Canvey Island, Essex, England Justin@g0ksc.co.uk
Twin boom quad
144MHz LFA Yagis
144MHz LFA Yagis

Low Noise LFA Yagis designed by G0KSC free to build for personal use.

144MHz LFA Yagis
70cms LFA Yagis
70cms LFA Yagis
Twin-Boom G0KSC Quads
G0KSC Twin-Boom Quads
Twin-Boom G0KSC Quads
G0KSC Custom Dish feeds - Above installation @ HB9Q
Custom low-noise dish feeds
Custom low-noise dish feeds
G0KSC Custom Dish Feeds

Above installation @ HB9Q

G0KSC Custom Dish feeds - Above installation @ HB9Q
previous arrowprevious arrow
next arrownext arrow
 
Read Time: 3 - 5 minutes

G0KSC SC6-4-11D 11el 50Mhz/70Mhz Dual band Yagi Antenna with a 4.9 Metre Length Boom

About this Antenna

This is a dual band Yagi for both 50Mhz and 70Mhz which has a single feed point. This is what is known as an 'interlaced' Yagi as both a 70Mhz beam and a 50Mhz beam (there are no common elements) are interlaced and sitting on the same boom.

The next interesting feature is the fact none of the 70Mhz elements are physically connected to the feed point. The 70Mhz antenna is feed by it's closeness to the 50Mhz elements. i.e. the driven element of the 70Mhz Yagi sitting closely to the 50Mhz driven. It is a little more technical than that but so as the masses can understand how it works. This antenna performs as a 6 element beam on six metres and a 5 element beam on four metres.

You will also note the first director element on 50Mhz is very close to the driven element on the same band. The 70Mhz elements alter the feed impedance of the 50Mhz Yagi and the first director always acts as a tuning device. For this reason, the first director has had to be brought much closer than usual in order for a match to be seen.

The Interlaced OWA design removes these restrictions from the mix. With no losses from matching and just one feed point you have a winning formula!

Design Considerations

Interlaced, single feed point Yagi's are hard to model and there is some interaction between the elements. As a result, I have had to compromise a little more than one normally would have to in order to achieve my performance directives. In this case, I have sacrificed a little Front to Back ratio in an attempt to maintain as flat an SWR curve as possible. There are a couple of reasons for doing this. One, of course is to give as much bandwidth as possible but mainly, as with all antennas on this site, if the SWR curve is wide and low, any small mistakes in sizing and spacing by the builder will not make a tremendous impact on the antennas overall performance.

The image below shows how the antenna looks. The 50Mhz and 70Mhz antenna elements are easily seen apart.

The SC6-4-11D installed and built by GM3NKG

'wrk'd E4X on Sunday, cracked the pile up with 50W, was first qso with antenna on 6'

GM3NKG

 


The SC6-4-11D installed at G8FJG

'50mhz flat from 50.000-51.00...much less than 1:1.1 measured in shack
70mhz flat 70.0 - 70.4  less 1:1.1'

Ron, G8FJG

 


 

 

Sizing and spacing are as follows:

Dimensionsin Metres

Element spacing:

  • Ref 6     =     0
  • Ref 4     =     .255
  • Driven 6 =     .824
  • Driven 4 =     .734
  • D1-6     =      .883
  • D1-4     =      1.396
  • D2-6     =      1.765
  • D2-4     =      2.731
  • D3-6     =      3.376
  • D3-4     =      4.118
  • D4-6     =      4.896

Element sizes per element half:

  • Ref 6     =       1.473
  • Ref 4     =       1.056
  • Driven 6 =       1.456
  • Driven 4 =       1.026
  • D1-6      =       1.35
  • D1-4      =       .988
  • D2-6      =       1.37
  • D2-4      =       .947
  • D3-6      =       1.339
  • D3-4      =       .918
  • D4-6      =       1.313

Performance figures @ 50.250Mhz:

  • Froward Gain: 11.17dBi free space
  • Front to Back: 17.18dB
  • Radiation angle at 10 Metres above ground: 8 degrees

 

Performance figures @ 70.250Mhz:

  • Froward Gain: 10.55dBi free space
  • Front to Back: 14.37dB
  • Radiation angle at 10 Metres above ground: 5 degrees

 

Element diameter:

Each element is made out of single piece 1/2 inch (12.7mm) aluminum tubing Each element half length needs to be doubled in order to gain your total element size. No difference is length needs to be calculated for the 1inch or 1,1/4 inch boom as the elements sit high enough above the boom for the boom to have no influence.

NOTE:

You can build this antenna with 13mm diameter tubing using the same parameters above. Slightly higher front to back ratio and forward gain will be seen along with a narrower SWR curve.

 

For construction information see 'G0KSC insulators' and the UKSMG article from the main menu on the home page.

Below are two images showing current distribution through the antenna on both 50Mhz and 70Mhz. This current is represented by the line lines overlaying the elements. The higher the line is away from the element, the higher the current.

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Note the radiation effeciency circled in the window below

 

 

And again on 70Mhz even though there is no direct feed.