When working with fiber optics, you need some special tools to check fiber connections. Continuity checking makes certain the fibers are not broken and to trace a path of a fiber from one end to another through many connections. You can use a visible light “fiber optic tracer” or “pocket visual fault locator“. It looks like a flashlight or a pen-like instrument with a light bulb or LED source (sometimes laser) that mates to a fiber optic connector.
Attach the light source a fiber optic cable to test to the visual tracer and look at the other end to see the light transmitted through the core of the fiber. If there is no light at the end, go back to intermediate connections to find the bad section of the cable. Warning: Avoid looking at other fibers that could have signal in them, because active communications fibers can have so much invisible laser power in them that it can damage your eyes!
EDN design idea LED flasher checks fiber-optic strands allows you to verify fiber-optic strands. It uses two high-intensity flashing LEDs (red and yellow) that you can see at the far end of multi-mode fiber link (up to 1 km). Basically the circuit is LED flasher with some extra features (like auto power-off after 50 minutes). The fiber transmitter module is constructed simply: the T1-3/4 LEDs fit nicely into ST barrel connectors with some glue to hold them in place. If you need some other fiber connector type, you can use a patch cable to match the fiber connectors in your network.
Nice circuit idea but the circuit looks a little complicated for a LED flasher (three ICs). If you want to make something simpler, I think that you could also try the same idea with just one simple 555 timer based or other simple LED flasher circuit.
It is even possible to use a flash light for this application with suitable adapter or you can make your own light source if the commercial devices look too expensive. I own an a simple plastic adapter that connects a Mini Maglite to many common types of fiber optic connectors. It is an Universal adaptor for connectors with 2.5mm ferrules (works with FC/SC/ST connectors). It was given out for free at some fiber optics fair years ago and made from cheap plastic. It is not ideal, but it works and does the job many times.
There are also higher power versions of such tracers. A higher power version of the tracer uses red laser light that is powerful enough (typically few mW) to show breaks in fibers or high loss connectors. You can actually see the loss of the bright red light even through many yellow or orange simplex cable jackets. The red laser light can also be seen from the other end of the fiber cable that can be many kilometers long (ranges typically of up to 5km). This kind of gadget can be also used to optimize mechanical splices or pre-polished-splice type fiber optic connectors. Laser pointers are really cheap nowadays, but it is a bit hard to focus the laser beam from them well to the thin fiber.
Invisible infrared radiation normally carried in optical fiber can be made visible with a video camera. Many video cameras will detect IR radiation quite well, both black&white and color cameras (usually as RED but can be other color as well). The camera on your cell-phone can also usually work as a really cheap “laser” detector that nearly every tech carries. For example N73 cellular phone camera showed 1300 nm light as weak blue color on the fiber that has the signal in it. Because I can see IR remote control signals (850 – 950nm) on cellular phone camera, should 850 nm IR signals from fiber show as well.
The primary tools for serious fiber optics testing are a fiberscope for visual connector inspection and a power meter with laser source, a set of laser goggles (if you plan to work on single-mode or long-haul multimode fiber), an assortment of fiber patch cables, and a mini-maglite with fiber adapter (for simple continuity tests). There are many tutorials on the web showing how to use these tools, most from equipment vendors themselves, and some are even high quality video presentations.
More fiber optic testing ideas and information can be found at Fiber Optic Testing FAQ, LANshack.com Fiber Optic Testing, FOA Reference Guide To Fiber Optics Fiber Optic Testing, Measuring Power in Fiber Optics and Can You Build a Fiber Test Kit On a Budget?
Here is picture of most common fiber optic connector types (from Asara web site): LC, MU, MT-RJ, SC, ST and FC
69 Comments
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Tomi Engdahl says:
https://ask.slashdot.org/story/08/08/19/1354248/can-you-build-a-fiber-test-kit-on-a-budget
http://www.instructables.com/answers/If-i-hook-up-a-laser-pointer-to-a-fiber-optic-cabl/
Tomi Engdahl says:
Use your smartphone as a fiber optic tester
http://www.cablinginstall.com/articles/2010/09/use-your-smartphone-as-a-fiber-optic-tester.html
In most cases, the tool used as a fiber optic tester is either an optical-loss test set (OLTS), visual fault locator, or a higher-end device like an optical time-domain reflectometer (OTDR). But according to a “tech topic” recently posted on the Fiber Optic Association’s Web site, the smartphone in your pocket can act as a fiber optic tester, in a pinch and for certain functions.
you can use the camera on your smartphone to see the IR light emitted by the transmitter. To do so, follow these steps.
Turn on your phone’s camera function.
Point it to the remote control.
Push any button on the remote control.
The IR light will show on the camera’s screen.
Tomi Engdahl says:
Build a simple Fiber Optic tester
http://www.instructables.com/id/Build-a-simple-Fiber-Optic-tester/
This instructable will show you how to make a simple fiber optic cable tester for any LC style fiber.
Most testers I found were very expensive and measured db loss through the fiber. We just needed to know if it was intact or broken. I came up with this idea after looking at an LC fiber coupler and shoving a 5mm LED into it and finding out it was a perfect press fit! This tester works great for finding a broken fiber or if you have multiple fibers in an IT closet that no one has labeled (like that would ever happen…) identifying them.
Parts List:
Four high brightness RED LED’s
Four 330-Ohm resistors for current limiting
Two dual fiber couplers http://www.l-com.com/productfamily.aspx?id=528
Nine volt battery clip
Hot glue
¼” or 3/16” Heat Shrink Tubing
Comment from page:
I just tried 5mm High Brightness Leds and yes, this technique works very well for *multimode*, but with diminished intensity on singlemode cables at the other end. But for the few bucks, USB powered, this is an instructable that saves costs. Fiber Identifiers from China are about $30-40 in Laser 5mW but there are inherent dangers
Tomi Engdahl says:
The remarkable evolution of modern fiber-optic connector inspection probes
http://www.cablinginstall.com/articles/print/volume-25/issue-7/features/installation/the-remarkable-evolution-of-modern-fiber-optic-connector-inspection-probes.html?cmpid=enl_cim_cimdatacenternewsletter_2017-07-20&[email protected]&eid=293591077&bid=1816974
It’s mid-2017 and nearly everyone is aware that the information technology world encircling us is simultaneously getting both faster and denser. Bits of data are flying through optical network links at rates of 100 billion bits per second and higher, and the feature sizes in the network processor chips at the ends of these network links continue to shrink, as roughly and famously predicted by Gordon Moore. Multifiber connectors such as MPO, MT, and MXC are putting more and more less-than-human-hair diameter glass fibers into tighter spaces. With single MPO connectors increasingly using 16 fibers at 25 Gbits/sec per fiber, the asset value of these 400-Gbit/sec short-reach Ethernet links is exceedingly high, making data center infrastructure equipment failures due to connector contamination completely unacceptable to savvy management teams. Microscopic connector endface dirt and debris cause light reflections and attenuation – the enemies of optimal optical signal transmission.
Thankfully there now exist excellent quality and easy-to-use tools for inspecting and cleaning fiber endfaces. In particular, the brief history and evolution of fiber microscopes shows a compelling level of innovation, in terms of optics, electronics and software.
Tomi Engdahl says:
The article wrote:
“Invisible infrared radiation normally carried in optical fiber can be made visible with a video camera. Many video cameras will detect IR radiation quite well, both black&white and color cameras (usually as RED but can be other color as well). The camera on your cell-phone can also usually work as a really cheap “laser” detector that nearly every tech carries. For example N73 cellular phone camera showed 1300 nm light as weak blue color on the fiber that has the signal in it. Because I can see IR remote control signals (850 – 950nm) on cellular phone camera, should 850 nm IR signals from fiber show as well.”
Update:
Some newer smart phone cameras do not react to 1300 mn infrared light at all.
I tested with new Honor 8 phone, and it’s camera did not seem to react to 1300 nm signal at all.
In am not sure if that is intentional or unintentional feature.
Why the camera did not react could be caused by differences in optical filters and sensors.
Tomi Engdahl says:
Updated link to LED flasher checks fiber-optic strands article
http://www.edn.com/design/power-management/4312724/LED-flasher-checks-fiber-optic-strands
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Frank Rizzo says:
Thanks for the write up. Could you give me your thoughts on the Anritsu VFL650 Visual Fault Locator Would it be a good choice for me?
Tomi Engdahl says:
I have not used this locator myself.
Generally Anritsu is a reputable company known for good quality measurement tools.
I looked at the web page on the specifications of the device, and they look right on the line they should be.
If you are interested in the fiber fault locating, take a look at this post that has videos on this topic
https://www.epanorama.net/blog/2018/02/25/fiber-visual-fault-locator-videos/
Here are some tests of some cheap Chinese fiber optic testing tools I have (find both to be OK quality):
https://www.epanorama.net/blog/2017/03/21/cheap-fiber-optic-visual-fault-locator/
https://www.epanorama.net/blog/2017/03/29/fiber-optics-power-meter/
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What kind of problem you have and which specific Opera version do you use on what OS?
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