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Subelement E9

ANTENNAS AND TRANSMISSION LINES

Section E9C

Practical wire antennas; folded dipoles; phased arrays; effects of ground near antennas

What type of radiation pattern is created by two 1/4-wavelength vertical antennas spaced 1/2-wavelength apart and fed 180 degrees out of phase?

  • Cardioid
  • Omni-directional
  • A figure-eight broadside to the axis of the array
  • Correct Answer
    A figure-eight oriented along the axis of the array

The most significant factors here are that the elements are fed 180 degrees out of phase and are spaced 1/2-wavelength apart. In a half-wavelength a radio frequency signal differs by 180 degrees from the source. So, you can also say that the elements are spaced 180 degrees apart. Therefore, when a signal leaving one element reaches the other it is in phase with the radiation from the element it is reaching and thus the output of each element re-enforces the output from the other.

That means the pattern is essentially two overlapping circular outputs from the two elements and strengthened in the direction away from the antenna in each direction in line with the axis through the two antenna elements. In other words: a figure-8 oriented along the axis of the array.

See also: http://www.bellscb.com/cb_radio_hobby/antennas/antarray.html, last Fig

Memory tips from other users:

  • "180 degrees" has an 8, so it's a figure eight answer. The signal is "O"ut of phase, so the pattern is "O"riented along the axis. Choose the answer with 180 and an "O" word. (See other easily confused similar question, E9C03, whose answer is a broadside figure 8.)

  • Visualize a signal leaving one of the verticals as "slow" when heading off in any direction except through the other phased vertical, but when it leaves the first vertical element and travels "through" the area immediately surrounding the second vertical on its way to its intended target, it gets a little "boost" and speeds up. The "boost" effect is 'along the axis of the array' which, in other words, means when the two antennas are aligned, one in front of the other, on a path toward the intended target.

  • "Half, Opposite, Along" - For 1/2-wavelength apart and 180 degrees out of phase (opposite), think of the figure-8 pattern stretching along the line connecting the two antennas. The word "Half" also visually resembles the figure-8 lying along the axis.

  • "Out of Phase" and "Oriented" both start with the letter "O". Two O's make an 8. So look for "8" and "Oriented"

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Tags: arrl chapter 9 arrl module 9d

What type of radiation pattern is created by two 1/4-wavelength vertical antennas spaced 1/4-wavelength apart and fed 90 degrees out of phase?

  • Correct Answer
    Cardioid
  • A figure-eight end-fire along the axis of the array
  • A figure-eight broadside to the axis of the array
  • Omni-directional

See Figure 3 at: http://www.bellscb.com/cb_radio_hobby/antennas/antarray.html

Memory Tip: The "9" in 90 degrees looks a bit like a drawing of a cardioid shape.

Mnemonic: "Quarter, Quarter, Heart" - For 1/4-wavelength apart and 90 degrees out of phase, think of a cardioid, which resembles a heart shape. "Quarter, Quarter" for both the spacing and the phase creates an easy-to-remember connection to the cardioid shape.

Silly hack: Think of an index card (for cardoid). The angle of the card is 90 degrees at all corners.

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What type of radiation pattern is created by two 1/4-wavelength vertical antennas spaced 1/2-wavelength apart and fed in phase?

  • Omni-directional
  • Cardioid
  • Correct Answer
    A figure-eight broadside to the axis of the array
  • A figure-eight end-fire along the axis of the array

There are many ways to put up antennas that are directional. One way to get directionality without a tower is to use phased vertical arrays.

In general, the phased vertical array consists of two or more quarter-wave vertical antennas. The radiation pattern that the array will have depends on how you feed the vertical antennas.

So, for example, the radiation pattern of two 1/4-wavelength vertical antennas spaced 1/2-wavelength apart and fed 180 degrees out of phase is a figure-8 oriented along the axis of the array. (E9C01) The radiation pattern of two 1/4-wavelength vertical antennas spaced 1/4-wavelength apart and fed 90 degrees out of phase is a cardioid. (E9C02) The radiation pattern of two 1/4-wavelength vertical antennas spaced 1/2-wavelength apart and fed in phase is a Figure-8 broadside to the axis of the array. (E9C03)

Source kb6nu.com - Extra Class question of the day: Wire and phased vertical antennas


Memory Tips from other users:

  • "In phase" is pretty standard, and a dipole is pretty standard. So the pattern is roughly the same as a dipole: a figure-8 broadside to the antenna.

  • "Half, Same, Broadside" - For 1/2-wavelength apart and in phase (same phase), visualize the figure-8 broadside to the axis. The word "Broadside" helps to remember that the pattern is oriented perpendicular to the line connecting the two antennas.

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What happens to the radiation pattern of an unterminated long wire antenna as the wire length is increased?

  • Fewer lobes form with the major lobes increasing closer to broadside to the wire
  • Correct Answer
    Additional lobes form with major lobes increasingly aligned with the axis of the antenna
  • The elevation angle increases, and the front-to-rear ratio decreases
  • The elevation angle increases, while the front-to-rear ratio is unaffected

The main lobe of the radiation pattern starts to follow along the direction of the wire when the length is increased past 1 to 2 wavelengths. The general rule of thumb is that the longer the wire the more constricted the main lobes.

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What is the purpose of feeding an off-center-fed dipole (OCFD) between the center and one end instead of at the midpoint?

  • Correct Answer
    To create a similar feed point impedance on multiple bands
  • To suppress off-center lobes at higher frequencies
  • To resonate the antenna across a wider range of frequencies
  • To reduce common-mode current coupling on the feed line shield

Feeding an off-center-fed dipole (OCFD) between the center and one end, instead of at the midpoint, helps achieve a similar feed point impedance across multiple bands. This is because the off-center feed point causes the antenna to resonate at different frequencies in a way that presents a consistent impedance at those frequencies, making it effective for multi-band use.

In many cases you might need to use an antenna tuner to get the SWR where you want it with this type of antenna, but the consistent impedance makes it easier / possible for the tuner to match to the antenna.

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What is the effect of adding a terminating resistor to a rhombic or long-wire antenna?

  • It reflects the standing waves on the antenna elements back to the transmitter
  • Correct Answer
    It changes the radiation pattern from bidirectional to unidirectional
  • It changes the radiation pattern from horizontal to vertical polarization
  • It decreases the ground loss

Normally, a rhombic antenna is bi-directional along the longer axis; adding a terminating resistor, usually in the 600 ohm range, at the vertex opposite to the feedpoint makes the rhombic unidirectional in the direction from feedpoint to resistor.

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What is the approximate feed point impedance at the center of a two-wire half-wave folded dipole antenna?

  • Correct Answer
    300 ohms
  • 72 ohms
  • 50 ohms
  • 450 ohms

Think of those flat twin ribbon TV antenna wire with an impedance of 300 ohms.

The impedance of a folded dipole is 4x that of a half-wave dipole, which is 73 ohms.1

73 x 4 = 292 ohms and 300 is the closest to this.

Memory trick: the 3 looks like it it has been folded, and the 00 looks like a cross section of 2 wires.

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What is a folded dipole antenna?

  • A dipole one-quarter wavelength long
  • A center-fed dipole with the ends folded down 90 degrees at the midpoint of each side
  • Correct Answer
    A half-wave dipole with an additional parallel wire connecting its two ends
  • A dipole configured to provide forward gain

The key is to remember that this antenna is one wavelength long "folded" in to a thin loop one-half wavelength long.

For more information see wikipedia: Folded Dipole Antenna

Silly memory trick: It's folded in half.

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Which of the following describes a G5RV antenna?

  • Correct Answer
    A wire antenna center-fed through a specific length of open-wire line connected to a balun and coaxial feed line
  • A multi-band trap antenna
  • A phased array antenna consisting of multiple loops
  • A wide band dipole using shorted coaxial cable for the radiating elements and fed with a 4:1 balun

The G5RV antenna is a dipole with a symmetric resonant feeder line, which serves as impedance matcher for a 50 Ohm coax cable to the transceiver.

Reference: https://en.wikipedia.org/wiki/G5RV_antenna

Those of you who would like to know; G5RV is the call sign of the inventor of the antenna. Louis Varney. (Not the Opera dude)

More info on the legend here:
http://www.radioworks.com/Varney/G5RVmain.htm

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Which of the following describes a Zepp antenna?

  • A horizontal array capable of quickly changing the direction of maximum radiation by changing phasing lines
  • Correct Answer
    An end-fed half-wavelength dipole
  • An omni-directional antenna commonly used for satellite communications
  • A vertical array capable of quickly changing the direction of maximum radiation by changing phasing lines

Zeppelins used to have this type of antenna, a long wire connected to the transmitter in the zeppelin and hanging down. It's also called an end-fed zepp (picture the zeppelin with a wire hanging down - it has to be end-fed).

Perhaps think of the "pp" in zepp and think of two letters, "di" means two. So, that should remind you of a di-pole.

The origin is the antenna used in zeppelins, and the length of the antenna was a half-wave, hence the answer, "An end-fed dipole antenna"

Silly hack: The letter Z in "Zepp" is at the end of the alphabet

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How is the far-field elevation pattern of a vertically polarized antenna affected by being mounted over seawater versus soil?

  • Radiation at low angles decreases
  • Additional lobes appear at higher elevation angles
  • Separate elevation lobes will combine into a single lobe
  • Correct Answer
    Radiation at low angles increases

The main effect of placing a vertical antenna over an imperfect ground is that it reduces low-angle radiation. Mounting it over seawater (a very even and highly conductive surface) will increase the low-angle radiation.

Silly Hint: The LARI low angle radiation increase, I (Increase) being different the wrong answer

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Which of the following describes an extended double Zepp antenna?

  • An end-fed full-wave dipole antenna
  • A center-fed 1.5-wavelength dipole antenna
  • Correct Answer
    A center-fed 1.25-wavelength dipole antenna
  • An end-fed 2-wavelength dipole antenna

The Zepp, short for Zeppelin is any resonant antenna end-fed by ladder line.

A Double Zepp is a center-fed 1 wavelength antenna.

The double extended Zepp is a dipole type Antenna consisting of two collinear 0.64 wave length elements fed in phase. The "extension" being an extra 1/8 wavelength added to the Zepp (on each side).

This double extended version provides 3 db gain over a dipole on the band it is designed for and each side or leg is about 5/8 wavelength long.

The antenna is constructed much like an ordinary Dipole antenna but with 5/8 Wavelength Elements matched with an added Impedance Matching Section of balanced feed line.

For calculations pertaining to the construction of a Zepp Antenna see: Zepp Antenna Calculator

Memory Aid: With the question asking about double Zepp - think of two Zs. The 2 and 5 in the correct answer (1.25) are like two Zs standing back to back.

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How does the radiation pattern of a horizontally polarized antenna vary with increasing height above ground?

  • The takeoff angle of the lowest elevation lobe increases
  • Correct Answer
    The takeoff angle of the lowest elevation lobe decreases
  • The horizontal beamwidth increases
  • The horizontal beamwidth decreases

The farther the antenna is above ground, the less the ground will affect its radiation pattern. The same is true for vertical omni-directional antennas. The main lobe takeoff angle decreases with increasing height, so the answer to this question is incorrect. The lowest part of the antenna would have the highest elevation lobe.

If their ground radials are brought up they will raise the radiation pattern and main lobe, or increase the main lobe takeoff angle.

Silly hack: For all questions regarding takeoff angle, the answer is "decrease" except for the one about seawater.

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How does the radiation pattern of a horizontally-polarized antenna mounted above a long slope compare with the same antenna mounted above flat ground?

  • The main lobe takeoff angle increases in the downhill direction
  • Correct Answer
    The main lobe takeoff angle decreases in the downhill direction
  • The horizontal beamwidth decreases in the downhill direction
  • The horizontal beamwidth increases in the uphill direction

The performance of a horizontally polarized antenna mounted on the side of a hill will be different from the performance of the same antenna mounted on flat ground. Specifically, the main lobe takeoff angle decreases in the downhill direction.

Hint: Mentally draw an XY axis with the antenna at the origin. When on a hill the signal will take advantage of that height and the radiating lobe will fill/fall down the hill, decreasing in angle into -y values.

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