Building the Single Sided 8 Slot Waveguide

We used 100mm x 50mm rectangular hollow box section aluminium with 3mm thick walls. This gives us an internal size of 94mm x 44mm. We chose to build the antenna for 2.442GHz, or channel 7, as this is close to the center of the 13 channels available to us (US designs use channel 6 (2.437Ghz), as they have 11 channels). The internal width (the wide side), determines the operating frequency. The internal height (the narrow side) determines the impedance. We used Rob Clark's 5 wavelength design over Trevor Marshall's 4.75 wavelength design simply because we could cut the 5 wavelength design down to get the 4.75 wavelength one if our first try didn't work. Trevor's design also has wider slots and our slots could be made wider if we messed them up too much. We used Paul Wade's spreadsheet (Slotantenna.xls)to calculate the slot sizes and placement (The "Improved from Elliot" figures with a 2% reduction in slot length for square ends (see his text)). I have included a key lengths calculator in the form below.

Frequency

GHz

Wide Side

mm (Inside Measurement)

Short Side

mm (Inside Measurement)

Material Thickness

NSlots

One Sided

Te10 Cut off
Frequency

GHz to next mode

GHz

Operating Range

GHz to

GHz

Free Space
Wavelength

Waveguide
Wavelength

Waveguide
1/4 Wavelength

Probe Length

Slot Length

Slot width

Slot Offset

mm (From Center to Slot Center)

Slot Spacing

mm (centers)

Slot to Top

mm (center to top Plate)

Slot to Probe

mm (center to probe center)

Probe to Bottom

mm (Probe center to Bottom Plate)

Inside Length

mm (Top to Bottom Plate)

Outside Length

mm (Top to Bottom)

The waveguide impedance drops rapidily from infinite at Te10 cut off, then becomes close to linear
Te10 Cut Off is the lowest frequency the waveguide will operate at.
At the next mode frequency, the waveguide will resonate differently, and at a different speed
(Next mode cut off is usually the Te20 mode, but if the width < 2 x Height, it becomes the Te01 mode)
Operating Range is ~1.27 x Te10 Cut Off, up to 95% of the next mode Frequency
The low 27% of the range has a very rapidly changing impedance
Above 95% of the next mode, there is a danger of jumping to a different resonant mode.

The final product only needs to be accurate to about 1mm as this will only shift the frequency within the range of the 802.11 spectrum. A smaller slot length will shift the frequency response of that slot to a higher channel. A longer slot length will shift it down. Changes in the slot spacing affects the vertical signal pattern. A smaller spacing (higher channel) results in the lower channels having a slightly downward vertical pattern. A larger spacing (A lower channel) will result in higher channels having a slightly upward tilted vertical pattern. Slot width variation affect the frequency response. The distance of each slot from the center varies with design. I don't know what this affects. One design deliberately changes this distance for each slot so as to reduce the side lobes of the vertical radiation pattern.

Methods and madness

I measured to .1mm using vernier callipers, on the assumption that errors in cutting might bring that closer to the 1mm error mark. I did in fact manage to get most slots cut to a few tenths of a mm in length. I used a drill press to make holes at either end of each slot and a hand held router with built on guide to cut between them. I then used a file to square the ends of each slot and to clean the edges up.

Misc Notes

100 is added to the bottom (alternately 50mm top & bottom) for mounting (included in form as the outside length).
I used 3mm aluminium because the N-Socket is 3mm deep. The thickness also alters the slot calculation, but I have no idea how (I'm told the slots would be smaller in length, but I don't know what the exact realtionship is). People have successfully used much thinner material.
The slots alternate left and right of center, but it doesn't matter which way the first one goes.
We made the top cap from part of a 44mm offcut and filed it so it was a tight fit (I'm told this isn't that crtical).
The other side of the offcut was used for bottom plate (We made it an L shape to help in fixing it) and used the callipers to measure how far down the tube it needed to go.
The probe is a 2mm diameter copper wire soldered into an N-Socket and cut 1/8λg, including the protruding bit of the N-Socket (Should be slightly longer). Using a cone for a probe gave a much better SWR.
The N-Socket is held down with nylon screws. I threaded the mounting holes. If you use metal screws, use stainless steal ones and keep them short so they don't protrude into the cavity.
Water in the antenna, or spider and insects will be a problem. One suggestion is to make the antenna upside down and make small holes in the top plate to let the water out. Another is to cover the holes with thin microwave transparent tape, such as Kapton (source 3M and expensive) or Mylar (3M and others, but a common polyester tape with an acrylic adhesive. Sometimes called Yellow Thermoset tape). Some people have used other tapes. They should be as thin as possible and not heat up in the microwave.

Step by Step pictorial guide

A view from the Front.

For a step by step pictorial guide, follow me. The same contruction technique is common to both the single and double sided wave guide antenna.