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Reconfigurable optical add drop multiplexer based on M*N ports of silicon substrate liquid crystal

An optical add-drop multiplexer and port technology, which is applied in wavelength division multiplexing systems, optical guides, optics, etc., can solve the problems of limiting the number of ports and the complexity of optical system design, and achieves flexible assignment and optimal spectrum flexibility. Excellent performance and function

Inactive Publication Date: 2013-09-04
MINZU UNIVERSITY OF CHINA
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Problems solved by technology

Although the ROADM technology of the LCoS-based Opto-VLSI processor chip has many significant advantages such as high channel count, spectral flexibility, dispersion adjustment and pulse shaping, and many other significant advantages, such as remote upgrades can be easily performed by software, but due to its Due to the complexity of optical system design itself, LCoS-based ROADMs in the world still use 1×N port design so far.
Restricted by basic elements such as the size of optical components such as lenses and optical path design, the adoption of this 1×N port technical solution greatly limits the number of ports that can be realized by an LCoS-based ROADM
At present, the highest level of commercialized ROADM (WSS) using this technology is only 1×23 ports, and there are great technical difficulties in further increasing the number of ports.

Method used

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  • Reconfigurable optical add drop multiplexer based on M*N ports of silicon substrate liquid crystal
  • Reconfigurable optical add drop multiplexer based on M*N ports of silicon substrate liquid crystal
  • Reconfigurable optical add drop multiplexer based on M*N ports of silicon substrate liquid crystal

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Embodiment Construction

[0023] Below in conjunction with accompanying drawing, through embodiment, further illustrate the present invention.

[0024] Such as figure 1 As shown, the reconfigurable optical add / drop multiplexer based on M×N ports of liquid crystal on silicon in this embodiment includes: a fiber collimator input array 1 with 8 ports, a spherical mirror 2, a volume grating 3, LCoS Opto-VLSI chip 4, lens 5 and fiber collimator output array 6 with 32 ports; Wherein, fiber collimator input array 1 and volume grating 3 are respectively located on the focal plane of spherical reflector 2; LCoS Opto- The VLSI chip 4 and the fiber collimator output array 6 are respectively located on the front and rear focal planes of the lens 5; the incident light is incident from the fiber collimator input array 1 with M ports, and is reflected by the spherical mirror 2 to the volume grating 3 ; Optical demultiplexing of the volume grating 3 forms 8 dispersion bars on the LCoS Opto-VLSI chip 4, and each wavel...

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Abstract

The invention discloses a reconfigurable optical add drop multiplexer (ROADM) based on M*N ports of silicon substrate liquid crystal. The ROADM comprises an optical fiber collimator input array with M ports, a spherical reflector, a body optical grating, an LCoS Opto-VLSI chip, a lens and an optical fiber collimator output array with N ports. The ROADM based on M*N ports of LCoS is realized. An optical system inside the equipment is unique in design, exquisite in structure, and good in function, uses the high-density scoring body grating as a dispersion element, adopts a method that phase gratings of different two-dimension orientations are loaded on an LCoS chip, and realizes efficient and flexible assignments of a large scale optical integrated chip on an incident wave length passage through changing the period of the grating and grating orientation modulation light beam phases. The ROADM has a high port number and optimized spectrum flexibility, has the functions of dispersion adjustments, pulse shaping and the like, and can conduct remote control and upgrade conveniently through software.

Description

technical field [0001] The invention relates to optical communication and optical network technology, in particular to a reconfigurable optical add-drop multiplexer based on silicon-based liquid crystal with M×N ports. Background technique [0002] Since the beginning of the 21st century, with the wide application of Dense Wavelength Division Multiplexing (DWDM) technology and the huge growth of optical fiber transmission capacity, Synchronous Digital Hierarchy (SDH) technology has long been overwhelmed, building a next-generation intelligent system based on wavelength switching The all-optical communication network has gradually become an important consensus in the field of communication research and industry. The all-optical communication network has many significant advantages such as low investment and operation cost, high reliability, low power consumption, strong scalability, flexible networking, intelligent and dynamic configuration of network resources, and transpare...

Claims

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Application Information

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IPC IPC(8): H04J14/02G02B6/293G02F1/13
Inventor 陈根祥陈笑张颖宋菲君吕敏王义全
Owner MINZU UNIVERSITY OF CHINA
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