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Though 40- and 80-Gbit/sec transmission using all-optical 3R Regenerators has been done in the past, OKI believes its trial is the first in the world using 160-Gbit/sec optical signal regenerators.  Âīy evaluating the performance of all-optical 3R regenerators while changing the regenerator spacing, OKI achieved a maximum regenerator spacing of 380 km, which is equivalent to transmitting at 160 Gbits/sec between Tokyo and Osaka with just one optical 3R regenerator. In the field trial using this equipment, OKI says it proved, in principal, that there were hardly any limits to transmission distance. OKI's newly developed PMDC adopts a design to fully leverage the optical 3R Regenerator. Because the faster the transmission speed, the more sensitive it is to such changes, a PMDC is indispensable for transmission systems operating at over 40 Gbits/sec. OKI says it also developed a Polarization Mode Dispersion Compensator (PMDC) that adaptively mitigates the impact of the changes in transmission line characteristics that are unique to optical fiber. Polarization mode dispersion is a phenomenon whereby wave distortion increases in an oval-shaped fiber core. The dispersion value changes depending on the temperature or transmission environment. With these advances, in theory, it is possible to achieve signal processing speeds of over 200 Gbits/sec. To do this, OKI developed an all-optical 3R regenerator, which uses a specialized optical-repeater technology with functions for re-amplification, re-shaping to remove optical signal wave distortion, and re-timing to avoid timing jitter accumulation. As a result, technologies that efficiently regenerate optical signals without converting them to electric signals are required in order to achieve a transmission speed of over 100 Gbits/sec, explain OKI representatives. However, the speed for batch signal processing is currently limited to 40 Gbits/sec. They are then converted back into optical signals and re-transmitted after the signal processing is completed. To achieve longer distance, optical signals are converted into electric signals before the transmission limit is reached. Because signal distortion and timing jitter accumulate during transmission, the faster the speed of transmission, the shorter the transmission range. In a conventional optical communication system, an optical amplifier is placed every 50 to 100 km to compensate for propagation loss.
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OKI will analyze the findings from the field trial and develop a commercial-level 160-Gbit/sec optical 3R regenerator." "160-Gbit/sec data transmission uses an ultra high-speed optical communication technology that is expected to be commercialized in 2010 or after. "This amount of data at this speed can be sent over distances greater than the length of Japan, which is about 3,000 km and, in fact, to the other side of the planet, which is about 20,000 km," he adds. "This result proves that we can now transmit data at 160 Gbits/sec, a speed equivalent to transmitting four movies, approximately 8 hours of data, in a single second," contends Takeshi Kamijo, general manager of the corporate R&D center at OKI. The research that led to OKI's achievement was conducted as part of the "Research and Development on ? Utility Technology," under the auspices of NICT. OKI used an optical test-bed provided by the National Institute of Information and Communications Technology (NICT)'s Japan Gigabit Network II (JGN II). (search for OKI) today announced what it claims is the world's first all optically regenerated transmission of 160 Gbits/sec on a single wavelength.