High Gain Wi-fi Antenna project

Presented here may be a versatile, durable, and rather distinctive Wisconsin fi antenna which will greatly extend your wireless networking vary and speed. once designed with 10 or a lot of turns, this coiling Wisconsin fi antenna immensely outperforms the cantennas and Wisconsin fi pan tiptop typically seen on the web. a brief 5 flip coiling makes a awfully smart feeder for a Wisconsin fi parabolic directional antenna. A special quality of this antenna is that it radiates and receives a circularly polarized signal. It doesn't favor vertically or horizontally polarized signals. Thus, this antenna works well Wisconsinth wi fi signals reflective off of buildings, moving vehicles, or antennas orientated at odd angles. Circularly polarized signals ar less suffering from rain, thus you'll be able to reach distant access points in stormy weather. there's a three decibel loss of gain once exploitation this antenna with linearly polarized signals; high gain is maintained by creating the antenna long - a minimum of 10 turns for complete usage.

At this point you should have a PC board with a circle in the center, four tick marks on the circle at 90 deg intervals, and one tick mark exactly between two others

PARTS REQUIRED FOR THE WIFI HELICAL ANTENNA:

1. one square piece of copper sheet metal or single sided PC board for a ground plane.
2. one PVC kitchen drain tailpiece (3.8 cm / 1.5" diameter) to hold the helical windings
3. six 1/8" plastic cable ties
4. a length of copper circuit tape (adhesive backed, width 3mm or 1/8") or #14 copper wire
5. one suitable chassis connector (I used a reverse sma type matching the connector on my adaptor)
6. one 90 degree angle bracket with screws and bolts to fit

CONSTRUCTION:

1. Center the tailpiece on the PC board, copper side, and mark the circumference in ink.
2. Mark four locations on the circumference, spaced 90 degrees, where the cable ties will hold down the PVC tube.
3. Mark one location on the circumference, exactly between two 90 degree markings, where the coaxial connector will be mounted. 

At this point you should have a PC board with a circle in the center, four tick marks on the circle at 90 deg intervals, and one tick mark exactly between two others.

4. Drill 1/8" holes on the inside and outside of the circumference at the cable tie locations.
5. Drill a hole directly on the circumference suitable for the chassis connector. Carefully measure and drill other holes for this connector if necessary.
6. Drill four holes, spaced 90 deg apart near the bottom end of the PVC tailpiece.
7. Drill holes to accomodate a small 90 degree corner bracket.
8. Drill holes on opposite side of board to accomodate USB wi-fi adapter that will be affixed with cable ties.
9. Tin the copper around the connector mounting hole, then mount the connector. Clip the center pin to keep it only long enough for connection to the helix windings.
10. Cut out a notch to accomodate the connector; it should clear center conductor, but avoud cutting out excess PVC material.
11. Feed cable ties through from the back side of the board, through holes in the tube, and back through the board. Tighten the cable ties, making sure the tube is firmly held to the copper ground plane.
12. Use a ruler and the edge of a sheet of paper to create a template for positioning the windings on the PVC tube. Distance zero represents the ground plane, then add the feedpoint distance, then ticks matching the turns spacing. Use the template to mark your tube on both the feedpoint side and the opposite side.

Space the turns 2.5 cm on a
tube of 3.9cm outer diameter.

Here is a table used for my prototype helical wi-fi antenna and its connector. Note that turn 1 starts at 0.8 cm (height above ground plane of feedpoint). Turns Spacing is 2.5 cm, and the diameter is 3.9 cm (close enough for 1.5" PVC tailpiece). If your connector can be trimmed to allow a feed connection closer to the ground plane than 0.8CM, then simply run the helix as low as necessary. Most impartant is keeping the proper spacing between turns.

Spacing=2.5cm Diameter=3.9cm (fits 1.5" PVC tailpiece)
Turn #	Height (cm) above groundplane	Half Turns Height (cm)
1 (feedpoint)	0.8	2.05
2	3.3	4.55
3	5.8	7.05
4	8.3	9.55
5	10.8	12.05
6	13.3	14.55
7	15.8	17.05
8	18.3	19.55
9	20.8	22.05
10	23.3	24.55
11	25.8	27.05
12	28.3	29.55
13	30.8	32.05

13. Carefully wind the helix, using circuit tape or wire, then solder to center conductor of chassis connector. Double check against the turns template. Polarization will be right-handed if the turns spiral clockwise (looking outward from feedpoint). 
    

  14. Attach the angle bracket and wi-fi adapter, making sure all parts are secure and ready for service, as seen in the images below. 

 The high gain wi-fi helical antenna.
10 turn stand alone version

 

Cable losses avoided by
mounting wi-fi adapter
at base of antenna. 

Short wi-fi helix feeding a long range parabolic wi-fi
antenna.

At this point, helical wi-fi antenna is ready for its smoke test...plug in the cables and look for some signals! Theoretical gain of the prototype helical was about 18 dB over an isotropic radiator; it beat my biquad by about 7 to 13 RSSI units, and indeed seemed less sensitive to polarization and rainfall. Signals still seem to fluctuate much from second to second. If your antenna is functioning satisfactorily at this point, I suggest spray painting three layers of clearcoat onto the windings and groundplane for stability and corrosion prevention.
 Electronics Circuit Application