Optical transport network

An optical transport network (OTN) is a digital wrapper that encapsulates frames of data, to allow multiple data sources to be sent on the same channel. This creates an optical virtual private network for each client signal. ITU-T defines an optical transport network as a set of optical network elements (ONE) connected by optical fiber links, able to provide functionality of transport, multiplexing, switching, management, supervision and survivability of optical channels carrying client signals. An ONE may re-time, re-Amplify, re-shape (3R) but it does not have to be 3R - it can be purely photonic. Unless connected by optical fibre links, it shall not be OTN. Mere functionality of switching, management, supervision shall not make it OTN, unless the signals are carried through optical fibre. OTN was designed to provide higher throughput (currently 400G) than its predecessor SONET/SDH, which stops at 40Gbit/s, per channel. ITU-T Recommendation G.709 is commonly called Optical Transport Network (OTN) (also called digital wrapper technology or optical channel wrapper). As of December 2009, OTN has standardized the following line rates. The OTUk (k=1/2/2e/3/3e2/4) is an information structure into which another information structure called ODUk (k=1/2/2e/3/3e2/4) is mapped. The ODUk signal is the server layer signal for client signals. The following ODUk information structures are defined in ITU-T Recommendation G.709 At a very high level, the typical signals processed by OTN equipment at the Optical Channel layer are: SONET/SDH Ethernet/FibreChannel Packets OTN A few of the key functions performed on these signals are: Protocol processing of all the signals:- Mapping and de-mapping of non-OTN signals into and out of OTN signals Multiplexing and de-multiplexing of OTN signals Forward error correction (FEC) on OTN signals Packet processing in conjunction with mapping/de-mapping of packet into and out of OTN signals The OTN signals at all data-rates have the same frame structure but the frame period reduces as the data-rate increases.

Programmable frequency-bin quantum states in a nano-engineered silicon device

Matteo Galli, Marco Clementi

Frequency-bin qubits get the best of time-bin and dual-rail encodings, but require external modulators and pulse shapers to build arbitrary states. Here, instead, the authors work directly on-chip by controlling the interference of biphoton amplitudes gene ...

NATURE PORTFOLIO2023

Measurement device or biochip including an optical microcavity

Nicolas Maxime André Descharmes, Raphaël Barbey

The present invention concerns a measurement device including at least one fluidic channel for providing at least one specimen in at least one liquid to at least an optical measurement region of the measurement device; and at least one optical structure co ...

2022

Programmable frequency-bin quantum states in a nano-engineered silicon device

Domain Imaging and Switching Dynamics in BaTiO3-Based Photonic Integrated Devices

Measurement device or biochip including an optical microcavity

Domain Imaging and Switching Dynamics in BaTiO3-Based Photonic Integrated Devices

Measurement device or biochip including an optical microcavity

Programmable frequency-bin quantum states in a nano-engineered silicon device