For Immediate Release - July 17, 2012
Siemon Labs' testing highlights performance risks of low-cost generic fibre optic assemblies
Siemon, a leading global manufacturer of IT network cabling and infrastructure systems, has released the results of comprehensive benchmark testing on optical fibre assemblies and warns of significant risks in specifying low-cost generic fibre jumpers over well-known, quality global brands.
Performed by Siemon Labs, these tests included randomly selected fibre jumpers from five well-known global brands, including Siemon, as well as jumpers from four low-cost generic assembly houses. The results clearly showed a significant performance gap between the global brands and the generic products, with a significant number of generic assemblies failing to meet minimum standards requirements across a range of performance-critical parameters. To review the full test results, download the new Siemon whitepaper "A Closer Look at Fiber Optic Cable Assemblies" at www.siemon.com/go/fiberjumper.
In terms of optical performance, Siemon Labs tested all assemblies for Insertion Loss (IL) and Return Loss (RL). Whilst all assemblies passed minimum IL requirements, three out of four generic suppliers had RL failures. "The optical performance results show that substandard assemblies continue to find their way into otherwise high-performance networks," explained Robert Carlson, Siemon's vice president of global marketing. "Whilst you may only field-test for IL, substandard RL performance will negatively impact transmission and degrade overall channel performance - even if the assembly passes IL field-testing."
In addition to optical performance, the tests also covered standards-based requirements for fibre end-face geometry; specifically fibre end-face radius of curvature, apex offset and fibre height. These three critical mechanical characteristics of the fibre end-face control the alignment and actual physical contact between fibre cores to ensure reliable signal transmission. Whilst only one global supplier assembly experienced an end-face failure, none of the generic assemblies passed all three minimum requirements. The generic brands fared even worse against Siemon's more rigorous internal performance requirements.
Standards-based visual inspections were also performed, and the results highlight the potential performance impact of contamination and fibre core defects. Fibre core fractures and contamination on ferrules, alignment sleeves or dust caps degrade IL and RL performance, making test results completely unpredictable and causing unnecessary problems such as wasted time in trouble-shooting test failures and false passes that cause non-compliant channel performance on 'day two'. With the exception of Siemon assemblies, all samples exhibited some form of contamination and failed visual inspection. After proper cleaning, 75 per cent passed with some defects, and 25 per cent failed even after cleaning.
Whilst lab tests on optical parameters and connection attributes provide a very strong indicator of an assembly's overall quality and performance, it does not guarantee that the assembly will survive in the real world. Siemon Labs performed mechanical reliability testing against standards requirements for cable pull, flex, torsion and retention; parameters designed to ensure that assemblies can endure the mechanical stresses of installation and maintenance in a real-world network and still deliver reliable, long-term performance. These tests once again showed a large quality gap, with all global brands indicating 100 per cent pass results, whilst not a single low-cost supplier made it through without significant failures.
The full results of the Siemon Labs' testing highlights the significant risks in specifying low-cost generic fibre jumpers over well-known, quality global brands as well as the dangers in considering a passing IL field test as an indication of overall assembly performance. Sub-standard RL, non-compliant end-face geometry and poor mechanical reliability dramatically increase the likelihood that generic assemblies will degrade overall network performance.
"Users make significant investments in fibre network equipment for its ability to deliver high-bandwidth performance," explained Carlson. "And that performance is choked by cheap, sub-standard jumpers."
Adding an example, Carlson continued, "A 24-port, 10GbE fibre switch costs about £6500. If an OM3 LC fibre jumper costs about £10 from a generic supplier and £15 from a high-quality global brand, you'd save a total of about £120 if you used generic jumpers with that switch. Is £120 in jumper savings worth jeopardising the performance of a £6500 piece of equipment? If you factor in potential downtime, troubleshooting and replacement jumper costs, using anything less than the highest quality jumpers makes no sense.
The full results of Siemon Labs' fibre assembly testing are included in the new Siemon whitepaper entitled: "A Closer Look at Fibre Optic Cable Assemblies", available online at http://www.siemon.com/go/fiberjumper
For a quick and easy overview of Siemon's fibre assembly testing, see the infographic on Siemon's Network Infrastructure blog: http://blog.siemon.com/infrastructure/?p=664
- About Siemon
- Established in 1903, Siemon is an industry leader specialising in the manufacture and innovation of high quality, high-performance network cabling solutions. Headquartered in Connecticut, USA, with global offices and partners throughout the world, Siemon offers the most comprehensive suite of copper (unshielded and shielded twisted-pair) and fibre cabling systems available. With over 400 patents specific to structured cabling, Siemon Labs invests heavily in R&D and development of industry standards, underlining the company's long-term commitment to its customers and the industry.
- For further information or supporting picture please contact:
- Debbie Ireland, Marketing Consultant
- 07728 016633