Javascript Electronic Notebook Electrically Short Half-Wave Dipole by Martin E. Meserve

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Introduction

Description

InitialParameters

PossibleConfigurations

CustomDimensions

B & WInductors

This page is a direct adaption of a HamCalc program by, George Murphy (VE3ERP), for designing Short Off-Center-Loaded Dipoles.

Shown below is a diagram of a lumped-constant loaded dipole antenna that is intended to fit in available space, rather than requiring a full 1/2 wavelength, at a specified frequency. As long as the physical length is longer than 0.2 wavelengths, it will work well at any height between 30 and 90 Ft. The antenna can be fed directly with 50 Ohm coaxial line or, as the drawing shows, throuh a 1:1 Balun.

This electrically shortened dipole is similar in appearance to a trap dipole except the `traps' consist of coils only, causing the antenna to operate not unlike two mobile inductively loaded whips mounted horizontally, base-to-base.

The performance of any antenna depends upon many factors, not the least of which is its design. This program will help you arrive at a mathematically precise design, but the overall performance of any antenna also depends upon construction integrity, location, height, orientation, terrain, surrounding objects, etc. Some antenna adjustment and pruning to compensate for these variable conditions is nearly always required.

The inductance required is based on the antennas total width (A), the distance from the center of the antenna to the loading coil (B), the wire diameter (D) of the radiating elements, and the required operating frequency (f). The equation for determining the inductance required is listed below. This web page eliminates the need for you to try and enter this messy equation in your calculator/computer. Note that the dimension C is the distance from the input of the Loading Coil to the end insulator.

Reduce your available space by 6" to 12" on each side to allow for securing and insulating the dipole from it's supports. The exact distance required depends on your mounting method.

There is a minimum space requirement, which is displayed early in the program. Shorter lengths will work but will be less efficient. For maximum efficiency the antenna should be as long as possible, consistent with available space.

Program Description

The Initial Parameters section asks for some basic information, like the intended operating frequency, the available horizontal space, and the wire size. It then lists the minimum space you should use and the space required for a full size dipole. If the available space is not big enough, you may wish to choose an alternative antenna, like an Inverted Vee. You can get creative and combine the Inverted Vee antenna with loaded radiators to fit in just about any space.

The ratio of the antenna length to the wire size does have some effect on the overall length of the antenna, but the difference is small and you will need to do some pruning anyway. So just use a wire size that is close to what you may be using.

The Possible Antenna Configurations section presents you with 9 variations for the antenna dimensions. They are listed in order from least to most efficient. For maximum efficiency select the combination using the largest inductor that is practical for your application.

The Custom Dimensions section lets you define other lengths for Dimension B. The program will then calculate the necesary inductor value and Dimension C for these lengths.

The Possible Antenna Configurations section and the Custom Dimensions section have buttons that will bring up a program for designing the inductor of your choice. In the Possible Antenna Configurations section choose the antenna configuration you with to use and press the Design Coil button. In the Custom Dimensions section, just press the Design Coil button.

The Custom Coil link brings up a program for designing the inductor you have decided on.

Once you have the inductor value the physical characteristics of the loading coils can be developed using the Coil Design program (available through this link or from the Navigation Bar), or, Barker & Williamson pre-wound air core inductors are available in a variety of diameters, turns per inch, and lengths.

Barker & Williamson air core inductors are pre-wound coils with plastic supports to maintain their shape and structure. It is purchased in stock lengths and then trimmed down to the size required. This is a good source of very stable and accurate coils. Use the link in the Navigation Bar to display a catalog listing of available coil stock.

For an acceptable Q choose a coil whose length does not exceed twice its diameter.

Another antenna intended for restricted space, using a slightly different approach for the loading coil, is the Shorty 40. The Shorty 40 is intended for use on 40 Meters, but it will fit in the space required for a 20 Meter dipole.

Initial Parameters

Enter your initial requirements. Specify the Center Frequency, in MHz, for the band you want the antenna to operate in, the Length Available for Dimension "A" and the Wire Size.

The output data will indicate the Minimum Required Space for Dimension A. This is the minimum length for maximum efficiency. Shorter antennas will also work, but at reduced efficiency. Also, it will list the space required for a Full Size Dipole.

NOTE: In your specification for Dimension A, be sure to allow space for the end insulators. Derate your space available by the amount needed for the end insulators.

Center Frequency

Dimension "A"

Ft M

Wire Size

AWG# inches mm

A Full Size dipole for x would require x. For maximum efficency, the Shortened Dipole should be no shorter than x. The length of x for Dimension A, as specified above, should not include end insulators or mounting brackets. This is strictly the length of the antenna.

Possible Configurations

The table below lists 10 variations for the placement of a loading coil. They are listed, in order, from least to most efficient. Using the buttons next to the antenna numbers select the configuration you would like to use. Then use the Coil Design program, or, Barker & Williamson pre-wound air core inductors are available in a variety of diameters, turns per inch, and lengths.

For maximum efficiency select the combination with the highest coil Q that is practicable for your application.

The loading coils should be as far from the center feed point as possible, bearing in mind that as the distance for the feed point increases, coil size increases and the self-resonant frequency decreases until it reaches the operating frequency, at which point coil Q decays to zero, and the antenna efficienty approaches zero.

If one of the selections does not meet your requirements, the Custom Dimensions section will allow you to define other lengths for Dimension B and Dimension C. The program will calculate the necesary inductor value for these lengths.

<------ Dimensions ------>

<------------- Inductor ------------->

Ant.

B

C

Ind.

Dia.

Self Res.

Q

0

1

2

3

4

5

6

7

8

9

The chart below shows the dimensions for Antenna Number x, which is to be used on x. The chart on the right details the coil specifications for this antenna.

Available Space (A) -

x

Dimension B -

Dimension C -

Inductance -

Diameter -

Length -

Turns -

Wire Size -

Antenna Configurations Using Custom Dimensions

You can use the previously calculated table of dimensions for your antenna or specify a different B Dimension. The required inductance for the specified dimension will be automatically calculated. The Frequency and Available Space are brought down from the Initial Parameters section. The drawing for the antenna is again included below, for clarity.

Length forDimension "B" Ft M

Frequency -

Required Inductance -

Barker & Williamson Air-Core Inductors

CatalogNumber

Diameter(in.)

Turnsper Inch

Length(in.)

AWG#

3001

0.5

18

3002

3003

16

20

3004

32

24

3005

0.625

3006

3007

3008

3009

0.75

3010

3011

3012

3013

3014

3015

3016

3017

1.25

14

3018

3019

3020

3021

1.75

3022

3023

3024

3025

10

12

3026

3027

3029

2.5

3030

3031

3033

3034

3035