End Fed Half Wave Antennas Perhaps the Simplest
- Slides: 31
End Fed Half Wave Antennas Perhaps the Simplest of All Multiband Wire Antennas Hap Griffin WZ 4 O January 2019
Before We Start… Recall from previous programs and antenna/transmission line theory… In any resonant RF system with standing waves that impedance changes with distance from a source or load and repeats every half wavelength… And… A Half Wavelength away from an open (Hi Z) is an open (Hi Z), and a Quarter Wavelength away from an open (Hi Z) is a short (Lo Z).
Current, Voltage and Impedance on a Half Wavelength Dipole Impedance Voltage Current Ohm’s Law: R = E/I Impedance: Z = R ± X
Balance and Grounding in Low Impedance Antennas In a low impedance feedpoint antenna (half wave dipole fed at midpoint, or a quarter wave vertical), we are concerned with current balance…the antenna has to “work against” a stable reference (ground). In a dipole, the two sides of the antenna provide the reference for each other and the feed current is balanced between the two sides.
Balance and Grounding in Low Impedance Antennas In a low impedance feedpoint antenna (half wave dipole fed at midpoint, or a quarter wave vertical), we are concerned with current balance…the antenna has to “work against” a stable reference (ground). In a ¼ wave vertical, the reference can be the actual “ground”…
Balance and Grounding in Low Impedance Antennas In a low impedance feedpoint antenna (half wave dipole fed at midpoint, or a quarter wave vertical), we are concerned with current balance…the antenna has to “work against” a stable reference (ground). Or, a set of radials (also known as a “counterpoise). For a low impedance feedpoint where we have significant current that has to be carried, the radials are generally ¼ wavelength long to provide a low impedance at their joining point (remember, ¼ wave away from an open is a short).
Balance and Grounding in High Impedance Antennas In a high impedance feedpoint antenna, for any given power, the currents are less and having a stable reference point (ground or counterpoise) becomes less important.
The Zeppelin Antenna No “ground” is available…so a high impedance antenna (a half wavelength wire fed at the end (half wave away from an open is an open)) is used to minimize the need for a ground reference or counterpoise. A ¼ wavelength of transmission line is use to transform the Hi Z of the antenna to Lo Z for the transmitter.
A Modern Day Incarnation of the Classic Zeppelin Antenna… the familiar J-Pole Antenna!
A Modern Day Incarnation of the Counterpoise… The “Tigertail” or “Rat Tail” to enhance the performance of an HT antenna
Current, Voltage and Impedance on a Half Wavelength Dipole Impedance Voltage Current Ohm’s Law: R = E/I Impedance: Z = R ± X
Dipole Operated on 2 nd Harmonic Frequency Impedance Voltage Current Ohm’s Law: R = E/I Impedance: Z = R ± X
Dipole Operated on Fundamental and 2 nd Harmonic Frequencies Fundamental Impedance 2 nd Harmonic Impedance Feedpoint Impedance in the middle is vastly different on fundamental frequency vs 2 nd harmonic
Dipole Operated on Fundamental and 2 nd Harmonic Frequencies Fundamental Impedance 2 nd Harmonic Impedance At a point offset from the middle, the feedpoint Impedance is same on fundamental frequency and 2 nd harmonic, but is higher than at a center feedpoint.
Dipole Operated on Fundamental and 2 nd Harmonic Frequencies w/ Offset Feedpoint Fundamental Impedance Z= Approx 200 ohms 2 nd Harmonic Impedance Balun By using a 4: 1 balun at the point where the fundamental and 2 nd harmonic feedpoint impedances are the same, we have a multiband antenna
Current, Voltage and Impedance on a Dipole Impedance Voltage Current Ohm’s Law: R = E/I Impedance: Z = R ± X
Dipole Operated on 2 nd Harmonic Frequency Impedance Voltage Current Ohm’s Law: R = E/I Impedance: Z = R ± X
Dipole Operated on 3 rd Harmonic Frequency Impedance Voltage Current Ohm’s Law: R = E/I Impedance: Z = R ± X
Dipole Operated on 4 th Harmonic Frequency Impedance Voltage Current Ohm’s Law: R = E/I Impedance: Z = R ± X
Harmonic Relationship of Ham Bands 80 m – 3. 5 MHz 40 m – 7. 0 MHz 30 m - 10. 1 MHz 20 m – 14 MHz 17 m – 18. 068 MHz 15 m – 21 MHz 10 m – 28 MHz
Takes the place of the ¼ wave transmision line section of the Zepp antenna but is broadbanded.
Grounding the EFHW Antenna Config 1: No ground, use coax shield as counterpoise Works but can have RF in the shack Wire Supported by Any Convenient Means Radio Matching Unit Can be Mounted Close to Ground
Grounding the EFHW Antenna Config 2: Counterpoise wire added Works better than Config 1, may need to adjust length of counterpoise for best VSWR performance Radio Matching Unit Counterpoise
Grounding the EFHW Antenna Config 3: No ground, use coax shield as counterpoise and place RF choke near shack Works better than Config 1 Radio RF Choke Matching Unit
Grounding the EFHW Antenna Config 4: Ground at matching unit Works better than Config 2 (Counterpoise) Radio Matching Unit
Grounding the EFHW Antenna Config 5: Ground at matching unit with RF choke near matching unit Best performance in tests Radio RF Choke Matching Unit
Questions?
- Half wave rectifier meaning
- Full wave rectifier examples
- Difference between full wave and half wave rectifier
- End fed zepp antenna
- End fed antenna configuration
- End fed antenna length chart
- Endfed antenne
- 49:1 transformer
- Vhf uhf and microwave antennas
- Broadband microstrip antennas
- Eh antenna
- (“mti wireless edge” or mtiwe) and anten
- Hi z antennas
- Hi-z antennas
- European school of antennas
- Stacking yagi antennas
- N6lf radials
- Hi-q antennas
- Bencher skyhawk
- Antennas and propagation
- Nasimuddin+microstrip+antennas
- Gerard wijtsma
- Mulciber roman god
- What is a half horse half man called
- Half empty or half full
- Vertical
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- What greek monster had nine heads