Topic Index

• Balun
• Batwing
• Beamwidth
• Big Wheel
• Bobtail Curtain
• Books
• Boom Effects
• Bowtie / Fan
• Broadcast
• Bruce Array / Sterba Curtain
• Closed and Interrupted Loop
• Collinear
• Corner Reflector
• Delta Loop
• Design
• Dipole
• Dipole Curtain Array
• Discone
• Doublet
• EDZ / Zepp
• Education
• G5RV / ZS6BKW
• HB9CV / ZL Special
• HF Lower
• HF Multi Band
• HF Upper
• Half Square
• Hardware
• Helix
• Hex Beam
• Horizontal Loop
• Inverted L
• Inverted U
• Inverted V
• J-Pole
• LPDA
• Lazy H
• Lindenblad
• Links
• Loading
• Longwire
• MF
• Magazine Columns
• Matching
• Modeling
• Moxon
• NVIS
• Noise / Receive
• Off Center Fed Dipole
• PVC
• Phased Array
• Planar Reflector
• Portable
• Prismatic Polyhedron
• Quad
• Quad Loop
• Rectangle
• Reversible
• Rhombic
• SCV
• Satellite
• Small Beams
• Stacking
• Stepped Diameter
• Tales
• Transmission Line
• Traps
• Turnstile
• VHF / UHF
• VOACAP
• Vertical
• Voltage Feeding
• W8JK
• X Beam
• Yagi

Balun

• A Common-Mode Current Picture Show
• Impedance-Transformation Properties of Common 4:1 Balun Types Index
• Unwanted Currents and Their Suppression

Batwing

• FM BC Antennas Part 5: The Batwing Antenna and Array
• Notes on the Batwing Part 1: Basic Batwing Properties
• Notes on the Batwing Part 2: Uni-Directional and Omni-Directional Batwings
• Notes on the Batwing Part 3: Modeling Issues with the Batwings

Beamwidth

• How Accurately Must We Aim a Beam?
• Rotator Direction Controllers

Big Wheel

• AO 16a: Horizontally Polarized Omni-Directional Antennas: Some Larger Choices
• Reinventing the (Big) Wheel

Bobtail Curtain

• AO 09: A Broadside of Vertical Wires
• Half-Square on 2 Meters Part 3: Bobtail Curtain Parasitic Beams
• SCVs Part 1: The Group Picture
• SCVs Part 5: Shorties, Double-Wides, and Twins
• The 40-Meter Bobtail Curtain as An All-Band Wire Antenna
• Triangulating Bobtail Curtains

Books

• Antenna Books
• Electronics Books
• Periodicals
• Some Antenna Books by L. B. Cebik, W4RNL

Boom Effects

• Boom Effects with Short 3-Element 146-MHz Yagis

Bowtie / Fan

• De-Mystifying the Modern Dipole Curtain Array
• Modeling and Understanding Small Beams Part 6: Fans, Bowties

Broadcast

• 1 MHz Ground-Wave Analysis: Comparison Among MININEC and NEC Modeling Implementations
• AO 11: From Two to One
• Counterpoise? On the Use and Abuse of a Word
• De-Mystifying the Modern Dipole Curtain Array
• FM BC Antennas Part 1: A Few Basics
• FM BC Antennas Part 2: A Few Possible Yagi Beam Designs
• FM BC Antennas Part 3: Some Ideas for Home-Built Beam Antennas
• FM BC Antennas Part 4: Some LPDA Options
• FM BC Antennas Part 5: The Batwing Antenna and Array
• LPDAs for the 400-800-MHz Television Range Part 1: An Ideal But Impractical Antenna
• LPDAs for the 400-800-MHz Television Range Part 2: A Practical Antenna

Bruce Array / Sterba Curtain

• AO 09: A Broadside of Vertical Wires
• AO 10: Horizontal Bi-Directional Wires
• SCVs Part 6: The Bruce Array: An Update

Closed and Interrupted Loop

• AO 16: Horizontally Polarized Omni-Directional Antennas: Some Compact Choices
• Closed and Interrupted Loop Antennas for 40 Meters
• Half-Wavelength Interrupted Loops: Their Evolution and Uses
• The IL-ZX Antenna for 40 Meters
• The IL-ZX as an 80-Meter Vertical

Collinear

• AO 10: Horizontal Bi-Directional Wires
• Is COCO (Coaxial-Collinear) Your Cup of Tea?
• The Case of the Curly Collinear

Corner Reflector

• Corner Arrays for Personal Communications
• Corner Reflectors Revisited Again Part 1: A Systematic Look at Planar Reflector Sides
• Corner Reflectors Revisited Again Part 2: A Non-Systematic Look at Some Corner Variations
• Corner Reflectors Revisited Again Part 3: Rod-Based Corner Reflectors
• Corner Reflectors Revisited Again Part 4: Variations on Standard Corner Reflectors
• Corner Reflectors Revisited Again Part 5: The Very-Wide-Band Corner Reflector
• Corner Reflectors Revisited Part 1: A Comparison With a Good Yagi
• Corner Reflectors Revisited Part 2: The Evolution of a Model
• Corner Reflectors Revisited Part 3: Optimizing the Model
• Planar and Corner Reflectors Revisited
• The 3-D Corner Reflector
• The Flat-Plane Reflector for 432 MHz
• The Prismatic Polyhedron Part 3: Corner Reflector

Delta Loop

• AO 09: A Broadside of Vertical Wires
• All-Band Use of Vertical-Plane Deltas
• Cutting Formulas
• Lower HF Wire Beams
• Multiband Use of VOHPLs
• SCVs Part 1: The Group Picture
• SCVs Part 2: The Delta Branch
• SCVs Part 5: Shorties, Double-Wides, and Twins
• Symposium 1997 Dayton: Wi're We Using Wire?
• Symposium 2000 Dayton: Do the VOMBA!
• Vertically Oriented, Vertically Polarized 1 wl Loops
• Vertically-Oriented, Horizontally Polarized 1 wl Loops
• Voltage Feeding SCV Loops

Design

• Antenna Design
• Cutting Formulas

Dipole

• 17-15-12 and Simple
• 3 Wires = The Whole World
• 6-Meter B-Antennas: A Dipole and a 2-Element Beam
• 80-Meter Dipoles and Inverted-Vs A Graphical Scrapbook
• A 102' Center-Fed Multi-Band Dipole Data Compendium
• A 135' Center-Fed Multi-band Dipole Data Compendium
• A Collection of Quadrant Antenna Patterns
• A Potpourri of Bent Dipoles
• A Triangle for the Short Vertical Operator
• A Vertical Doublet for 30-10 Meters
• AO 07: Wire and the HF Horizon: the Ys and Wherefores
• AO 09: A Broadside of Vertical Wires
• AO 10: Horizontal Bi-Directional Wires
• AO 12: Narrowband NVIS Antennas
• AO 16a: Horizontally Polarized Omni-Directional Antennas: Some Larger Choices
• AO 18: Reflections on Reflectors
• Adjusting Near-Perfect Broadband Antennas for 80-75 Meters
• Antenna Design
• Controlled Current Distribution (CCD) Antenna
• Counterpoises, Capacity Hats, and A Standard for Suspected of Feedline Radiation
• Cutting Formulas
• De-Mystifying the Modern Dipole Curtain Array
• FM BC Antennas Part 1: A Few Basics
• Half-Length Dipoles (for 40 Meters)
• Horizontal vs. Vertical Antennas on the Low HF Bands
• How High is My Antenna?
• Linear Resonator Notes Part 1: 20 and 15 Meters
• Linear Resonator Notes Part 2: 20-10 and 15-10 Meters
• Linear Resonator Notes Part 3: Wire Linear-Resonator Dipoles
• Making a Dipole Fit the Space Available
• Modeling Biconical Antennas
• Modeling and Understanding Small Beams Part 6: Fans, Bowties
• Modeling the T2FD
• Multiband Use of VOHPLs
• NVIS Horizontal Heights and Sound Bites
• Notes on Antenna Bandwidth
• Notes on Hatted Vertical Dipoles for 10 Meters
• Notes on NVIS Antennas
• Notes on Ribbons, Cages, Parasites, and Lines, Broadband Coverage of the 80-75-Meter Band with AWG #12 Copper Wire
• Reinventing the (Big) Wheel
• Symposium 1997 Dayton: Wi're We Using Wire?
• Symposium 1999 Dayton: Verticals without Vertigo
• Symposium 2000 Dayton: Do the VOMBA!
• Symposium 2003 Dayton: Some Principles of Portable Antennas to Strive For
• Symposium 2004 Dayton: My Top Five Backyard Multi-Band Wire HF Antennas
• Symposium 2007 Dayton: Back to Basics An Antenna Primer for New QRP Operators
• Terminated Wide-Band "Folded Dipole"
• The 40-Meter 3-Way Special
• The B-Antenna
• The Dual-Element Wideband Dipole: Some Preliminary Notes
• The Resonant Half-Wavelength Center-Fed Antenna
• The Terminated Wide-Band Folded Dipole Antenna
• The Zig-Zag Dipole-Doublet
• To Trap or Not to Trap
• Unfolding the Story of the Folded Dipole
• Vertically Oriented, Vertically Polarized 1 wl Loops
• Vertically Radiating Horizontal Antennas
• Vertically-Oriented, Horizontally Polarized 1 wl Loops
• Wide-Band Multi-Wire "Folded Dipoles" Part 1: Some Idealized Illusions
• Wide-Band Multi-Wire "Folded Dipoles" Part 2: Some More Real Potentials
• Wire Size and Material
• Yagi Driver Assemblies: Linear, Folded Dipole, and Quagi
• Your First 160-Meter Antenna

Dipole Curtain Array

• AO 11: From Two to One
• AO 18: Reflections on Reflectors
• De-Mystifying the Modern Dipole Curtain Array

Discone

• Notes on HF Discone Antennas

Doublet

• 10 Frequency Asked Questions about the All-Band Doublet
• 17-15-12 and Simple
• A 102' Center-Fed Multi-Band Dipole Data Compendium
• A 135' Center-Fed Multi-band Dipole Data Compendium
• A Nearly All-Band Vertical Doublet
• A Vertical Doublet for 30-10 Meters
• AO 10: Horizontal Bi-Directional Wires
• AO 13: NVIS Antennas for Special Needs
• Back-Up Antenna for 80-20 Meters
• Feeding the EDZ
• How High is My Antenna?
• Introducing the "All-Band" Doublet
• Multi-Band Inverted-V
• Notes on NVIS Antennas
• Notes on Triangles of Doublets
• Resurrecting the Y-Doublet
• Some Notes on EDZ Beams
• Suppose I Could Have Only One Wire Antenna. . .
• Symposium 2000 Dayton: Do the VOMBA!
• Symposium 2004 Dayton: My Top Five Backyard Multi-Band Wire HF Antennas
• Symposium 2007 Dayton: Back to Basics An Antenna Primer for New QRP Operators
• The 44' Doublet as a 40-10 Meter
• The Zig-Zag Dipole-Doublet
• Unfolding the Story of the Folded Dipole

EDZ / Zepp

• 2-Meter Phased Yagis, EDZ Beams, and Landstorfer Yagis
• A 135' End-Fed Multi-band Dipole Data Compendium
• AO 10: Horizontal Bi-Directional Wires
• AO 11: From Two to One
• Feeding the EDZ
• Modeling and Understanding Small Beams Part 3: The EDZ Family of Antennas
• Symposium 1997 Dayton: Wi're We Using Wire?
• Symposium 2000 Dayton: Do the VOMBA!
• The 44' Doublet as a 40-10 Meter

Education

• A Short Tale About the Family, the Fox, and the Moxon
• Amateur Radio Continuing Education Index
• Antenna Modeling Programs as Teaching Tools
• Continuing Ham Education
• Introducing the "All-Band" Doublet
• Principles of Effective Station Design
• QRP: A Newcomer's and Old-Timer's Challenge
• Teaching R.M.S. Values of AC Voltage and Current
• The Blackboard Jumble
• The Internet as a Teaching Tool
• Youth Teachers and Tutors

G5RV / ZS6BKW

• Symposium 2007 Dayton: Back to Basics An Antenna Primer for New QRP Operators
• The G5RV Antenna System Re-Visited Part 1: The G5RV on 20 meters
• The G5RV Antenna System Re-Visited Part 2: The G5RV on all HF Bands
• The G5RV Antenna System Re-Visited Part 3: The Almost-No-ATU ZS6BKW

HB9CV / ZL Special

• HB9CV Phased Array
• Modeling and Understanding Small Beams Part 5: The ZL Special
• Nulling an Unwanted Station: Worse and Better Solutions
• Symposium 2002 Dayton: Mastering Some Mysteries of 2-Element Beams Part 2
• Two-Element Horizontal Phased Arrays Part 3

HF Lower

• 2-Element Quads as a Function of Wire Diameter Part 1
• 2-Element Quads as a Function of Wire Diameter Part 2
• 2-Element Quads as a Function of Wire Diameter Part 3
• 3 Wires = The Whole World
• 3/8 Wavelength Inverted-L Multi-Band Antenna Data Compendium
• 40-Meter Wide-Band 3-Element Quad Designs
• 40-Meter Wire Moxon Rectangles
• 80-Meter Dipoles and Inverted-Vs A Graphical Scrapbook
• 80-Meter Wire LPDAs
• A 102' Center-Fed Multi-Band Dipole Data Compendium
• A 135' Center-Fed Multi-band Dipole Data Compendium
• A 3-Element Wire Yagi Design for 10.1373 MHz
• A Collection of Quadrant Antenna Patterns
• A Potpourri of Bent Dipoles
• A Short Look at Wire Beams
• A Triangle for the Short Vertical Operator
• AO 08: How Wide is Wide?
• AO 09: A Broadside of Vertical Wires
• AO 11: From Two to One
• AO 12: Narrowband NVIS Antennas
• AO 13: NVIS Antennas for Special Needs
• AO 14: Reversible Wire Beams for Lower HF Use
• Adjusting Near-Perfect Broadband Antennas for 80-75 Meters
• An 80-Meter LPMA Part 1. Designing the LPMA With a MININEC Ground
• An 80-Meter LPMA Part 2. The Adequacy of the LPMA Design
• An 80/40 Quad Design
• Automating the Design of 3-Element Monoband Quad Beams Part 2
• Closed and Interrupted Loop Antennas for 40 Meters
• De-Mystifying the Modern Dipole Curtain Array
• Full and Shrunken 40-Meter Quads
• HF Vertically-Oriented Moxon Rectangles
• Half-Length 80-Meter Vertical Monopoles Index
• Half-Length 80-Meter Vertical Monopoles Part 1: Goals, and Methods of the Study
• Half-Length 80-Meter Vertical Monopoles Part 2: Baseline Data: Full-Size and Capacity-Hat Verticals
• Half-Length 80-Meter Vertical Monopoles Part 3: Base-Loading: Lumped-Constant and Linear Loading
• Half-Length 80-Meter Vertical Monopoles Part 4: Top (Element-Extension) Loading: Linear, Zig-Zag, and Helical Loading
• Half-Length 80-Meter Vertical Monopoles Part 5: Summary Comparisons and Conclusions
• Half-Length 80-Meter Vertical Monopoles Part 6: Descriptions of Models Reported
• Half-Length Dipoles (for 40 Meters)
• Half-Wavelength Interrupted Loops: Their Evolution and Uses
• Horizontal vs. Vertical Antennas on the Low HF Bands
• Lobe Formation With Height Increases in Horizontal Antennas
• Lower HF Wire Beams
• Modeling Perspective on Ground Planes Index
• Modeling Perspective on Ground Planes Part 1: Some Preliminary Notes on the Ground
• Modeling Perspective on Ground Planes Part 2: "Capacity" Hats
• Modeling Perspective on Ground Planes Part 3: Planes in Space
• Modeling Perspective on Ground Planes Part 4: Down to Earth Verticals
• Modeling Perspective on Ground Planes Part 5: Regional Differences
• Models with Buried Radials: A Small Compendium
• Moxon Rectangles for 30m and 40m
• NEC-2 and NEC-4: Reading Trends with Caution 7 MHz Vertical + Ground Plane
• Noise, Antennas, and Receiving Systems
• Notes on Antenna Bandwidth
• Notes on NVIS Antennas
• Notes on Reversible Yagi Arrays
• Notes on Ribbons, Cages, Parasites, and Lines, Broadband Coverage of the 80-75-Meter Band with AWG #12 Copper Wire
• Notes on the Modified Half-Loop
• SCVs Part 1: The Group Picture
• SCVs Part 2: The Delta Branch
• SCVs Part 3: The Rectangular Division
• SCVs Part 4: The Open-Ended Cousins
• SCVs Part 5: Shorties, Double-Wides, and Twins
• SCVs Part 6: The Bruce Array: An Update
• Screening 40-Meter Vertical Arrays
• Short Beams and Operating Bandwidth
• Short Folded Monopoles Basic Properties
• Short Folded Monopoles Extended Applications
• Substituting Wire Elements in Lower HF Arrays
• Symposium 1999 Dayton: Verticals without Vertigo
• Symposium 2003 Dayton: Some Principles of Portable Antennas to Strive For
• The 40-Meter 3-Way Special
• The 5/8-Wavelength Mystique Part 1: 80-Meter Monopoles With Buried Radials
• The Dual-Element Wideband Dipole: Some Preliminary Notes
• The IL-ZX Antenna for 40 Meters
• The IL-ZX as an 80-Meter Vertical
• The Insulated Radial Question
• The Pseudo-Brewster Angle Revisited
• The Slippery Sloper Argument
• Triangulating Bobtail Curtains
• Unfolding the Story of the Folded Dipole
• Using Moxon Rectangles for WARC-Band Antennas Part 2
• Vertical Dipoles and Ground Planes What Antenna Modeling Reports
• Vertically Oriented, Vertically Polarized 1 wl Loops
• Vertically Radiating Horizontal Antennas
• Vertically-Oriented, Horizontally Polarized 1 wl Loops
• Voltage Feeding SCV Loops
• What Is a Folded Monopole? Skirting the Issue
• Where Do I Hang My Hat?
• Wide-Band 40-Meter Yagis Part 1: Standard and Non-Standard Designs
• Wide-Band 40-Meter Yagis Part 2: Alternative 4-Element Designs
• Wide-Band 40-Meter Yagis Part 3: A 3-Element Wire Design
• Wide-band 50/75-Ohm Feed System
• Wire Beam for 80 and 75 Meters
• Wire Moxon Rectangles for 40-10 Meters
• Wire Size and Material

HF Multi Band

• 10 Frequency Asked Questions about the All-Band Doublet
• 3/8 Wavelength Inverted-L Multi-Band Antenna Data Compendium
• 4-30 MHz LPDA Design Concepts
• A 1/2 Wavelength Inverted-L Multi-Band Antenna Data Compendium
• A 135' End-Fed Multi-band Dipole Data Compendium
• A 135' Off-Center-Fed Multi-Band Dipole Data Compendium
• A 3.5 Octave LPDA of High Potential Performance Part 1: No One Will Build
• A 3.5 Octave LPDA of High Potential Performance Part 2: Performance Graphics
• A 40-Meter Star
• A Collection of Inverted-Vee Patterns
• A Horizontal 80-Meter Multi-Band Loop Data Compendium
• A Nearly All-Band Vertical Doublet
• A Vertical Doublet for 30-10 Meters
• All-Band Use of Horizontal-Plane Loops
• All-Band Use of Vertical-Plane Deltas
• An Almost Universal HF Back-Up Antenna
• Back-Up Antenna for 80-20 Meters
• Curtains for the Extended Lazy-H
• Differentiating Among Many Types of Grounds
• Feeding the EDZ
• Fundamentals of Off-Center-Fed Dipoles
• Harmonic Operation of OCFs
• Horizontal Wire Loops How Big? How High? What Shape?
• How Much Coaxial Cable? A Case Study
• LPCAD Designs and NEC Models of LPDAs
• Long-Wire Antennas Part 1: Center-Fed and End-Fed Unterminated Long-Wire Antennas
• Long-Wire Antennas Part 2: Terminated End-Fed Long-Wire Directional Antennas
• Long-Wire Antennas Part 3: V Arrays and Beams
• Long-Wire Antennas Part 4: Rhombic Arrays and Beams
• Long-Wire Antennas Part 5: Multi-Band, Multi-Wire, and Multi-Element Rhombics
• Modeling the T2FD
• Multi-Band Inverted-V
• Multiband Use of VOHPLs
• NVIS and ALE: Some Preliminary Studies
• Notes of Mr. Windom's "Ethereal Adornments"
• Notes on Triangles of Doublets
• Notes on the Extended Aperture Log-Periodic Array
• Resurrecting the Y-Doublet
• Sorting Out Bi-Directional Phased Arrays
• Standard Design HF LPDAs (for 3-30 MHz) Design and Modeling Data
• Suppose I Could Have Only One Wire Antenna. . .
• Symposium 1997 Dayton: Wi're We Using Wire?
• Symposium 1999 Atlanticon: HO-HO-HOHPLS
• Symposium 2000 Dayton: Do the VOMBA!
• Symposium 2004 Dayton: My Top Five Backyard Multi-Band Wire HF Antennas
• Symposium 2005 Dayton: Straightening Out the Inverted-L
• Terminated Wide-Band "Folded Dipole"
• The 40-Meter Bobtail Curtain as An All-Band Wire Antenna
• The 44' Doublet as a 40-10 Meter
• The All-Band Center-Fed Inverted-L
• The Dual Expanded Lazy-H for 80-10 Meters
• The Expanded Lazy-H
• The G5RV Antenna System Re-Visited Part 1: The G5RV on 20 meters
• The G5RV Antenna System Re-Visited Part 2: The G5RV on all HF Bands
• The G5RV Antenna System Re-Visited Part 3: The Almost-No-ATU ZS6BKW
• The Isolated Off-Center-Fed Antenna (2 Parts)
• The Terminated (Very) Longwire Antenna
• The Terminated Wide-Band Folded Dipole Antenna
• The Zig-Zag Dipole-Doublet
• To Trap or Not to Trap
• Wide-Band Multi-Wire "Folded Dipoles" Part 1: Some Idealized Illusions
• Wide-Band Multi-Wire "Folded Dipoles" Part 2: Some More Real Potentials

HF Upper

• 1-2-3: 1 Boom, 2 Bands, 3 Elements Each
• 12/17-Meter Trap Quad
• 17-15-12 and Simple
• 2-Element Moxon Rectangle 10m
• 2-Element Quads as a Function of Wire Diameter Part 1
• 2-Element Quads as a Function of Wire Diameter Part 2
• 2-Element Quads as a Function of Wire Diameter Part 3
• 2-Element Yagis: How Short Can We Go?
• 3 More 14-30 MHz LPDA Designs
• 3-Band, 2-Element Spider-Supported Quad Beam
• 4-Element Monoband Quad Design
• A 10-Meter LPDA Index
• A 10-Meter LPDA Phase 1: From Calcuations to Models
• A 10-Meter LPDA Phase 2: A Low Impedance Version
• A 10-Meter LPDA Phase 3: Element Length and Diameter
• A 10-Meter LPDA Phase 4: 3 vs. 4 Elements in an LPDA for 10 Meters
• A 10-Meter LPDA Phase 5: Preconstruction Decisions
• A 10-Meter LPDA Phase 6: A Yagi Standard and Alternative
• A 10-Meter LPDA Phase 7: Wide-Band Yagis: Element Diameter Questions
• A 102' Center-Fed Multi-Band Dipole Data Compendium
• A 135' Center-Fed Multi-band Dipole Data Compendium
• A 3-Band, 3-Element Quad?
• A Short Look at Wire Beams
• A Tale of 4 Beams: The X, the Hex, the Square, and the Rect
• A Trap 2-Band 2-Element Beam for 17 and 12 Meters
• A Truly Portable Moxon Rectangle for Nearly No-Tool Field Assembly
• AO 07: Wire and the HF Horizon: the Ys and Wherefores
• AO 08: How Wide is Wide?
• AO 10: Horizontal Bi-Directional Wires
• Automating the Design of 3-Element Monoband Quad Beams Part 1
• Automating the Design of 3-Element Monoband Quad Beams Part 2
• Build Your Own LPDA 1. 11.5 Models To Start You Off
• Build Your Own LPDA 2. 5 Strategies for Doctoring the Basic Design
• Build Your Own LPDA 3. Wire and Vee-Element LPDAs: The Telerana
• Build a 3-Element Yagi Index
• Build a 3-Element Yagi Part 1: How Big Shall I Make It?
• Build a 3-Element Yagi Part 2: How Wide-Band Shall I Make It?
• Build a 3-Element Yagi Part 3: What Real Dimensions Shall I Use?
• Build a 3-Element Yagi Part 4: How Shall I Feed the Antenna?
• Common-Feed Quads Part 1
• Common-Feed Quads Part 2
• Common-Feed Quads Part 3
• De-Mystifying the Modern Dipole Curtain Array
• Design of a 2-3-Element Full-Performance Yagi for Portable and Field Use (3 Parts)
• Designing Multi-Band Parasitic Beams (6 Parts)
• Director/Driven Element 2-Element Yagis for 12 and 17 Meters
• Dream Beams Index
• Forming Reasonable Expectations of Modern Tri-Band Beam Designs
• HB9CV Phased Array
• HF General Coverage LPDAs Using 30-35' Booms
• Half-Wavelength Interrupted Loops: Their Evolution and Uses
• High-Gain, Wide-Band Yagis for 10, 6, and 2 Meters
• Horizontal Phased Arrays with Parasitic Directors
• How High is My Antenna?
• LPDA Design and Modeling Data
• Linear Resonator Notes Part 1: 20 and 15 Meters
• Linear Resonator Notes Part 2: 20-10 and 15-10 Meters
• Linear Resonator Notes Part 3: Wire Linear-Resonator Dipoles
• Lobe Formation With Height Increases in Horizontal Antennas
• Long-Boom General Coverage LPDA
• Long-Boom LPDAs for 14-30 MHz
• M3KXZ 2-Element Vertical Phased Array
• Modeling 6 Long-Boom Yagis
• Modeling Yagis by Equation Part 1. Background and One Example
• Modeling Yagis by Equation Part 2. High-Gain and Wide-Band Yagis
• Modeling and Understanding Small Beams Part 1: The X-Beam
• Modeling and Understanding Small Beams Part 2: VK2ABQ Squares and The Modified Moxon Rectangle
• Modeling and Understanding Small Beams Part 3: The EDZ Family of Antennas
• Modeling and Understanding Small Beams Part 4: Linear-Loaded Yagis
• Modeling and Understanding Small Beams Part 5: The ZL Special
• Modeling and Understanding Small Beams Part 6: Fans, Bowties
• Modeling and Understanding Small Beams Part 7: Shrunken Quads
• Modeling and Understanding Small Beams Part 8: Capacity Hats
• Monxon Yagi Rectangle for 10m 15m 20m
• Moxon-Modifying the C3-Type Tri-bander
• Multi-Banding the Moxon Rectangle
• NEC-2 Models of LPDAs Some Special Considerations
• Notes on Antenna Bandwidth
• Notes on Designing Large 5-Band Quads
• Notes on HF Discone Antennas
• Notes on Hatted Vertical Dipoles for 10 Meters
• Notes on LPDA Stubs
• Quad Models Index
• Quad Models Part 1 Full-Size 2-Element Quads
• Quad Models Part 2 Variations and Comparisons
• Quad Models Part 3 Shrunken 2-Element Quads
• Quad Models Part 4 Multi-Band 2-Element Quad Beams
• Quad Models Part 4a Alternative Common Feeds for Multi-Band 2-Element Quad Beams
• Quad Models Part 4b Stacking 2-Element, 5-Band Quads
• Quad Models Part 5 Monoband Quads of More Than 2 Elements
• Quad Models Part 5a Further Notes on 3-Element Quads
• Quad Models Part 6 Larger Multi-Band Quads
• Quad Models Part 7 Feeding Multi-Band Quads
• Some Aspects of Long-Boom, Monoband Log-Cell Yagi Design
• Some Notes on EDZ Beams
• Some Notes on Long-Boom Quads
• Stacked Beams
• Stacking Moxon Rectangles Part 2
• Stacking Yagis (3 Articles)
• Stacking: What Difference Does Difference Make?
• Stepped-Diameter Moxon Rectangles for 20 through 10 Meters
• Supplementary Notes on Stacking
• Symposium 1996 Dayton: Overview of Small Loaded Yagis
• Symposium 2001 Dayton: Mastering Some Mysteries of 2-Element Beams Part 1
• Symposium 2002 Dayton: Mastering Some Mysteries of 2-Element Beams Part 2
• Symposium 2003 Dayton: Some Principles of Portable Antennas to Strive For
• Symposium 2006 Dayton: Welcome to Yagi-World
• The "Lazy-8JK"
• The "Quad vs. Yagi" Question
• The 5/8-Wavelength Mystique Part 3: Upper HF Monopoles and a "Poorly Grounded" Speculation
• The B-Antenna
• The Birdcage Antenna
• The Double-D Antenna
• The Dual-Element Wideband Dipole: Some Preliminary Notes
• The Elusive Moxon Nest
• The G4ZU Bird Yagi
• The Inverted-U Yagi on 20 Meters
• The Inverted-U as a Field Yagi
• The L-Antenna
• The Monoband Log-Cell Yagi Revisited Index
• The Monoband Log-Cell Yagi Revisited Part 1: An Introduction to the Log-Cell Yagi
• The Monoband Log-Cell Yagi Revisited Part 2: Element Phasing and Log-Cell Design
• The Monoband Log-Cell Yagi Revisited Part 3: Some Practical Log-Cell Yagi Designs
• The Monoband Log-Cell Yagi Revisited Part 4: Vee-ing the Log-Cell Yagi Elements
• The Pseudo-Brewster Angle Revisited
• The Quest for the Elusive TBWB4EQ (The Tri-Band Wide-Band 4-Element Quad)
• The Terminated Vee-Beam and Rhombic
• The Turnstile An Omni-Directional Horizontally Polarized Antenna
• The V-Dipole LPDA
• Three Forward-Stagger 5-Band Yagis from ON4ANT
• Three Ways to Skin a Quad Loop
• Three-Element Yagi Models: Standards of Comparison
• Two-Element Horizontal Phased Arrays Index
• Two-Element Horizontal Phased Arrays Part 1
• Two-Element Horizontal Phased Arrays Part 2
• Two-Element Horizontal Phased Arrays Part 3
• Two-Element Horizontal Phased Arrays Part 4
• Unfolding the Story of the Folded Dipole
• Using Moxon Rectangles for WARC-Band Antennas Part 1
• Using Moxon Rectangles for WARC-Band Antennas Part 2
• V-Yagi Notes
• V-Yagi is it a 3-Element Moxon?
• Voltage Feeding SCV Loops
• What Can We Expect from a 2-Element Beam? Index
• What Can We Expect from a 2-Element Beam? Part 1: Method, Units of Measure, and the Dipole Standard of Reference
• What Can We Expect from a 2-Element Beam? Part 2: The Full-Size 2-Element Yagi
• What Can We Expect from a 2-Element Beam? Part 3: Shortened Dipoles and Capacity Hat Yagis
• What Can We Expect from a 2-Element Beam? Part 4: Loaded Yagis
• What Can We Expect from a 2-Element Beam? Part 5: Strategies for Improving Forward and Rearward Performance
• Wire Moxon Rectangles for 40-10 Meters
• Yagi Element Diameter

Half Square

• AO 09: A Broadside of Vertical Wires
• AO 11: From Two to One
• Half-Square on 2 Meters Part 1: A Bi-Directional Vertical Antenna
• Half-Square on 2 Meters Part 2: Half Square Parasitic Beams
• Half-Square on 2 Meters Part 3: Bobtail Curtain Parasitic Beams
• Lower HF Wire Beams
• Notes on the Modified Half-Loop
• SCVs Part 1: The Group Picture
• SCVs Part 4: The Open-Ended Cousins
• SCVs Part 5: Shorties, Double-Wides, and Twins
• Symposium 1999 Dayton: Verticals without Vertigo
• Vertically Oriented, Vertically Polarized 1 wl Loops

Hardware

• Antenna Systems
• Basic Operating Needs of the Radio Shack
• Building a QRP Field Vertical
• Home-Brew Design and Construction
• Home-Built Antenna Hardware
• The Shack Layout
• Wire Size and Material

Helix

• AO 15: Circularly Polarized Aimed Satellite Antennas
• Axial-Mode Helical Antennas Part 1: Helix Basics
• Axial-Mode Helical Antennas Part 2: 10- and 15-Turn Helical
• Axial-Mode Helical Antennas Part 3: Axial-Mode Helices

Hex Beam

• A Tale of 4 Beams: The X, the Hex, the Square, and the Rect

Horizontal Loop

• A 40-Meter Star
• A Horizontal 80-Meter Multi-Band Loop Data Compendium
• AO 12: Narrowband NVIS Antennas
• All-Band Use of Horizontal-Plane Loops
• Horizontal Wire Loops How Big? How High? What Shape?
• Notes on NVIS Antennas
• Symposium 1999 Atlanticon: HO-HO-HOHPLS
• Symposium 2004 Dayton: My Top Five Backyard Multi-Band Wire HF Antennas
• Your First 160-Meter Antenna

Inverted L

• A 1/2 Wavelength Inverted-L Multi-Band Antenna Data Compendium
• A Potpourri of Bent Dipoles
• Counterpoise? On the Use and Abuse of a Word
• Differentiating Among Many Types of Grounds
• Modeling 160-Meter Vertical Arrays Part 4: A Potpourri of 160-Meter Vertical Antennas and Modeling Issues
• Symposium 2004 Dayton: My Top Five Backyard Multi-Band Wire HF Antennas
• Symposium 2005 Dayton: Straightening Out the Inverted-L
• Symposium 2007 Dayton: Back to Basics An Antenna Primer for New QRP Operators
• The All-Band Center-Fed Inverted-L
• Your First 160-Meter Antenna

Inverted U

• The Inverted-U Yagi on 20 Meters
• The Inverted-U as a Field Yagi

Inverted V

• 80-Meter Dipoles and Inverted-Vs A Graphical Scrapbook
• A Collection of Inverted-Vee Patterns
• A Potpourri of Bent Dipoles
• AO 12: Narrowband NVIS Antennas
• AO 13: NVIS Antennas for Special Needs
• How High is My Antenna?
• Multi-Band Inverted-V
• Notes on NVIS Antennas
• Symposium 2007 Dayton: Back to Basics An Antenna Primer for New QRP Operators
• Vertically Radiating Horizontal Antennas

J-Pole

• J-Poles Part 1: Why I Finally Got Interested
• J-Poles Part 2: The Varieties of Twinlead J-Poles
• J-Poles Part 3: The Effects of Element Diameter and Match-Section
• J-Poles Part 4: Some Things We Can and Cannot Do With a J-Pole
• What is a Slim Jim?
• What is a Slim Jim? Data Appendix: Radiating and Transmission-Line Currents

LPDA

• 3 More 14-30 MHz LPDA Designs
• 4-30 MHz LPDA Design Concepts
• 80-Meter Wire LPDAs
• A 10-Meter LPDA Index
• A 10-Meter LPDA Phase 1: From Calcuations to Models
• A 10-Meter LPDA Phase 2: A Low Impedance Version
• A 10-Meter LPDA Phase 3: Element Length and Diameter
• A 10-Meter LPDA Phase 4: 3 vs. 4 Elements in an LPDA for 10 Meters
• A 10-Meter LPDA Phase 5: Preconstruction Decisions
• A 10-Meter LPDA Phase 6: A Yagi Standard and Alternative
• A 10-Meter LPDA Phase 7: Wide-Band Yagis: Element Diameter Questions
• A 100-1000 MHz "Utility" LPDA
• A 3.5 Octave LPDA of High Potential Performance Part 1: No One Will Build
• A 3.5 Octave LPDA of High Potential Performance Part 2: Performance Graphics
• An 80-Meter LPMA Part 1. Designing the LPMA With a MININEC Ground
• An 80-Meter LPMA Part 2. The Adequacy of the LPMA Design
• Build Your Own LPDA 1. 11.5 Models To Start You Off
• Build Your Own LPDA 2. 5 Strategies for Doctoring the Basic Design
• Build Your Own LPDA 3. Wire and Vee-Element LPDAs: The Telerana
• Dream Beams Index
• FM BC Antennas Part 4: Some LPDA Options
• HF General Coverage LPDAs Using 30-35' Booms
• LPCAD Designs and NEC Models of LPDAs
• LPDA Design and Modeling Data
• LPDAs for the 400-800-MHz Television Range Part 1: An Ideal But Impractical Antenna
• LPDAs for the 400-800-MHz Television Range Part 2: A Practical Antenna
• Long-Boom General Coverage LPDA
• Long-Boom LPDAs for 14-30 MHz
• NEC-2 Models of LPDAs Some Special Considerations
• Notes on 2-Band (2-M, 70-CM) LPDAs (2 Parts)
• Notes on LPDA Stubs
• Notes on the Extended Aperture Log-Periodic Array
• Some Aspects of Long-Boom, Monoband Log-Cell Yagi Design
• Split or Continuous LPDAs for Personal Communications
• Standard Design HF LPDAs (for 3-30 MHz) Design and Modeling Data
• The 64-(Euro-)Dollar Question (6m LPDA)
• The Monoband Log-Cell Yagi Revisited Index
• The Monoband Log-Cell Yagi Revisited Part 1: An Introduction to the Log-Cell Yagi
• The Monoband Log-Cell Yagi Revisited Part 2: Element Phasing and Log-Cell Design
• The Monoband Log-Cell Yagi Revisited Part 3: Some Practical Log-Cell Yagi Designs
• The Monoband Log-Cell Yagi Revisited Part 4: Vee-ing the Log-Cell Yagi Elements
• The V-Dipole LPDA

Lazy H

• AO 10: Horizontal Bi-Directional Wires
• An Almost Universal HF Back-Up Antenna
• Back-Up Antenna for 80-20 Meters
• Curtains for the Extended Lazy-H
• Sorting Out Bi-Directional Phased Arrays
• Symposium 2000 Dayton: Do the VOMBA!
• Symposium 2004 Dayton: My Top Five Backyard Multi-Band Wire HF Antennas
• The Dual Expanded Lazy-H for 80-10 Meters
• The Expanded Lazy-H

Lindenblad

• AO 16a: Horizontally Polarized Omni-Directional Antennas: Some Larger Choices
• Notes on Fixed Satellite Antennas
• The Practical Lindenblad

Links

• Antenna Sites
• Ham Links
• Manufacturers and Dealers

Loading

• 2-Element Yagis: How Short Can We Go?
• A Triangle for the Short Vertical Operator
• AO 09: A Broadside of Vertical Wires
• AO 12: Narrowband NVIS Antennas
• AO 14: Reversible Wire Beams for Lower HF Use
• Counterpoises, Capacity Hats, and A Standard for Suspected of Feedline Radiation
• Full and Shrunken 40-Meter Quads
• Half-Length 80-Meter Vertical Monopoles Index
• Half-Length 80-Meter Vertical Monopoles Part 1: Goals, and Methods of the Study
• Half-Length 80-Meter Vertical Monopoles Part 2: Baseline Data: Full-Size and Capacity-Hat Verticals
• Half-Length 80-Meter Vertical Monopoles Part 3: Base-Loading: Lumped-Constant and Linear Loading
• Half-Length 80-Meter Vertical Monopoles Part 4: Top (Element-Extension) Loading: Linear, Zig-Zag, and Helical Loading
• Half-Length 80-Meter Vertical Monopoles Part 5: Summary Comparisons and Conclusions
• Half-Length 80-Meter Vertical Monopoles Part 6: Descriptions of Models Reported
• Half-Length Dipoles (for 40 Meters)
• Linear Resonator Notes Part 1: 20 and 15 Meters
• Linear Resonator Notes Part 2: 20-10 and 15-10 Meters
• Linear Resonator Notes Part 3: Wire Linear-Resonator Dipoles
• Modeling Loads and Transmission Lines Index
• Modeling Loads and Transmission Lines Part 1: Getting Oriented: Basic Loads and Simple Antennas
• Modeling Loads and Transmission Lines Part 2: From Place to Laplace: Converting X and R to C, L, and R
• Modeling Loads and Transmission Lines Part 3: Transmission Lines as Lines
• Modeling Loads and Transmission Lines Part 4: Transmission Lines as Lumped Constants
• Modeling Perspective on Ground Planes Part 2: "Capacity" Hats
• Modeling Perspective on Ground Planes Part 3: Planes in Space
• Modeling and Understanding Small Beams Part 4: Linear-Loaded Yagis
• Modeling and Understanding Small Beams Part 8: Capacity Hats
• Notes on Hatted Vertical Dipoles for 10 Meters
• Quad Models Part 3 Shrunken 2-Element Quads
• Reactive Antenna Loads and Their NEC Models Index
• Reactive Antenna Loads and Their NEC Models Part 1: Some Center Loading Basics
• Reactive Antenna Loads and Their NEC Models Part 2: Some Mid-Element Loading Basics
• Reactive Antenna Loads and Their NEC Models Part 3: Some Linear Loading Basics
• Reactive Antenna Loads and Their NEC Models Part 4: Some Solenoid Loading Basics
• Reactive Antenna Loads and Their NEC Models Part 5: Some Unfinished Business
• Symposium 1996 Dayton: Overview of Small Loaded Yagis
• Symposium 1999 Dayton: Verticals without Vertigo
• Symposium 2003 Dayton: Some Principles of Portable Antennas to Strive For
• The 40-Meter 3-Way Special
• The Dual-Element Wideband Dipole: Some Preliminary Notes
• What Can We Expect from a 2-Element Beam? Part 3: Shortened Dipoles and Capacity Hat Yagis
• What Can We Expect from a 2-Element Beam? Part 4: Loaded Yagis
• Where Do I Hang My Hat?

Longwire

• Long-Wire Antennas Part 1: Center-Fed and End-Fed Unterminated Long-Wire Antennas
• Long-Wire Antennas Part 2: Terminated End-Fed Long-Wire Directional Antennas
• Long-Wire Antennas Part 3: V Arrays and Beams
• Long-Wire Antennas Part 4: Rhombic Arrays and Beams
• Long-Wire Antennas Part 5: Multi-Band, Multi-Wire, and Multi-Element Rhombics
• The Terminated (Very) Longwire Antenna

MF

• 1 MHz Ground-Wave Analysis: Comparison Among MININEC and NEC Modeling Implementations
• Counterpoise? On the Use and Abuse of a Word
• Modeling 160-Meter Vertical Arrays Index
• Modeling 160-Meter Vertical Arrays Part 1: Some Baseline Data
• Modeling 160-Meter Vertical Arrays Part 2: Appreciating Conductivity and Permittivity
• Modeling 160-Meter Vertical Arrays Part 3: Complex Radial Systems
• Modeling 160-Meter Vertical Arrays Part 4: A Potpourri of 160-Meter Vertical Antennas and Modeling Issues
• Modeling 160-Meter Vertical Arrays Part 5: The Use of Multiple Ground Qualities in Lieu of Radials
• Modeling Perspective on Ground Planes Index
• Modeling Perspective on Ground Planes Part 1: Some Preliminary Notes on the Ground
• Modeling Perspective on Ground Planes Part 2: "Capacity" Hats
• Modeling Perspective on Ground Planes Part 3: Planes in Space
• Modeling Perspective on Ground Planes Part 4: Down to Earth Verticals
• Modeling Perspective on Ground Planes Part 5: Regional Differences
• Models with Buried Radials: A Small Compendium
• Pursuing the (Nearly) Perfect Parasitic Vertical Array for 160 Meters Part 1
• Pursuing the (Nearly) Perfect Parasitic Vertical Array for 160 Meters Part 2
• The Insulated Radial Question
• Your First 160-Meter Antenna

Magazine Columns

• An-Ten-Ten-nas Index (64 Articles)
• Antenna Options Index (19 Articles)
• Antennas From the Ground Up Index (42 Articles)
• AntenneX Antenna Modeling Column Index (147 Articles)

Matching

• 10 Frequency Asked Questions about the All-Band Doublet
• A Junkbox L-C-L/L-C ATU
• A Little Matching
• AO 17: Beam-Matching
• ATUs, Delta, and Losses
• ATUs, Delta, and Tuner Losses
• Adjusting Near-Perfect Broadband Antennas for 80-75 Meters
• Antenna Design
• Antenna Matching
• Antenna Systems
• Building a QRP Field Vertical
• Designing Multi-Band Parasitic Beams (6 Parts)
• How to Make Your Tuner Work on Every Band
• Link-Coupled Antenna Tuners
• Link-Coupled Antenna Tuners Index
• Link-Coupled Antenna Tuners Part I: Inductive Coupling
• Link-Coupled Antenna Tuners Part II: The Input Story
• Link-Coupled Antenna Tuners Part III: The Output Story
• Link-Coupled Antenna Tuners Part IV: Series Circuits and Reactance
• Link-Coupled Antenna Tuners Part V: Components, Construction, and Measurement
• Modeling Hybrid Transmission Line Stubs
• More on ATUs, Delta, and Losses
• Notes on Ribbons, Cages, Parasites, and Lines, Broadband Coverage of the 80-75-Meter Band with AWG #12 Copper Wire
• Notes on the Gamma Match
• Notes on the Gamma Match MININEC Models
• SWR, Feedlines, and Reactance Part 1. Dipole Samples
• SWR, Feedlines, and Reactance Part 2. Some Interesting Antennas and Matching Systems
• Series Matching: A Review
• Series and Parallel Coaxial Cable Assemblies
• Some (Old) Notes on Home-Brew Parallel Transmission Lines
• Some Facts and Fantasies About Standing Wave Ratios
• Symposium 1998 Dayton: 12 Ways to See and Love Your Feeders
• Symposium 2001 Dayton: Mastering Some Mysteries of 2-Element Beams Part 1
• The 75-Ohm 1/4 Wavelength Matching Section
• The Balanced-L Network
• The Beta Match: 2 Views
• The Matching Question Redux
• Transmission-Line and Tuner Calculation Aids
• Values Along a Transmission Line
• When is a Quarter Wave Not a Quarter Wave?
• Where to Place Your Impedance Matching Efforts
• Wide-band 50/75-Ohm Feed System

Modeling

• A GAP in Our Understanding of Feedpoints
• AO 04: Antenna Modeling Software: Part 1
• AO 05: Antenna Modeling Software: Part 2
• Antenna Modeling Aids
• Antenna Modeling Programs
• Antenna Modeling Programs as Teaching Tools
• AntenneX Antenna Modeling Column Index (147 Articles)
• Azimuth, Elevation, and Antenna Modeling
• Calibrating K to NEC
• Close-Spaced Wires
• Getting the Most Out of Antenna Patterns
• Model Planning Form
• Modeling Antenna Elements
• Modeling Loads and Transmission Lines Index
• Modeling Loads and Transmission Lines Part 1: Getting Oriented: Basic Loads and Simple Antennas
• Modeling Loads and Transmission Lines Part 2: From Place to Laplace: Converting X and R to C, L, and R
• Modeling Loads and Transmission Lines Part 3: Transmission Lines as Lines
• Modeling Loads and Transmission Lines Part 4: Transmission Lines as Lumped Constants
• Modeling Trap Antennas
• Modeling and Convergence Testing
• Models for Antenna Modelers: 2nd Edition
• Models with Buried Radials: A Small Compendium
• Multi-Diameter Dipoles: MININEC vs. NEC-4
• NEC and Reciprocity
• NEC-2 Models of LPDAs Some Special Considerations
• NEC-2 and NEC-4: Reading Trends with Caution 7 MHz Vertical + Ground Plane
• NEC-4 vs. NEC-2 Stepped-Diameter Correction and Auto-Segmentation
• Notes on Dipole Convergence
• Reactive Antenna Loads and Their NEC Models Index
• Reactive Antenna Loads and Their NEC Models Part 1: Some Center Loading Basics
• Reactive Antenna Loads and Their NEC Models Part 2: Some Mid-Element Loading Basics
• Reactive Antenna Loads and Their NEC Models Part 3: Some Linear Loading Basics
• Reactive Antenna Loads and Their NEC Models Part 4: Some Solenoid Loading Basics
• Reactive Antenna Loads and Their NEC Models Part 5: Some Unfinished Business
• Reading a NEC Deck
• Some Antenna Books by L. B. Cebik, W4RNL
• Some Pitfalls of Careless dBd-ing
• Systematic Trap Modeling
• The Insulated Radial Question
• The Tee-Match
• Trap Placement Part 1
• Trap Placement Part 2
• Two Limitations of NEC-4
• VOACAP Type 13 File Patterns
• VOACAP Type 13 Files
• Why I use dBi - Mostly

Moxon

• 2-Element Moxon Rectangle 10m
• 40-Meter Wire Moxon Rectangles
• A 3-Moxon Polling Array for 914 MHz
• A Short Look at Wire Beams
• A Short Tale About the Family, the Fox, and the Moxon
• A Tale of 4 Beams: The X, the Hex, the Square, and the Rect
• A Truly Portable Moxon Rectangle for Nearly No-Tool Field Assembly
• AO 06: Do I Need More Gain?
• AO 13: NVIS Antennas for Special Needs
• AO 14: Reversible Wire Beams for Lower HF Use
• Antenna Design
• Building a 2-Meter Moxon
• CAP Emergency-Beacon Direction-Finding Antennas
• Designing Moxon Rectangles by Equation and by Model
• Designing Multi-Band Parasitic Beams (6 Parts)
• HF Vertically-Oriented Moxon Rectangles
• Horizontal Polling Arrays
• Improved Antenna Performance for VHF FM: Some Basics, Some Options, Some Hurdles
• Interesting Alternatives to the Yagi
• Lower HF Wire Beams
• Modeling and Understanding Small Beams Part 2: VK2ABQ Squares and The Modified Moxon Rectangle
• Monxon Yagi Rectangle for 10m 15m 20m
• Moxon Rectangles and Online Calculator
• Moxon Rectangles for 30m and 40m
• Moxon Rectangles for 6 Meters
• Moxon-Modifying the C3-Type Tri-bander
• Multi-Banding the Moxon Rectangle
• Notes on Fixed Satellite Antennas
• Notes on NVIS Antennas
• Nulling an Unwanted Station: Worse and Better Solutions
• Simplifying the Turnstile Moxon Rectangle Fixed-Position Satellite Antennas
• Stacking Moxon Rectangles Part 1
• Stacking Moxon Rectangles Part 2
• Stepped-Diameter Moxon Rectangles for 20 through 10 Meters
• Symposium 2002 Dayton: Mastering Some Mysteries of 2-Element Beams Part 2
• The Double-D Antenna
• The Elusive Moxon Nest
• The Moxon Rectangle Pattern
• The Moxon Rectangle on 2 Meters
• The Moxon Rectangle: A Review
• Using Moxon Rectangles for WARC-Band Antennas Part 1
• Using Moxon Rectangles for WARC-Band Antennas Part 2
• Wire Moxon Rectangles for 40-10 Meters

NVIS

• AO 12: Narrowband NVIS Antennas
• AO 13: NVIS Antennas for Special Needs
• NVIS Horizontal Heights and Sound Bites
• NVIS and ALE: Some Preliminary Studies
• Notes on NVIS Antennas

Noise / Receive

• Noise, Antennas, and Receiving Systems

Off Center Fed Dipole

• A 135' Off-Center-Fed Multi-Band Dipole Data Compendium
• Fundamentals of Off-Center-Fed Dipoles
• Harmonic Operation of OCFs
• How Much Coaxial Cable? A Case Study
• Notes of Mr. Windom's "Ethereal Adornments"
• Symposium 1997 Dayton: Wi're We Using Wire?
• The Isolated Off-Center-Fed Antenna (2 Parts)

PVC

• A Short Tale About the Family, the Fox, and the Moxon
• FM BC Antennas Part 3: Some Ideas for Home-Built Beam Antennas
• PVC Gurneys for All Occasions
• PVC for Antenna Applications

Phased Array

• 2-Meter Phased Yagis, EDZ Beams, and Landstorfer Yagis
• AO 10: Horizontal Bi-Directional Wires
• AO 11: From Two to One
• Don't Be Phased By Phasing
• HB9CV Phased Array
• Horizontal Phased Arrays with Parasitic Directors
• Interesting Alternatives to the Yagi
• M3KXZ 2-Element Vertical Phased Array
• Modeling and Understanding Small Beams Part 5: The ZL Special
• Nulling an Unwanted Station: Worse and Better Solutions
• Sorting Out Bi-Directional Phased Arrays
• Symposium 2002 Dayton: Mastering Some Mysteries of 2-Element Beams Part 2
• The "Lazy-8JK"
• Two-Element Horizontal Phased Arrays Index
• Two-Element Horizontal Phased Arrays Part 1
• Two-Element Horizontal Phased Arrays Part 2
• Two-Element Horizontal Phased Arrays Part 3
• Two-Element Horizontal Phased Arrays Part 4

Planar Reflector

• AO 18: Reflections on Reflectors
• Curtains for the Extended Lazy-H
• Planar Reflectors Part 1: The Planar Reflector and the Dipole
• Planar Reflectors Part 2: Phased Dipoles and Rectangles
• Planar Reflectors Part 3: Bobtails and Diamonds
• Planar Reflectors Part 4: Rod or Bar Reflectors
• Planar and Corner Reflectors Revisited
• The Prismatic Polyhedron Part 1: Planar Reflector
• The Prismatic Polyhedron Part 2: Planar Reflector Supplementary Data

Portable

• A Truly Portable Moxon Rectangle for Nearly No-Tool Field Assembly
• Design of a 2-3-Element Full-Performance Yagi for Portable and Field Use (3 Parts)
• The Inverted-U as a Field Yagi

Prismatic Polyhedron

• The Prismatic Polyhedron Part 1: Planar Reflector
• The Prismatic Polyhedron Part 2: Planar Reflector Supplementary Data
• The Prismatic Polyhedron Part 3: Corner Reflector

Quad

• 12/17-Meter Trap Quad
• 2-Element Quads as a Function of Wire Diameter Part 1
• 2-Element Quads as a Function of Wire Diameter Part 2
• 2-Element Quads as a Function of Wire Diameter Part 3
• 3-Band, 2-Element Spider-Supported Quad Beam
• 4-Element Monoband Quad Design
• 40-Meter Wide-Band 3-Element Quad Designs
• A 3-Band, 3-Element Quad?
• A Little Matching
• AO 15: Circularly Polarized Aimed Satellite Antennas
• An 80/40 Quad Design
• Antenna Design
• Automating the Design of 3-Element Monoband Quad Beams Part 1
• Automating the Design of 3-Element Monoband Quad Beams Part 2
• Calculating the Length of a Resonant Square Quad Loop
• Circling the Square Quad
• Common-Feed Quads Part 1
• Common-Feed Quads Part 2
• Common-Feed Quads Part 3
• Cutting Formulas
• Dream Beams Index
• Full and Shrunken 40-Meter Quads
• How Accurately Must We Aim a Beam?
• How High is My Antenna?
• In Pursuit of Better VHF Quad Beams
• Medium-Length 2-Meter Quads and Yagis
• Modeling and Understanding Small Beams Part 7: Shrunken Quads
• Modeling the Double-Diamond for UHF
• New Quad Studies Index
• Noise, Antennas, and Receiving Systems
• Notes on Designing Large 5-Band Quads
• Notes on Fixed Satellite Antennas
• Quad Models Index
• Quad Models Part 1 Full-Size 2-Element Quads
• Quad Models Part 2 Variations and Comparisons
• Quad Models Part 3 Shrunken 2-Element Quads
• Quad Models Part 4 Multi-Band 2-Element Quad Beams
• Quad Models Part 4a Alternative Common Feeds for Multi-Band 2-Element Quad Beams
• Quad Models Part 4b Stacking 2-Element, 5-Band Quads
• Quad Models Part 5 Monoband Quads of More Than 2 Elements
• Quad Models Part 5a Further Notes on 3-Element Quads
• Quad Models Part 6 Larger Multi-Band Quads
• Quad Models Part 7 Feeding Multi-Band Quads
• Quagi and Yagi on 2 Meters
• Some Notes on Long-Boom Quads
• The "Quad vs. Yagi" Question
• The Birdcage Antenna
• The Flat-Plane Reflector for 432 MHz
• The Quad Beam as an Amateur Satellite Antenna
• The Quest for the Elusive TBWB4EQ (The Tri-Band Wide-Band 4-Element Quad)
• Three Ways to Skin a Quad Loop
• Yagi Driver Assemblies: Linear, Folded Dipole, and Quagi

Quad Loop

• A Diamond Jubilee
• AO 16: Horizontally Polarized Omni-Directional Antennas: Some Compact Choices
• Cutting Formulas
• Multiband Use of VOHPLs
• SCVs Part 1: The Group Picture
• SCVs Part 3: The Rectangular Division
• SCVs Part 5: Shorties, Double-Wides, and Twins
• Symposium 1997 Dayton: Wi're We Using Wire?
• Symposium 2000 Dayton: Do the VOMBA!
• Vertically Oriented, Vertically Polarized 1 wl Loops
• Vertically-Oriented, Horizontally Polarized 1 wl Loops

Rectangle

• AO 09: A Broadside of Vertical Wires
• Multiband Use of VOHPLs
• SCVs Part 1: The Group Picture
• SCVs Part 3: The Rectangular Division
• SCVs Part 5: Shorties, Double-Wides, and Twins
• Vertically Oriented, Vertically Polarized 1 wl Loops
• Vertically-Oriented, Horizontally Polarized 1 wl Loops

Reversible

• AO 14: Reversible Wire Beams for Lower HF Use
• HF Vertically-Oriented Moxon Rectangles
• Lower HF Wire Beams
• Modeling Hybrid Transmission Line Stubs
• Notes on Reversible Yagi Arrays
• The Quad Beam as an Amateur Satellite Antenna

Rhombic

• AO 11: From Two to One
• Long-Wire Antennas Part 4: Rhombic Arrays and Beams
• Long-Wire Antennas Part 5: Multi-Band, Multi-Wire, and Multi-Element Rhombics
• Modeling the Dual Rhomboid Part 1: The 1296 MHz Version
• Modeling the Dual Rhomboid Part 2: Will the Real Laport Please Stand Up
• Modeling the Dual Rhomboid Part 3: Some Standards of Comparison
• The Terminated Vee-Beam and Rhombic

SCV

• SCVs Index: A Family Album
• SCVs Part 1: The Group Picture
• SCVs Part 2: The Delta Branch
• SCVs Part 3: The Rectangular Division
• SCVs Part 4: The Open-Ended Cousins
• SCVs Part 5: Shorties, Double-Wides, and Twins
• SCVs Part 6: The Bruce Array: An Update
• Symposium 1999 Dayton: Verticals without Vertigo
• The 40-Meter Bobtail Curtain as An All-Band Wire Antenna
• Triangulating Bobtail Curtains
• Vertically Oriented, Vertically Polarized 1 wl Loops
• Voltage Feeding SCV Loops

Satellite

• AO 15: Circularly Polarized Aimed Satellite Antennas
• Axial-Mode Helical Antennas Part 1: Helix Basics
• Axial-Mode Helical Antennas Part 2: 10- and 15-Turn Helical
• Axial-Mode Helical Antennas Part 3: Axial-Mode Helices
• Notes on Fixed Satellite Antennas
• Simplifying the Turnstile Moxon Rectangle Fixed-Position Satellite Antennas
• Some Overlooked Antenna Basics for DX and Off-World Communications
• The Practical Lindenblad
• The Quad Beam as an Amateur Satellite Antenna

Small Beams

• Modeling and Understanding Small Beams Index
• Modeling and Understanding Small Beams Part 1: The X-Beam
• Modeling and Understanding Small Beams Part 2: VK2ABQ Squares and The Modified Moxon Rectangle
• Modeling and Understanding Small Beams Part 3: The EDZ Family of Antennas
• Modeling and Understanding Small Beams Part 4: Linear-Loaded Yagis
• Modeling and Understanding Small Beams Part 5: The ZL Special
• Modeling and Understanding Small Beams Part 6: Fans, Bowties
• Modeling and Understanding Small Beams Part 7: Shrunken Quads
• Modeling and Understanding Small Beams Part 8: Capacity Hats

Stacking

• 2-Meter Yagi Stacks Part 1: 6- to 18-Element OWA Examples
• 2-Meter Yagi Stacks Part 2: 9- to 18-Element DL6WU Examples
• 70-CM Yagi Stacks Part 1: 10- to 40-Element DL6WU Examples
• 70-CM Yagi Stacks Part 2: 10- to 40-Element VK3AUU Examples
• How High is My Antenna?
• Notes on the Batwing Part 1: Basic Batwing Properties
• Quad Models Part 4b Stacking 2-Element, 5-Band Quads
• Stacked Beams
• Stacking Moxon Rectangles Part 1
• Stacking Moxon Rectangles Part 2
• Stacking Yagis (3 Articles)
• Stacking: What Difference Does Difference Make?
• Supplementary Notes on Stacking
• What's Wrong With This Turnstile Stack?

Stepped Diameter

• Multi-Diameter Dipoles: MININEC vs. NEC-4
• NEC-4 vs. NEC-2 Stepped-Diameter Correction and Auto-Segmentation
• Symposium 2001 Dayton: Mastering Some Mysteries of 2-Element Beams Part 1
• Yagi Element Diameter

Tales

• 10-10 and Lindbergh
• 10-Minute Timer
• A Guide to Assisting Songbird Babies
• A Time to Reminisce
• Antenna Newcomers
• Caring for a Terminally Ill Loved One
• Everything Old Is New Again
• In Memory of Jean
• Lost Traditions
• PVC Gurneys for All Occasions
• Q-Signals
• RST
• Sell an Antenna
• Socio-Cybernetic Modeling
• The Serviceberry Tree
• The Wouff-Hong, the Rettysnitch, and the What?
• To the Sea Again
• Understanding and Producing Scientific and Technical Articles
• What's in a Name?
• When Shacks Were Shacks
• Why Call "CQ"?

Transmission Line

• Antenna Systems
• Handling Parallel Feedlines
• Modeling Hybrid Transmission Line Stubs
• Modeling Loads and Transmission Lines Index
• Modeling Loads and Transmission Lines Part 1: Getting Oriented: Basic Loads and Simple Antennas
• Modeling Loads and Transmission Lines Part 2: From Place to Laplace: Converting X and R to C, L, and R
• Modeling Loads and Transmission Lines Part 3: Transmission Lines as Lines
• Modeling Loads and Transmission Lines Part 4: Transmission Lines as Lumped Constants
• SWR, Feedlines, and Reactance Part 1. Dipole Samples
• SWR, Feedlines, and Reactance Part 2. Some Interesting Antennas and Matching Systems
• Series Matching: A Review
• Series and Parallel Coaxial Cable Assemblies
• Some (Old) Notes on Home-Brew Parallel Transmission Lines
• Symposium 1998 Dayton: 12 Ways to See and Love Your Feeders
• Transmission-Line and Tuner Calculation Aids
• Values Along a Transmission Line
• Voltage, Current, and Impedance Along a Transmission Line
• What Happens Along a Length of Feedline
• When and Which Parallel Feedline to Use
• When is a Quarter Wave Not a Quarter Wave?
• Where Do Antennas Fit in Your Communications System?
• Wide-band 50/75-Ohm Feed System

Traps

• 12/17-Meter Trap Quad
• A Trap 2-Band 2-Element Beam for 17 and 12 Meters
• Designing Multi-Band Parasitic Beams (6 Parts)
• Modeling Trap Antennas
• Notes on NVIS Antennas
• Symposium 2007 Dayton: Back to Basics An Antenna Primer for New QRP Operators
• Systematic Trap Modeling
• To Trap or Not to Trap
• Trap Placement Part 1
• Trap Placement Part 2

Turnstile

• AO 16: Horizontally Polarized Omni-Directional Antennas: Some Compact Choices
• Experimental Omni-Directional Antennas for 6-Meters
• FM BC Antennas Part 1: A Few Basics
• Notes on Fixed Satellite Antennas
• Simplifying the Turnstile Moxon Rectangle Fixed-Position Satellite Antennas
• Some Notes on Turnstile Antenna Properties
• The Turnstile An Omni-Directional Horizontally Polarized Antenna
• What's Wrong With This Turnstile Stack?

VHF / UHF

• 2-Element Quads as a Function of Wire Diameter Part 1
• 2-Element Quads as a Function of Wire Diameter Part 2
• 2-Element Quads as a Function of Wire Diameter Part 3
• 2-M/70-CM Dual-Band Yagi for the Home Builder
• 2-Meter Phased Yagis, EDZ Beams, and Landstorfer Yagis
• 2-Meter Yagi Stacks Part 1: 6- to 18-Element OWA Examples
• 2-Meter Yagi Stacks Part 2: 9- to 18-Element DL6WU Examples
• 220-MHz Yagis Index
• 220-MHz Yagis Part 1: Utility Beams: Boom Lengths under 100"
• 220-MHz Yagis Part 2: Medium-Length Boom Beams
• 220-MHz Yagis Part 3: Very Long Yagis
• 220-MHz Yagis Part 4: Special Designs
• 4-Element Monoband Quad Design
• 6-Meter B-Antennas: A Dipole and a 2-Element Beam
• 70-CM Yagi Stacks Part 1: 10- to 40-Element DL6WU Examples
• 70-CM Yagi Stacks Part 2: 10- to 40-Element VK3AUU Examples
• A 100-1000 MHz "Utility" LPDA
• A 3-Moxon Polling Array for 914 MHz
• A 70-CM Wide-Band, Long-Boom Yagi with High Sidelobe Suppression
• A Diamond Jubilee
• A Short Note on Tilted Vertical VHF Antennas
• AO 01: A Yagi Case Study: Part 1, Design Options
• AO 02: A Yagi Case Study: Part 2, Element Material Options
• AO 03: A Yagi Case Study: Part 3, Construction Options
• AO 06: Do I Need More Gain?
• AO 08: How Wide is Wide?
• AO 15: Circularly Polarized Aimed Satellite Antennas
• AO 16: Horizontally Polarized Omni-Directional Antennas: Some Compact Choices
• AO 16a: Horizontally Polarized Omni-Directional Antennas: Some Larger Choices
• AO 18: Reflections on Reflectors
• Appreciating DL6WU Wide-Band Long-Boom Yagi Design
• Automating the Design of 3-Element Monoband Quad Beams Part 1
• Automating the Design of 3-Element Monoband Quad Beams Part 2
• Axial-Mode Helical Antennas Part 1: Helix Basics
• Axial-Mode Helical Antennas Part 2: 10- and 15-Turn Helical
• Axial-Mode Helical Antennas Part 3: Axial-Mode Helices
• Boom Effects with Short 3-Element 146-MHz Yagis
• Building a 2-Meter Moxon
• CAP Emergency-Beacon Direction-Finding Antennas
• Circling the Square Quad
• Corner Arrays for Personal Communications
• Corner Reflectors Revisited Again Part 1: A Systematic Look at Planar Reflector Sides
• Corner Reflectors Revisited Again Part 2: A Non-Systematic Look at Some Corner Variations
• Corner Reflectors Revisited Again Part 3: Rod-Based Corner Reflectors
• Corner Reflectors Revisited Again Part 4: Variations on Standard Corner Reflectors
• Corner Reflectors Revisited Again Part 5: The Very-Wide-Band Corner Reflector
• Corner Reflectors Revisited Part 1: A Comparison With a Good Yagi
• Corner Reflectors Revisited Part 2: The Evolution of a Model
• Corner Reflectors Revisited Part 3: Optimizing the Model
• Counterpoises, Capacity Hats, and A Standard for Suspected of Feedline Radiation
• Expanded Coverage 2-Meter OWA Yagi
• Experimental Omni-Directional Antennas for 6-Meters
• Extending the 2-Meter OWA Family Part 1: 13 to 20 Elements and a Self-Limiting Design
• Extending the 2-Meter OWA Family Part 2: Gain, Element Population, and Hybrid Designs
• Extending the 2-Meter OWA Family Part 3: Increasing OWA Gain vs. Preserving Sidelobe Suppression
• FM BC Antennas Part 1: A Few Basics
• FM BC Antennas Part 2: A Few Possible Yagi Beam Designs
• FM BC Antennas Part 3: Some Ideas for Home-Built Beam Antennas
• FM BC Antennas Part 4: Some LPDA Options
• FM BC Antennas Part 5: The Batwing Antenna and Array
• Half-Square on 2 Meters Part 1: A Bi-Directional Vertical Antenna
• Half-Square on 2 Meters Part 2: Half Square Parasitic Beams
• Half-Square on 2 Meters Part 3: Bobtail Curtain Parasitic Beams
• High-Gain, Wide-Band Yagis for 10, 6, and 2 Meters
• Horizontal Polling Arrays
• Improved Antenna Performance for VHF FM: Some Basics, Some Options, Some Hurdles
• In Pursuit of Better VHF Quad Beams
• Is COCO (Coaxial-Collinear) Your Cup of Tea?
• J-Poles Part 1: Why I Finally Got Interested
• J-Poles Part 2: The Varieties of Twinlead J-Poles
• J-Poles Part 3: The Effects of Element Diameter and Match-Section
• J-Poles Part 4: Some Things We Can and Cannot Do With a J-Pole
• LPDAs for the 400-800-MHz Television Range Part 1: An Ideal But Impractical Antenna
• LPDAs for the 400-800-MHz Television Range Part 2: A Practical Antenna
• Long-Boom Trimming Yagis: An Accumulation of Data
• Long-Boom Yagi Rules of Thumb: A Comparison with Modeling Data
• Long-Boom Yagi Sidelobe Suppression
• Medium-Length 2-Meter Quads and Yagis
• Modeling Biconical Antennas
• Modeling the Double-Diamond for UHF
• Modeling the Dual Rhomboid Part 1: The 1296 MHz Version
• Modeling the Dual Rhomboid Part 2: Will the Real Laport Please Stand Up
• Modeling the Dual Rhomboid Part 3: Some Standards of Comparison
• Moxon Rectangles for 6 Meters
• Multiple Reflectors for Long-Boom Yagis
• Notes on 2-Band (2-M, 70-CM) LPDAs (2 Parts)
• Notes on 6-Element Wide-Band 2-Meter Yagis
• Notes on Fixed Satellite Antennas
• Notes on HF Discone Antennas
• Notes on the Batwing Part 1: Basic Batwing Properties
• Notes on the Batwing Part 2: Uni-Directional and Omni-Directional Batwings
• Notes on the Batwing Part 3: Modeling Issues with the Batwings
• Notes on the OWA Yagi
• Nulling an Unwanted Station: Worse and Better Solutions
• OWA Family Moves to 220
• OWA Family of 2-Meter Yagis Part 1: A Comparison of 12-Element Yagi Designs
• OWA Family of 2-Meter Yagis Part 2: The Entire Family
• Planar Reflectors Part 1: The Planar Reflector and the Dipole
• Planar Reflectors Part 2: Phased Dipoles and Rectangles
• Planar Reflectors Part 3: Bobtails and Diamonds
• Planar Reflectors Part 4: Rod or Bar Reflectors
• Planar and Corner Reflectors Revisited
• Preliminary Studies of Long-Boom Yagis for 420-450 MHz
• Quagi and Yagi on 2 Meters
• Reinventing the (Big) Wheel
• Route 66 6-Meter 6-Element OWA Yagis in 9 Versions
• Scaling and Adjusting VHF/UHF Yagis
• Sidelobe Attenuation and Suppression Part 1
• Sidelobe Attenuation and Suppression Part 2: Notes on 12-Element Yagis
• Sidelobe Attenuation and Suppression Part 3: Notes on 20-Element Yagis
• Simplifying the Turnstile Moxon Rectangle Fixed-Position Satellite Antennas
• Some Notes on Turnstile Antenna Properties
• Some Overlooked Antenna Basics for DX and Off-World Communications
• Split or Continuous LPDAs for Personal Communications
• Stacking Moxon Rectangles Part 1
• Stacking Moxon Rectangles Part 2
• The 3-D Corner Reflector
• The 5/8-Wavelength Mystique Part 2: 2-Meter Elevated Ground-Plane Antennas
• The 64-(Euro-)Dollar Question (6m LPDA)
• The Case of the Curly Collinear
• The Coaxial Folded Monopole
• The Dual-Element Wideband Dipole: Some Preliminary Notes
• The Flat-Plane Reflector for 432 MHz
• The L-Antenna
• The Moxon Rectangle on 2 Meters
• The Practical Lindenblad
• The Prismatic Polyhedron Part 1: Planar Reflector
• The Prismatic Polyhedron Part 2: Planar Reflector Supplementary Data
• The Prismatic Polyhedron Part 3: Corner Reflector
• The Pseudo-Brewster Angle Revisited
• The Quad Beam as an Amateur Satellite Antenna
• The V-Dipole LPDA
• The X-Array
• Two Three-Element Yagis for Six Meters
• Very-Wide-Band Yagi Design Part 1: A Study of Very-Wide-Band Crossed-Element Yagi
• Very-Wide-Band Yagi Design Part 2: Very-Wide-Band Planar Yagi
• What is a Slim Jim?
• What is a Slim Jim? Data Appendix: Radiating and Transmission-Line Currents
• What's Wrong With This Turnstile Stack?
• Wide-Band Utility Yagis for 420-450 MHz Part 1: 4- and 6-Element Models
• Wide-Band Utility Yagis for 420-450 MHz Part 2: An 8-Element Model
• Yagi Driver Assemblies: Linear, Folded Dipole, and Quagi

VOACAP

• VOACAP Type 13 File Patterns
• VOACAP Type 13 Files

Vertical

• 1 MHz Ground-Wave Analysis: Comparison Among MININEC and NEC Modeling Implementations
• 3 Wires = The Whole World
• A Nearly All-Band Vertical Doublet
• A Short Note on Tilted Vertical VHF Antennas
• A Triangle for the Short Vertical Operator
• A Vertical Doublet for 30-10 Meters
• AO 09: A Broadside of Vertical Wires
• AO 11: From Two to One
• An 80-Meter LPMA Part 1. Designing the LPMA With a MININEC Ground
• An 80-Meter LPMA Part 2. The Adequacy of the LPMA Design
• Building a QRP Field Vertical
• Controlled Current Distribution (CCD) Antenna
• Counterpoise? On the Use and Abuse of a Word
• Counterpoises, Capacity Hats, and A Standard for Suspected of Feedline Radiation
• Cutting Formulas
• Differentiating Among Many Types of Grounds
• HF Vertically-Oriented Moxon Rectangles
• Half-Length 80-Meter Vertical Monopoles Index
• Half-Length 80-Meter Vertical Monopoles Part 1: Goals, and Methods of the Study
• Half-Length 80-Meter Vertical Monopoles Part 2: Baseline Data: Full-Size and Capacity-Hat Verticals
• Half-Length 80-Meter Vertical Monopoles Part 3: Base-Loading: Lumped-Constant and Linear Loading
• Half-Length 80-Meter Vertical Monopoles Part 4: Top (Element-Extension) Loading: Linear, Zig-Zag, and Helical Loading
• Half-Length 80-Meter Vertical Monopoles Part 5: Summary Comparisons and Conclusions
• Half-Length 80-Meter Vertical Monopoles Part 6: Descriptions of Models Reported
• Horizontal vs. Vertical Antennas on the Low HF Bands
• Improved Antenna Performance for VHF FM: Some Basics, Some Options, Some Hurdles
• Is COCO (Coaxial-Collinear) Your Cup of Tea?
• J-Poles Part 1: Why I Finally Got Interested
• J-Poles Part 2: The Varieties of Twinlead J-Poles
• J-Poles Part 3: The Effects of Element Diameter and Match-Section
• J-Poles Part 4: Some Things We Can and Cannot Do With a J-Pole
• M3KXZ 2-Element Vertical Phased Array
• Modeling 160-Meter Vertical Arrays Index
• Modeling 160-Meter Vertical Arrays Part 1: Some Baseline Data
• Modeling 160-Meter Vertical Arrays Part 2: Appreciating Conductivity and Permittivity
• Modeling 160-Meter Vertical Arrays Part 3: Complex Radial Systems
• Modeling 160-Meter Vertical Arrays Part 4: A Potpourri of 160-Meter Vertical Antennas and Modeling Issues
• Modeling 160-Meter Vertical Arrays Part 5: The Use of Multiple Ground Qualities in Lieu of Radials
• Modeling Perspective on Ground Planes Index
• Modeling Perspective on Ground Planes Part 1: Some Preliminary Notes on the Ground
• Modeling Perspective on Ground Planes Part 2: "Capacity" Hats
• Modeling Perspective on Ground Planes Part 3: Planes in Space
• Modeling Perspective on Ground Planes Part 4: Down to Earth Verticals
• Modeling Perspective on Ground Planes Part 5: Regional Differences
• Models with Buried Radials: A Small Compendium
• NEC-2 and NEC-4: Reading Trends with Caution 7 MHz Vertical + Ground Plane
• Noise, Antennas, and Receiving Systems
• Notes on HF Discone Antennas
• Notes on Hatted Vertical Dipoles for 10 Meters
• Notes on the Extended Aperture Log-Periodic Array
• Pursuing the (Nearly) Perfect Parasitic Vertical Array for 160 Meters Part 1
• Pursuing the (Nearly) Perfect Parasitic Vertical Array for 160 Meters Part 2
• Screening 40-Meter Vertical Arrays
• Short Folded Monopoles Basic Properties
• Short Folded Monopoles Extended Applications
• Symposium 1999 Dayton: Verticals without Vertigo
• Symposium 2003 Dayton: Some Principles of Portable Antennas to Strive For
• Symposium 2007 Dayton: Back to Basics An Antenna Primer for New QRP Operators
• The 40-Meter 3-Way Special
• The 5/8-Wavelength Mystique Index
• The 5/8-Wavelength Mystique Part 1: 80-Meter Monopoles With Buried Radials
• The 5/8-Wavelength Mystique Part 2: 2-Meter Elevated Ground-Plane Antennas
• The 5/8-Wavelength Mystique Part 3: Upper HF Monopoles and a "Poorly Grounded" Speculation
• The Case of the Curly Collinear
• The Coaxial Folded Monopole
• The IL-ZX as an 80-Meter Vertical
• The Insulated Radial Question
• The Pseudo-Brewster Angle Revisited
• The Slippery Sloper Argument
• Vertical Dipoles and Ground Planes What Antenna Modeling Reports
• What Is a Folded Monopole? Skirting the Issue
• What is a Slim Jim?
• What is a Slim Jim? Data Appendix: Radiating and Transmission-Line Currents
• Where Do I Hang My Hat?
• Your First 160-Meter Antenna

Voltage Feeding

• SCVs Part 1: The Group Picture
• Voltage Feeding SCV Loops

W8JK

• AO 10: Horizontal Bi-Directional Wires
• Modeling and Understanding Small Beams Part 3: The EDZ Family of Antennas
• Sorting Out Bi-Directional Phased Arrays
• Symposium 2004 Dayton: My Top Five Backyard Multi-Band Wire HF Antennas
• The "Lazy-8JK"

X Beam

• A Tale of 4 Beams: The X, the Hex, the Square, and the Rect
• Modeling and Understanding Small Beams Part 1: The X-Beam
• The X-Array

Yagi

• 1-2-3: 1 Boom, 2 Bands, 3 Elements Each
• 2-Element Yagis: How Short Can We Go?
• 2-M/70-CM Dual-Band Yagi for the Home Builder
• 2-Meter Phased Yagis, EDZ Beams, and Landstorfer Yagis
• 2-Meter Yagi Stacks Part 1: 6- to 18-Element OWA Examples
• 2-Meter Yagi Stacks Part 2: 9- to 18-Element DL6WU Examples
• 220-MHz Yagis Index
• 220-MHz Yagis Part 1: Utility Beams: Boom Lengths under 100"
• 220-MHz Yagis Part 2: Medium-Length Boom Beams
• 220-MHz Yagis Part 3: Very Long Yagis
• 220-MHz Yagis Part 4: Special Designs
• 6-Meter B-Antennas: A Dipole and a 2-Element Beam
• 70-CM Yagi Stacks Part 1: 10- to 40-Element DL6WU Examples
• 70-CM Yagi Stacks Part 2: 10- to 40-Element VK3AUU Examples
• A 3-Element Wire Yagi Design for 10.1373 MHz
• A 70-CM Wide-Band, Long-Boom Yagi with High Sidelobe Suppression
• A Little Matching
• A Short Look at Wire Beams
• A Trap 2-Band 2-Element Beam for 17 and 12 Meters
• AO 01: A Yagi Case Study: Part 1, Design Options
• AO 02: A Yagi Case Study: Part 2, Element Material Options
• AO 03: A Yagi Case Study: Part 3, Construction Options
• AO 06: Do I Need More Gain?
• AO 08: How Wide is Wide?
• AO 13: NVIS Antennas for Special Needs
• AO 14: Reversible Wire Beams for Lower HF Use
• AO 15: Circularly Polarized Aimed Satellite Antennas
• AO 18: Reflections on Reflectors
• Antenna Design
• Appreciating DL6WU Wide-Band Long-Boom Yagi Design
• Boom Effects with Short 3-Element 146-MHz Yagis
• Build a 3-Element Yagi Index
• Build a 3-Element Yagi Part 1: How Big Shall I Make It?
• Build a 3-Element Yagi Part 2: How Wide-Band Shall I Make It?
• Build a 3-Element Yagi Part 3: What Real Dimensions Shall I Use?
• Build a 3-Element Yagi Part 4: How Shall I Feed the Antenna?
• CAP Emergency-Beacon Direction-Finding Antennas
• Cutting Formulas
• Design of a 2-3-Element Full-Performance Yagi for Portable and Field Use (3 Parts)
• Designing Multi-Band Parasitic Beams (6 Parts)
• Director/Driven Element 2-Element Yagis for 12 and 17 Meters
• Dream Beams Index
• Expanded Coverage 2-Meter OWA Yagi
• Extending the 2-Meter OWA Family Part 1: 13 to 20 Elements and a Self-Limiting Design
• Extending the 2-Meter OWA Family Part 2: Gain, Element Population, and Hybrid Designs
• Extending the 2-Meter OWA Family Part 3: Increasing OWA Gain vs. Preserving Sidelobe Suppression
• FM BC Antennas Part 1: A Few Basics
• FM BC Antennas Part 2: A Few Possible Yagi Beam Designs
• FM BC Antennas Part 3: Some Ideas for Home-Built Beam Antennas
• Forming Reasonable Expectations of Modern Tri-Band Beam Designs
• Half-Length Dipoles (for 40 Meters)
• High-Gain, Wide-Band Yagis for 10, 6, and 2 Meters
• Horizontal Polling Arrays
• Horizontal and Vertical Yagi Orientation
• How Accurately Must We Aim a Beam?
• How High is My Antenna?
• Improved Antenna Performance for VHF FM: Some Basics, Some Options, Some Hurdles
• Interesting Alternatives to the Yagi
• Lobe Formation With Height Increases in Horizontal Antennas
• Long-Boom Trimming Yagis: An Accumulation of Data
• Long-Boom Yagi Rules of Thumb: A Comparison with Modeling Data
• Long-Boom Yagi Sidelobe Suppression
• Lower HF Wire Beams
• Medium-Length 2-Meter Quads and Yagis
• Modeling 6 Long-Boom Yagis
• Modeling Yagis by Equation Part 1. Background and One Example
• Modeling Yagis by Equation Part 2. High-Gain and Wide-Band Yagis
• Modeling and Understanding Small Beams Part 4: Linear-Loaded Yagis
• Modeling and Understanding Small Beams Part 8: Capacity Hats
• Monxon Yagi Rectangle for 10m 15m 20m
• Moxon Rectangles for 30m and 40m
• Moxon-Modifying the C3-Type Tri-bander
• Multiple Reflectors for Long-Boom Yagis
• Noise, Antennas, and Receiving Systems
• Notes on 6-Element Wide-Band 2-Meter Yagis
• Notes on NVIS Antennas
• Notes on Reversible Yagi Arrays
• Notes on the OWA Yagi
• Nulling an Unwanted Station: Worse and Better Solutions
• OWA Family Moves to 220
• OWA Family of 2-Meter Yagis Part 1: A Comparison of 12-Element Yagi Designs
• OWA Family of 2-Meter Yagis Part 2: The Entire Family
• Preliminary Studies of Long-Boom Yagis for 420-450 MHz
• Quagi and Yagi on 2 Meters
• Route 66 6-Meter 6-Element OWA Yagis in 9 Versions
• Scaling and Adjusting VHF/UHF Yagis
• Short Beams and Operating Bandwidth
• Sidelobe Attenuation and Suppression Part 1
• Sidelobe Attenuation and Suppression Part 2: Notes on 12-Element Yagis
• Sidelobe Attenuation and Suppression Part 3: Notes on 20-Element Yagis
• Stacked Beams
• Stacking Yagis (3 Articles)
• Stacking: What Difference Does Difference Make?
• Substituting Wire Elements in Lower HF Arrays
• Supplementary Notes on Stacking
• Symposium 1996 Dayton: Overview of Small Loaded Yagis
• Symposium 1997 Dayton: Wi're We Using Wire?
• Symposium 2001 Dayton: Mastering Some Mysteries of 2-Element Beams Part 1
• Symposium 2002 Dayton: Mastering Some Mysteries of 2-Element Beams Part 2
• Symposium 2006 Dayton: Welcome to Yagi-World
• The "Quad vs. Yagi" Question
• The Flat-Plane Reflector for 432 MHz
• The G4ZU Bird Yagi
• The Inverted-U Yagi on 20 Meters
• The Inverted-U as a Field Yagi
• The Monoband Log-Cell Yagi Revisited Index
• The Monoband Log-Cell Yagi Revisited Part 1: An Introduction to the Log-Cell Yagi
• The Monoband Log-Cell Yagi Revisited Part 2: Element Phasing and Log-Cell Design
• The Monoband Log-Cell Yagi Revisited Part 3: Some Practical Log-Cell Yagi Designs
• The Monoband Log-Cell Yagi Revisited Part 4: Vee-ing the Log-Cell Yagi Elements
• Three Forward-Stagger 5-Band Yagis from ON4ANT
• Three-Element Yagi Models: Standards of Comparison
• Two Three-Element Yagis for Six Meters
• Using Moxon Rectangles for WARC-Band Antennas Part 2
• V-Yagi Notes
• V-Yagi is it a 3-Element Moxon?
• Vertically-Oriented, Horizontally Polarized 1 wl Loops
• Very-Wide-Band Yagi Design Part 1: A Study of Very-Wide-Band Crossed-Element Yagi
• Very-Wide-Band Yagi Design Part 2: Very-Wide-Band Planar Yagi
• What Can We Expect from a 2-Element Beam? Index
• What Can We Expect from a 2-Element Beam? Part 1: Method, Units of Measure, and the Dipole Standard of Reference
• What Can We Expect from a 2-Element Beam? Part 2: The Full-Size 2-Element Yagi
• What Can We Expect from a 2-Element Beam? Part 3: Shortened Dipoles and Capacity Hat Yagis
• What Can We Expect from a 2-Element Beam? Part 4: Loaded Yagis
• What Can We Expect from a 2-Element Beam? Part 5: Strategies for Improving Forward and Rearward Performance
• Why Parasitic Beams Work
• Wide-Band 40-Meter Yagis Part 1: Standard and Non-Standard Designs
• Wide-Band 40-Meter Yagis Part 2: Alternative 4-Element Designs
• Wide-Band 40-Meter Yagis Part 3: A 3-Element Wire Design
• Wide-Band Utility Yagis for 420-450 MHz Part 1: 4- and 6-Element Models
• Wide-Band Utility Yagis for 420-450 MHz Part 2: An 8-Element Model
• Wire Beam for 80 and 75 Meters
• Yagi Driver Assemblies: Linear, Folded Dipole, and Quagi
• Yagi Element Diameter