Feb 25, 2004. Finding his online cantenna calculator rather intriguing, I set out to find the mathematical roots to his calculations. The result is my own cantenna calculator program, which I wrote in in C++, based on formulae obtained from the ARRL Antenna Book. It's available on my free software page; the archive.

Lincomatic's Homebrew WiFi Antennas Lincomatic's Homebrew (DIY) WiFi Antennas One of my latest obsessions is building DIY homebrew WiFi antennas. Heinz Beans Cantenna This is the first antenna I built. It's the ubiquitous circular waveguide 'cantenna': I obtained my can by going to my local 99 Cents Only store and buying a can of Heinz beans, which happened to be desired 3.25' diameter. The resultant methane gas produced from consuming the beans was used to power my soldering iron afterwards.

I will not go into the construction details, as they are very well documented on. Finding his online cantenna calculator rather intriguing, I set out to find the mathematical roots to his calculations.

The result is my own, which I wrote in in C++, based on formulae obtained from the Antenna Book. It's available on my; the archive contains both a Win32 console-mode EXE and full source code. In addition, Adam Lesser has kindly supplied a binary for OS-X. Greg Rehm's calculator fixes the operating frequency at Channel 6 (2437MHz), which is the center channel in the USA, giving the best tradeoff if you want to build a general purpose antenna which works across Channels 1-11. On the other hand, my calculator lets you tune your antenna for maximum gain on a specific channel; this is handy if you want to use your antenna set up a permanent point to point link. Let's go through an example using my calculator.

The syntax of the program is cantenna diameter centerchannel where diameter is in mm.

Below, you will find my cantenna build diary. A quick search of the web will show that there are many ways to create a cantenna and even more materials one can use. I will address each step of my build in detail and provide accompanying photos to help you complete your cantenna build. While there are many websites documenting a cantenna build, I felt that most either made assumptions as to an individuals technical/mechanical ability and/or left out important steps and info such as connector and pigtail types and how to test the performance of your finished cantenna.

To address these shortcomings, I will show you how to build a cantenna step by step and hopefully leave nothing out that you may have questions about. Let’s get ready tobuild! Tools and Supplies needed: • A metal can that is 3 to 6 inches in diameter • An N type Female Chassis-mount connector available locally from for $5.39 • A cordless drill with 5/8th inch drill bit or Dremel tool with various attachments • A pigtail to connect the cantenna to your router. You will need either a or a connector to N-male. Check your routers manual for the correct external antenna connector type. Start Deutsch 1 Test Download.

• Masking tape • Ruler For my cantenna build I used Rob Flickenger’s 36 oz. Coffee can design for inspiration and reference over Andrew Clapp’s Pringles can design. The reason behind this was simply the potential for greater performance. After days of researching various cantenna designs based off of different can diameters and lengths, I chose the coffee can route due to its potential for greater dbi increase, ease of construction and the non-ridged surface inside of the can. Your choice of can is perhaps the most important design consideration you will make when building a cantenna, right after placement of the n-connector. Can Selection: Pretty much any can between 3 and 6 inches will do.

Beyond that there is a considerable roll off in performance. Coffee can I chose was an MJB brand and had a diameter of 6.1 inches exact.

Reports from the web have found that Nally’s Big Chunk Chili cans work good as does 4 inch stove pipe. Whatever can size or type you choose, try to avoid the ridged cans if at all possible as I have read that these can cause the signal to scatter. I am not sure how accurate this anecdotal info is but better safe than sorry. Your cantenna also needs to be made of a metal material, not plastic or glass. Can types Drilling the hole and installing the n-connector: After choosing an appropriate can. We need to make a hole for the n-connector that the pigtail attaches to from your router/wireless access point. The n-connector I had required that a.60 inch hole be drilled in the side of my can.

Where we drill this hole vertically is critical as it helps determines wavelength. In order for your cantenna to send or receive signals in the 2.4 ghz range that wireless B and G uses, you will need to input the diameter of your can into a free calculator such as this. This calculator takes the diameter of your can and tells you where to drill the hole vertically for your n-connector. Mine was 1.38 inches from the bottom of the can.

I simply used a piece of masking tape and placed a mark at the exact spot indicated. I then used a cordless drill to make a starter hole.

Following that, I used a half inch drill bit to finish the hole for the n-connector. I ended up needing to used a Dremel tool to smooth out the burrs and enlarge the hole slightly for my n-connector to fit nice and tight. Cantenna with hole drilled Here is a easy to use, freeware program for Winxp, Vista and Win7 that will calculate the proper dimensions for a cantenna.

After drilling the hole in the side of the can at the correct place, all you need to do is place the n-connector into the can and attach the pigtail to your router/wireless access point. Easy wasn’t it?

Next, we will look at connector types so that you know which types go to your router. Selecting the right connector: Below is a typical N-connector.

View of rear threads To connect your cantenna to your wireless router/access point you will need a. A pigtail is a low-loss cable that has a N female connector on one end and either a reverse polarity SMA or reverse polarity TNC connector on the other. DLink, Belkin and Netgear have standardized on RP-SMA connectors for their detachable antennas. Cisco, Linksys and Buffalo most commonly use RP-TNC connectors for their removable antennas.

You will need to purchase a pigtail with the proper connector for your wireless router. Simply remove the detachable antenna from your wireless router/access point and match it up with one of the examples below to know which connector type you have. On a final note, when purchasing a pigtail try to purchase as short of length as you need and look for a rated cable to assure minimal signal loss. LMR-200 cable losses.5 dbi every meter of length.

If you will be mounting your cantenna outdoors, be sure to purchase a cable with a surge arrestor to protect from lighten strikes. The cost is only a few dollars more for the increase in safety. Reverse Polarity TNC connector from a Linksys wireless access point Testing your cantenna’s performance: Now that you have built your cantenna and have connected it to your wireless router/access point you probably want to test its performance. Simply remove your stock antenna and connect the other end of the pigtail to your router. I used for measuring signal strength and signal to noise ratio and it worked very well. You can also use the software that came with your router.

Simply look for the dbi and signal to noise ratio readings. Netstumbler provides a nice graphical representation of these values that makes testing a breeze. Netstumbler screenshot showing cantenna testing I hope you have a great experience building and testing a cantenna. It is a lot of fun and a very worthwhile project. My cantenna has been put to use beaming my wireless signal through a concrete floor that a normal router can not penetrate. Not bad for a $20.00 project! Add-ons for your cantenna: Now that you have your cantenna built and tested, what else can you do to make it even more cool and usable?

How about attaching a pistol grip handle for wardriving/bluesnarfing or mounting it to an adjustable base? You could also attach a funnel to increase its output. A meager 3 db increase equates to a doubling of signal strength! The sky is the limit, use your imagination. Below are a few photos of cantennas from around the web that have been upgraded and made more usable. Hi, I saw your web page, and started to build some large-size antennas on my own now. I am adding a link to my website, where you can see some first photos.

The device you are seeing there, is the container. It is huge – it can take a helical antenna of 1.30 m length in its main fuselage. It is modular, and can carry a wide range of antennas. The regular “armament” is thought to be two YAGI antennas (each 25 dBi) at the main fuselage in front, two cantennas (each maybe 10 dBi) inside the back part of the main fuselage, and up to three helical antennas (each 15 to 30 dBi) around the center piece (top, left, right).

It is 1.35 m long, 1.25 m tall, and 0.25 cm wide. Connectable to any USB port. Inside the central part is a bay with the USB WiFi adapter (closer to the antennas prevents decibel loss with the SMA cables), and SMA splitters. The addition of antennas gives a better signal strength. Here’s the link.

If you wish to use the photos on your website, feel free to do so. Just mention my name, thanks.

About Cantenna Calculator The resource is currently listed in dxzone.com in 2 categories. The main category is 2.4 GHz Wifi antennas that is about 2.4 GHz Wifi antennas. This link is listed in our web site directory since Wednesday Sep 19 2012, and till today 'Cantenna Calculator' has been followed for a total of 3731 times. So far received 109 votes for a total score of 5.42/10 You may find other interesting sites similar to this one, under the following categories: • - Antenna design calculators • - 2.4 GHz Wifi antennas.