The next step is to mount the components on a mast. I am planning on a longevity and durability test in the near future.
In my spare time I build and test various wifi designs found on the Internet. I am using this knowledge to build cheap and simple wifi hot-spots that can be setup with very little technical knowledge. I believe that wifi should be in all places people frequent. From the mall, the grocery store, to downtown areas, free wireless Internet should be everywhere.
Tuesday, January 31, 2012
Solar powered router
My completed solar powered WAP. 12 solar charged PSU, solid lead-acid 12v 7.2mAh battery, Sunforce charge controller, and two Sunforce 1.8w panels.
The next step is to mount the components on a mast. I am planning on a longevity and durability test in the near future.
The next step is to mount the components on a mast. I am planning on a longevity and durability test in the near future.
Collinear Antenna Testing (indoors) Part 2, dual antenna
Round two of the indoor collinear tests. This time I used two of the 6Dbi antennas.
Below is the test data. Methodology is the same as before. Indoors tests run at 5, 10, 30 feet 1 wall, and 60 feet 2 walls. At each distance, the speed test was run 5 times. The five runs are averaged. The power settings ranged from 71mw default to 250mw maximum transmit power.
The bottleneck that arose at higher Tx powers on the single antenna were non-existant with this setup. At higher tx powers, the test device was able to approach 802.11g maximum bandwidth, which is 108mbps or 108000 kbps. It was also found that higher throughput was achieved at farther distances at higher tx powers.
Below is the test data. Methodology is the same as before. Indoors tests run at 5, 10, 30 feet 1 wall, and 60 feet 2 walls. At each distance, the speed test was run 5 times. The five runs are averaged. The power settings ranged from 71mw default to 250mw maximum transmit power.
71mw
100mw
150mw
200mw
250mw
The bottleneck that arose at higher Tx powers on the single antenna were non-existant with this setup. At higher tx powers, the test device was able to approach 802.11g maximum bandwidth, which is 108mbps or 108000 kbps. It was also found that higher throughput was achieved at farther distances at higher tx powers.
Monday, January 16, 2012
Sector Antenna version 2 teardown
I decided to redesign the sector antenna backplate/reflector to make it more robust. As you can see the hot-glued antenna standouts were inadequate to deal with even transport vibrations. I have decided to use nylon screw anchors the next time. The main differences between this and version one are as follows. Most noticeable is the copper coating on the reflector assembly. I used copper gasket spray which can be purchased at automotive parts house. The second difference is the copper insulator at the center of the antenna element. A few other people have used this method, I found it was far superior for holding everything in place and aligned. There are no other modifications done.
Cantenna Radome Part 1
The final part of the cantenna is the radome. This protects the antenna element and the reflector assembly from the elements. Most of the radomes in industry are made from UV resistant plastics or UV painted fiberglass. I chose to use fiberglass, as it is very easy to get and is easy to form. I created a plug form from a 3" tube.
Rubber gasket material was used to form the ridge. Hot-glue was used to affix it
A cardboard end cap
Wrapped with industrial plastic wrap. Afterward a liberal application of petroleum jelly or mold release
Small gap for sealant
Automotive silicone sealant affixes the finished radome to the antenna
Finished product
Testbed Part 1
I have come across a need to be able to try different antennas on the two stands I have. That led me to a removable mast system to allow for easy switching of antenna assemblies. I had some elongated thumb-screws and some threaded t-nuts. 1/4" holes in the stand and antenna assembly for the thumb-screws.
Friday, January 13, 2012
Collinear Antenna Testing (indoors)
This is my first serious test. I chose to stay indoors. The antenna was located at one end of the house. I took measurements at 5, 10, 30 and 60 foot intervals. The 30 and 60 foot sections had one and two walls between the test set and the antenna respectively.
The base unit consisted of the 6dbi omni antenna, a wrt54gs v6 loaded with ddwrt build v24SP2 (build 12548M).
The remote unit is an iPhone 3g running Ciscos GIST test app. It is the only wifi speed test app that runs without an internet connection. There seems to be some variance in the results reported by the app, either due to app/hardware integration, wifi interference, or both. Therefore I ran each distance test 5 times and averaged the speed. Below are some screenshots of the apps functionality.
In conclusion, within channel 6, the antenna works best in the 100mw range. Any speed over 100mw became sluggish and generally unresponsive. I am not sure if this is due to the antenna design or limits of the router. It may be that the router can only effectively radiate a given transmit power on one antenna. This has left some questions unanswered. I will build another antenna and run the test again with dual antennas. I suspect that is the solution to the slowdown at higher output.
The base unit consisted of the 6dbi omni antenna, a wrt54gs v6 loaded with ddwrt build v24SP2 (build 12548M).
The remote unit is an iPhone 3g running Ciscos GIST test app. It is the only wifi speed test app that runs without an internet connection. There seems to be some variance in the results reported by the app, either due to app/hardware integration, wifi interference, or both. Therefore I ran each distance test 5 times and averaged the speed. Below are some screenshots of the apps functionality.
Loading Screen
Main Screen
During test
Test results
To test the general usability of the antenna, I chose to test at varying transmit powers, starting with the routers default power, 71mw. Each subsequent power increase is shown in the charts below. The maximum transmit power for this particular router is 251mw. The selcted channel of operation is 6. This channel was selected by the Channel: [Auto] configuration on the wireless configuration page.
71mw
100mw
200mw
251mw
Wednesday, January 11, 2012
Collinear WiFi Antenna
Here is a quick omni-directional antenna that requires very little time and effort to create.
Materials:
Solid copper wire, service entry wire(u.s.) works best
1" dia. schedule 40 pvc endcaps
1" dia. schedule 200 pvc pipe
n-female chassis connector
Silicone sealant
Materials:
Solid copper wire, service entry wire(u.s.) works best
1" dia. schedule 40 pvc endcaps
1" dia. schedule 200 pvc pipe
n-female chassis connector
Silicone sealant
The loops are made at 60mm, 90mm, and 83mm. Each loop is 10mm in diameter.
A hole drilled in the bottom cap to accomodate the n-connector. A bit of Permatex grey gasket maker is the sealant and does a good job of holding the connector in place.
Links:
http://martybugs.net/wireless/collinear.cgi - martybug.net's compact 6dbi collinear antenna
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