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Subelement G3

RADIO WAVE PROPAGATION

Section G3C

Ionospheric layers; critical angle and frequency; HF scatter; Near Vertical Incidence Sky waves

Which of the following ionospheric layers is closest to the surface of the Earth?

  • Correct Answer
    The D layer
  • The E layer
  • The F1 layer
  • The F2 layer

The layers of the atmosphere are in alphabetical order; the D, E, and F layers are considered the ionosphere and the D layer (at a height of 30 to 60 miles) is the region closest to the surface of the earth.

The ionosphere is the portion of the atmosphere responsible for Skywave Propagation (bouncing signals "off of the sky" to come back down long distances away), which makes it of particular interest to Amateur Radio operators.

For more info see Wikipedia: D region

To remember this you may want to remember D for Down.

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Where on the Earth do ionospheric layers reach their maximum height?

  • Correct Answer
    Where the Sun is overhead
  • Where the Sun is on the opposite side of the Earth
  • Where the Sun is rising
  • Where the Sun has just set

The height of the ionospheric layers are extremely dependent on the strength of solar radiation that they receive. The layers reach their maximum height over a specific point when the sun is directly overhead. At this time the energy is "focused" overhead. So the correct answer is where the sun is overhead, as the three remaining answers are times when the sun is not "focused" on your location, but at some other point on the earth.

For more info see Wikipedia: Ionosphere

A simple way to remember this is that the ionosphere is made of air, and hot air rises.

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Why is the F2 region mainly responsible for the longest distance radio wave propagation?

  • Because it is the densest ionospheric layer
  • Because it does not absorb radio waves as much as other ionospheric regions
  • Correct Answer
    Because it is the highest ionospheric region
  • All of these choices are correct

(C). The F2 region appears when the highest layer of the ionosphere (the F region) becomes strongly ionized. As the ionization increases, the F layer splits into the lower F1 region and the higher F2 region. Because it is the highest ionospheric region, long distances may be reached in one bend or "hop" of the signal (up to about 2,500 miles!).

This is why the F2 region is mainly responsible for the longest distance radio wave propagation.

For more info see Wikipedia: F2 region

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What does the term critical angle mean as used in radio wave propagation?

  • The long path azimuth of a distant station
  • The short path azimuth of a distant station
  • The lowest takeoff angle that will return a radio wave to the Earth under specific ionospheric conditions
  • Correct Answer
    The highest takeoff angle that will return a radio wave to the Earth under specific ionospheric conditions

Silly hint: Your health is critical with high blood pressure.

In radio wave propagation, the term critical angle refers to the highest takeoff angle that will return a radio wave to the Earth under specific ionospheric conditions. If the angle of the signal leaving your antenna is too low, it may not reach the ionosphere, or if parallel to the earth, not even make it around the curvature of the earth and be lost. If the angle is too great the signal may go straight through the atmosphere and be lost into space. The critical angle, like the critical frequency levels of MUF and LUF are dependent on the conditions of the ionosphere, as the height of layers change with ionization levels, and the angle needed to reach those levels will change with those factors.

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Why is long distance communication on the 40, 60, 80 and 160 meter bands more difficult during the day?

  • The F layer absorbs signals at these frequencies during daylight hours
  • The F layer is unstable during daylight hours
  • Correct Answer
    The D layer absorbs signals at these frequencies during daylight hours
  • The E layer is unstable during daylight hours

HF frequencies such as the 40, 60, 80 and 160 meter bands are harder to use for long distance communication during the day. The same factors that make the upper E and F layers great for the higher VHF frequencies make the lower D layer more "absorbant" of HF wave signals. The lower HF signals are attenuated or absorbed and so do not pass through for bending at higher ionospheric levels. Ionization is higher during daylight hours, and so the D layer absorbs these frequencies much more during daylight hours. This makes the band much more useful for nighttime use than during the day.

Remember "D" for Daylight, Dull, Diminished. For more info: see Wikipedia

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What is a characteristic of HF scatter signals?

  • They have high intelligibility
  • Correct Answer
    They have a wavering sound
  • They have very large swings in signal strength
  • All of these choices are correct

HF scatter signals often sound distorted because the energy is scattered into the skip zone through several different radio wave paths. When this happens, the original signal is Split or Scattered and will be de-fragmented and may sound distorted at the receiver.

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What makes HF scatter signals often sound distorted?

  • The ionospheric layer involved is unstable
  • Ground waves are absorbing much of the signal
  • The E-region is not present
  • Correct Answer
    Energy is scattered into the skip zone through several different radio wave paths

HF scatter signals often sound distorted because the energy is scattered into the skip zone through several different radio wave paths.


Note:
A signal which is properly adjusted for angle and frequency is like tossing a clump of clay into the air: it makes a nice arc and comes back to earth at one spot, landing with a nice "thunk".

A signal which is scattered into the skip zone is like tossing up that same lump of clay into the air, but this time it hits the leaves of an overhanging tree which breaks up the clump. Some parts gets stuck in the tree, and the parts that do come down land in a wider area, making lots of smaller "scattered" sounds.

Silly, but easy, tip: the word "scatter" is used in the answer.

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Why are HF scatter signals in the skip zone usually weak?

  • Correct Answer
    Only a small part of the signal energy is scattered into the skip zone
  • Signals are scattered from the magnetosphere which is not a good reflector
  • Propagation is through ground waves which absorb most of the signal energy
  • Propagations is through ducts in F region which absorb most of the energy

An HF signal in the skip zone gets broken up by the ionospheric conditions, where only a small part of the signal energy is scattered into the skip zone. The signal that does get back to the receiving station arrives in "little bits" at slightly different angles, and so produces a weak and wavering sound.

Hint: 'skip zone' in both question and answer.

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What type of radio wave propagation allows a signal to be detected at a distance too far for ground wave propagation but too near for normal sky-wave propagation?

  • Faraday rotation
  • Correct Answer
    Scatter
  • Sporadic-E skip
  • Short-path skip

There's a distance that tends to be too far away to reach with ground propagation and too close to reach with sky-wave propagation. This area is called the skip zone.

You can reach the skip zone on occasion, though, when part of a signal scatters in the ionosphere and gets refracted at slightly different angles.

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Which of the following might be an indication that signals heard on the HF bands are being received via scatter propagation?

  • The communication is during a sunspot maximum
  • The communication is during a sudden ionospheric disturbance
  • The signal is heard on a frequency below the Maximum Usable Frequency
  • Correct Answer
    The signal is heard on a frequency above the Maximum Usable Frequency

(D). Frequencies above the Maximum Usable Frequency (MUF) normally pass through the ionosphere out into space rather than being bent back, but atmospheric scatter from the ionosphere will sometimes allow communication on these frequencies. Amateurs trying to communicate on frequencies that seem to be above the MUF may notice that they can communicate using these scattered signals. Had they been using a frequency below the MUF they may not have noticed any scattered signals. (see also discussion for question G3C06)

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Which of the following antenna types will be most effective for skip communications on 40 meters during the day?

  • Vertical antennas
  • Correct Answer
    Horizontal dipoles placed between 1/8 and 1/4 wavelength above the ground
  • Left-hand circularly polarized antennas
  • Right-hand circularly polarized antenna

(B). Low horizontal antennas, such as dipoles between 1/8 and 1/4 wavelength above the ground work best for daytime skip communications on low frequencies.

Signals from such antennas are radiated at high vertical angles that can be reflected by the ionosphere, but have a minimum amount of attenuation from the D and E layers.

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Which ionospheric layer is the most absorbent of long skip signals during daylight hours on frequencies below 10 MHz?

  • The F2 layer
  • The F1 layer
  • The E layer
  • Correct Answer
    The D layer

The daylight ionization that makes the upper ionospheric regions great for VHF sky-wave propagation works against HF frequencies below 10 MHz. During the daytime the D layer absorbs these signals. Think of the D layer as a "Daylight Dud". This layer becomes much more usable after dark, when ionization of the band decreases its "absorbent" character.

For more info see Wikipedia: D region

Hint: During Daylight D region

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What is Near Vertical Incidence Sky-wave (NVIS) propagation?

  • Propagation near the MUF
  • Correct Answer
    Short distance HF propagation using high elevation angles
  • Long path HF propagation at sunrise and sunset
  • Double hop propagation near the LUF

Near Vertical Incidence Sky-wave (NVIS) propagation as the name indicates uses signals which are sent out at very high angles, yet below the critical angle, or these signals would go right out into space! Because these signals take a shorter path through the ionospheric layers, they often have less absorption, attenuation or distortion of the signal. This method can be great for high quality short distance HF propagation using these high elevation angles, especially where there are interferences in the way of direct ground-wave propagation.

Hint: Near vertical implies high elevation angle.

For more info see Wikipedia: Near Vertical Incidence Sky-wave (NVIS)

Oversimplification: basically, instead of an antenna that radiates parallel to the ground, like a mag mount on your car or a Yagi pointed across town, you tip it over 90 degrees so you're sending RF at the sky (Yagi pointed at zenith in "Christmas Tree Mode"). These are also known as "cloud warmers."

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