SBIR Phase II: Voltage Tunable Micro-Ring Resonators: Low-Cost, Reconfigurable Optical Add-Drops

Information

  • NSF Award
  • 0646357
Owner
  • Award Id
    0646357
  • Award Effective Date
    4/1/2007 - 17 years ago
  • Award Expiration Date
    9/30/2010 - 14 years ago
  • Award Amount
    $ 578,052.00
  • Award Instrument
    Standard Grant

SBIR Phase II: Voltage Tunable Micro-Ring Resonators: Low-Cost, Reconfigurable Optical Add-Drops

This Small Business Innovation Research (SBIR) Phase II project entails the design and building of polarization independent, fiberdized, wavelength selective switches using patent pending EO-waveguide micro-ring technology developed and demonstrated as a result of work carried out under Phase I. The approach is electro-optic, rather than thermo-optic, and operates with negligible power consumption (< 30 microwatts per ring demonstrated in phase I), fast switching (< 100 microseconds demonstrated), larger index modulation (dn > 0.01 demonstrated, more possible) and importantly, will enable active polarization dependent loss (PDL) compensation. This will replace thermo-optically tuned ring resonators, which have provided only limited tunability (dn/dt =~ 1.5 x 10-5/oC), slower tuning times (> 3 milliseconds typical), high polarization dependency (no active PDL compensation possible), and are prohibitively power consumptive ( ~~ 0.5 Watts per ring).<br/><br/><br/>In the last century the low power transistor replaced the power hungry vacuum tube, thereby ushering in the age of integrated electronics. In a similar fashion, low-power LC-waveguides have the potential to replace high-power thermo-optics (providing a power savings of >10,000), thereby opening up applications and markets for integrated optics. In phase II we will transition our phase I feasibility demonstration into a fully functioning and packaged prototype. As computing power and bandwidth continue to grow (e.g., streaming media), low-cost electro-optical filtering and switching systems will be required to satisfy pending fiber-to-the-home and "last mile" deployment needs. Since 2002, United States and European deployment of long-haul dense wavelength division multiplexing (DWDM) systems have been almost entirely constructed from reconfigurable optical add-drop multiplexers (ROADM). A typical deployed system works by reading incoming optical signals and converting them to electrical signals, which can then be routed. Conversion back to optical is performed by an array of tunable lasers. This brute force method, while providing useful performance, is cost prohibitive for small network deployment. According to Infonetics, a leading market research firm, the ROADM-enabled equipment market size nearly reached $600 million in 2005, tripling earlier forecasts. Over all growth will be determined by affordability and reliability of ROADMs technology, especially within the metro and access space. The technology outlined in this proposal if successful will contribute a new and inherently agile all optical solution by reducing cost while maintaining performance and reliability. In addition to ROADMs, the voltage tunable micro-rings will enable a wide array of useful devices, ranging from spectral filters, to optical cross-connects, to routers, to name only a few.

  • Program Officer
    Juan E. Figueroa
  • Min Amd Letter Date
    3/19/2007 - 17 years ago
  • Max Amd Letter Date
    3/3/2010 - 14 years ago
  • ARRA Amount

Institutions

  • Name
    VESCENT PHOTONICS INCORPORATED
  • City
    DENVER
  • State
    CO
  • Country
    United States
  • Address
    4865 E. 41st Ave
  • Postal Code
    802164401
  • Phone Number
    3032966766

Investigators

  • First Name
    Scott
  • Last Name
    Davis
  • Email Address
    davis@vescentphotonics.com
  • Start Date
    3/19/2007 12:00:00 AM

FOA Information

  • Name
    Industrial Technology
  • Code
    308000