propagation can also skip over Earth's surface | |||
* Ocean's surface reflects radio waves (salt water) | |||
* Skip can also travel shorter distance as angle increased | |||
* Short skip can indicate there is larger skip available at lower frequencies | |||
** Short skip on 10 m indicates long skip on 6 m | |||
* Ionosphere has many variations in density, turbulent, rough | |||
* Variations can cause signals to take multiple paths | |||
* Multipath signals have echo/flutter | |||
* Ground wave signals attenuated more (ground not good conductor) | |||
* Higher frequency ground waves attenuated more | |||
* Ring-shaped region around station forms skip zone (further than maximum ground wave and shorter than minimum sky wave) | |||
* Stations in skip zone can't be contacted | |||
Long path/short path | |||
* Short path: shorter of great circle paths between two stations | |||
* Long path: travels long way around globe | |||
* If signal travels by both paths, short delay/echo | |||
* Round the world propagation: 1/7 second delay with own signal | |||
===Section 8.1 Summary=== | ===Section 8.1 Summary=== | ||
* When making a long path contact, antenna is pointed 180 degrees from short path heading | |||
* If sky wave signal arriving via short '''and''' long path, a well-defined echo will be heard | |||
* A good indicator of possible sky-wave propagation ('''long skip propagation''') on 6 m is, '''short skip skywave propagation''' on the 10 m band | |||
* Radio waves with frequencies below MUF and above LUF sent into ionosphere will be bent back to Earth | |||
* Approximate maximum distance covered by F2 layer skips is 2,500 miles | |||
* Approximate maximum distance covered by E layer skips is 1,200 miles | |||
* Ionospheric layer closest to surface of Earth is D layer | |||
* Earth's ionospheric layers reach maximum height where the sun is directly overhead | |||
* F2 region responsible for longest radio wave propagation because it is the highest ionospheric region | |||
* Critical angle in radio wave propagation refers to highest takeoff angle that will return the wave3 to Earth | |||
* Long distance communication on 40 m, 60 m, 80 m, 160 m, more difficult during day because the D layer absorbs these frequencies during the day | |||
* Ionospheric layer that absorbs most long skip signals during daylight, below 10 MHz, is D layer | |||
==Section 8.2: The Sun== | |||
Sunspots and cycles: | |||
* Sn generates UV rays, but a lot of variation over time | |||
* Variations caused by sunspots (cooler regions on Sun surface) | |||
* Sunspot number - number of sunspots present on solar disk | |||
* Sunspots vary over an 11 year period (sunspot cycle) | |||
* More sunspots lead to more UV radiation lead to more intense ionization | |||
* More ionization improves propagation on HF above 10 MHz, and into low VHF | |||
* Peak sunspot: bands like 10 m stay open into the evening, enabling long-distance contacts | |||
* High ionization increases absorption, takes a toll on 80 m and 160 m | |||
* Bottom on sunspot cycle: low HF bands have good propagation and higher bands (20 MHz) stay open | |||
* 20 m (14 MHz) supports daytime communication during the day | |||
* Sun rotates every 28 days, so spots change nad move | |||
* Propagation conditions can repeat themselves every 28 days | |||
* Strong daily/seasonal variations in HF propagation | |||
* Seasonal variation: summer, higher illumination, higher absorption, shifts HF activity to nighttime | |||
* Propagation around equinoxes (March/September) can be interesting | |||
Band: 160 m / 80 m / 60 m | |||
* Daytime: local and regional contacts, 100-200 miles | |||
* Nighttime: local to long distance, best near sunset/sunrise | |||
Band: 40 m / 30 m | |||
* Daytime: local and regional contacts, 300-400 miles | |||
* Nighttime: short and medium range to worldwide communications | |||
Band: 20 m / 17 m | |||
* Daytime: regional to long distance, open at sunrise, closing at nighttime | |||
* Nighttime: Open to west at night, may be open 24 hours | |||
Band: 15 m / 12 m / 10 m | |||
* Daytime: primarily long distance, 1,000+ miles | |||
* Nighttime: 10 m used for local communications 24 hours a day | |||
Measuring solar activity: | |||
* Solar activity critical to propagation and communication | |||
* Monitored 24/7 throughout world | |||
* Use of data, experience, and software allows for predicting propagation and being alerted to sudden propagation changes | |||
* '''SFI''' - solar flux index - amount of 2800 MHz radio energy coming from sun | |||
=Flags= | =Flags= | ||
{{GeneralFlag}} | {{GeneralFlag}} | ||
Revision as of 22:53, 30 June 2016
Section 8.1: Ionosphere
- Atmosphere gets thinner as you go further away
- At 30 miles in altitude, gets thin enough that UV rays can knock electrons away from molecules
- Gas is ionized by loss of electron, positively charged ion, negative free electron
- Ion + electron respond to voltage, like electrons in conductor
- Atmospheric layer - ionosphere - becomes weak conductor
- Ionosphere extends to 300 miles above surface of Earth
Regions:
- ISS orbits 200 miles above Earht
- Ionosphere arranged into multiple layers (D, E, F layers)
- D layer - 30-60 miles, only present when illuminated by sun
- E layer - 60-70 miles, similar to D region, lasts longer after sunset
- F layer - 100-300 miles, least dens,e partially ionized at night
- F1 layer/F2 layer - split during day, recombine at night
- Height of regions vary with season, TOD, latitude, solar activity
- F2 is highest layer, reaches highest point at noon
Reflection and absorption
- Weak conduction of layers allows bending/refracting of waves
- Layers of ionosphere can bend waves
- Bending o waves depends on ionization level, and wave frequency
- VHF/UHF waves hardly bent at all
- HF waves bent, can be reflected back to Earth
- Weaker bending requires lower takeoff angles, otherwise waves lost to space
- Critical angle - angle above which all energy lost to space
- Critical frequency - frequency above which all energy lost to space (if pointed straight up)
- Ionosonde - device used for measuring reflection of radio waves by ionosphere
- Absorption is the enemy of propagation
- In D and E layers, waves pass through denser gas regions, absorbed as they are refracted
- For HF bands, below 10 MHz, AM broadcast bands, the D layer completely absorbs radio waves
- Absorption increases with sunlight, ionization, more UV, and lower frequencies
Sky-wave and ground-wave propagation
- Reflection by ionosphere is called hop
- Signals received via waves bouncing off of ionosphere called sky-wave propagation
- Propagation via ionosphere called skip
- Skip via higher ionosphere layers travel further
- F2 layer skip travels up to 2,500 miles
- E layer skip travels up to 1,200 miles
- Sky wave propagation can also skip over Earth's surface
- Ocean's surface reflects radio waves (salt water)
- Skip can also travel shorter distance as angle increased
- Short skip can indicate there is larger skip available at lower frequencies
- Short skip on 10 m indicates long skip on 6 m
- Ionosphere has many variations in density, turbulent, rough
- Variations can cause signals to take multiple paths
- Multipath signals have echo/flutter
- Ground wave signals attenuated more (ground not good conductor)
- Higher frequency ground waves attenuated more
- Ring-shaped region around station forms skip zone (further than maximum ground wave and shorter than minimum sky wave)
- Stations in skip zone can't be contacted
Long path/short path
- Short path: shorter of great circle paths between two stations
- Long path: travels long way around globe
- If signal travels by both paths, short delay/echo
- Round the world propagation: 1/7 second delay with own signal
Section 8.1 Summary
- When making a long path contact, antenna is pointed 180 degrees from short path heading
- If sky wave signal arriving via short and long path, a well-defined echo will be heard
- A good indicator of possible sky-wave propagation (long skip propagation) on 6 m is, short skip skywave propagation on the 10 m band
- Radio waves with frequencies below MUF and above LUF sent into ionosphere will be bent back to Earth
- Approximate maximum distance covered by F2 layer skips is 2,500 miles
- Approximate maximum distance covered by E layer skips is 1,200 miles
- Ionospheric layer closest to surface of Earth is D layer
- Earth's ionospheric layers reach maximum height where the sun is directly overhead
- F2 region responsible for longest radio wave propagation because it is the highest ionospheric region
- Critical angle in radio wave propagation refers to highest takeoff angle that will return the wave3 to Earth
- Long distance communication on 40 m, 60 m, 80 m, 160 m, more difficult during day because the D layer absorbs these frequencies during the day
- Ionospheric layer that absorbs most long skip signals during daylight, below 10 MHz, is D layer
Section 8.2: The Sun
Sunspots and cycles:
- Sn generates UV rays, but a lot of variation over time
- Variations caused by sunspots (cooler regions on Sun surface)
- Sunspot number - number of sunspots present on solar disk
- Sunspots vary over an 11 year period (sunspot cycle)
- More sunspots lead to more UV radiation lead to more intense ionization
- More ionization improves propagation on HF above 10 MHz, and into low VHF
- Peak sunspot: bands like 10 m stay open into the evening, enabling long-distance contacts
- High ionization increases absorption, takes a toll on 80 m and 160 m
- Bottom on sunspot cycle: low HF bands have good propagation and higher bands (20 MHz) stay open
- 20 m (14 MHz) supports daytime communication during the day
- Sun rotates every 28 days, so spots change nad move
- Propagation conditions can repeat themselves every 28 days
- Strong daily/seasonal variations in HF propagation
- Seasonal variation: summer, higher illumination, higher absorption, shifts HF activity to nighttime
- Propagation around equinoxes (March/September) can be interesting
Band: 160 m / 80 m / 60 m
- Daytime: local and regional contacts, 100-200 miles
- Nighttime: local to long distance, best near sunset/sunrise
Band: 40 m / 30 m
- Daytime: local and regional contacts, 300-400 miles
- Nighttime: short and medium range to worldwide communications
Band: 20 m / 17 m
- Daytime: regional to long distance, open at sunrise, closing at nighttime
- Nighttime: Open to west at night, may be open 24 hours
Band: 15 m / 12 m / 10 m
- Daytime: primarily long distance, 1,000+ miles
- Nighttime: 10 m used for local communications 24 hours a day
Measuring solar activity:
- Solar activity critical to propagation and communication
- Monitored 24/7 throughout world
- Use of data, experience, and software allows for predicting propagation and being alerted to sudden propagation changes
- SFI - solar flux index - amount of 2800 MHz radio energy coming from sun
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General Class Ham License Notes from studying for my General Class ham license.
Chapter 2: Procedures and Practices: General/Chapter 2 Study Guide Chapter 3: Rules and Regulations: General/Chapter 3 Study Guide Chapter 4: Components and Circuits: General/Chapter 4 Study Guide Chapter 5: Radio Signals and Equipment: General/Chapter 5 Study Guide Chapter 6: Digital Modes: General/Chapter 6 Study Guide Chapter 7: Antennas: General/Chapter 7 Study Guide Chapter 8: Propagation: General/Chapter 8 Study Guide Chapter 9: Electrical and RF Safety: General/Chapter 9 Study Guide Flags · Template:GeneralFlag · e |