Explore jobs
Find specific jobs
Explore careers
Explore professions
Best companies
Explore companies
Optical Communication Products history
Optical Communication Products company history timeline
The TAT–9 submarine system used this technology in 1991; it was designed to operate near 1.55 μm at a bit rate of 560 Mb/s with a repeater spacing of about 80 km.
Also in 1991, photonic crystal fiber was developed.
The acronym WDM in this figure stands for wavelength-division multiplexing, a technique used after 1992 to transmit multiple channels at different wavelengths through the same fiber.
Fortunately, its adoption coincided with the advent and commercialization of the Internet around 1994.
Such WDM systems operating at bit rates of up to 80 Gbit/s were available commercially by the end of 1995.
The formation of the telecom bubble was the result of a rapid growth after 1995 in the telecommunication business.
In 1997, fiber cables capable of driving 300 KM at a speed of 40 Gb / s were produced.
In 1998, a submarine cable known as AC–1 was deployed across the Atlantic Ocean with a capacity of 80 Gb/s using the WDM technology.
The switch to the RZ format was made only after 1999 when it was found that its use helps in designing high-capacity lightwave systems.
Hecht J (1999) City of light: the story of fiber optics.
M2 Optics has been the market leader for designing and manufacturing customized optical fiber solutions for fiber optic network simulation, monitoring, and testing applications since 2001.
Way back in 2001, the open-source project Ronja provides instructions to build a low-cost transmitter-receiver pair capable of 10 Mbit/s communication over a 1.4 km range.
Fukuchi K, Kasamatsu T, Morie M, Ohhira R, Ito T, Sekiya K, Ogasahara D, Ono T (2001) 10.92-Tb/s (273 × 40-Gb/s) triple-band/ultra-dense WDM optical-repeatered transmission experiment.
It took nearly 5 years before the US economy recovered, only to crash again in August 2008 owing to the formation of another bubble, this time in the real-estate market.
Spectral efficiency as a function of SNR calculated numerically including the nonlinear effects over transmission distances ranging from 500 to 8000 km (after ; ©2010 IEEE)
Essiambre R-J, Kramer G, Winzer PJ, Foschini GJ, Goebel B (2010) Capacity limits of optical fiber networks.
The red star shows the fundamental capacity limit of optical fibers (after ; ©2012 IEEE)
By 2012, submarine systems with a total capacity of 5 Tbit/s for traffic in each direction became operational.
Takara H et al (2012) 1.01-Pb/s crosstalk-managed transmission with 91.4-b/s/Hz aggregated spectral efficiency.
Found this Hackaday link too: https://hackaday.com/2013/05/14/retrotechtacular-first-laser-transmitter-built-50-years-ago/
One interesting fact is that some people actually managed to “hack” it and make profits out of it (In french, but right click, translate to english!): https://blog.francetvinfo.fr/deja-vu/2017/10/10/le-piratage-du-systeme-chappe-ancetre-des-cyber-attaques-modernes.html
In September 2020, Facebook’s subsidiary PointView Tech launched the Athena satellite which is supposed to test a laser ground link.
One can only wonder what the future holds, especially if the potential of the SDM technology is realized by the year 2020.
Rate how well Optical Communication Products lives up to its initial vision.
Optical Communication Products jobs
Do you work at Optical Communication Products?
Does Optical Communication Products communicate its history to new hires?
Optical Communication Products history FAQs
Zippia gives an in-depth look into the details of Optical Communication Products, including salaries, political affiliations, employee data, and more, in order to inform job seekers about Optical Communication Products. The employee data is based on information from people who have self-reported their past or current employments at Optical Communication Products. The data on this page is also based on data sources collected from public and open data sources on the Internet and other locations, as well as proprietary data we licensed from other companies. Sources of data may include, but are not limited to, the BLS, company filings, estimates based on those filings, H1B filings, and other public and private datasets. While we have made attempts to ensure that the information displayed are correct, Zippia is not responsible for any errors or omissions or for the results obtained from the use of this information. None of the information on this page has been provided or approved by Optical Communication Products. The data presented on this page does not represent the view of Optical Communication Products and its employees or that of Zippia.
Optical Communication Products may also be known as or be related to OPTICAL COMMUNICATION PRODUCTS INC, Optical Communication Products and Optical Communication Products Inc.