Abstract

We demonstrate for the first time WDM multi-path routing through a monolithically integrated InP/InGaAsP 8 × 8 space and wavelength selective cross-connect. Data channels are dynamically routed from four input ports to the same output port with excellent OSNR from 27.0 to 31.1 dB. Representative data paths are evaluated in terms of optical power penalty. Data routing experiments are performed using round-robin scheduling with nanosecond time-scale switching times.

© 2014 Optical Society of America

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  1. R. Hemenway, R. R. Grzybowski, C. Minkenberg, R. Luijten, “Optical-packet-switched interconnect for supercomputer applications,” J. Opt. Commun. Networking 3(12), 900–913 (2004).
  2. L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).
  3. N. Madamopoulos, V. Kaman, S. Yuan, O. Jerphagnon, R. J. Helkey, J. E. Bowers, “Applications of large-scale optical 3D MEMS switches in fiber-based broadband-access networks,” Photonic Network Commun. 19(1), 62–73 (2010).
    [CrossRef]
  4. G. Baxter, S. Frisken, D. Abakoumov, H. Zhou, I. Clarke, A. Bartos, and S. Poole, “Highly programmable wavelength selective switch based on liquid crystal on silicon switching elements,” in Proc. OFC (2006), OTuF2.
    [CrossRef]
  5. O. Tamm, C. Hermsmeyer, A. M. Rush, “Eco-sustainable system and network architecture for future transport network,” Bell Labs Tech. J. 14(4), 311–327 (2010).
    [CrossRef]
  6. S. Araki, Y. Suemura, N. Henmi, Y. Maeno, A. Tajima, S. Takahashi, “Highly scalable optoelectronics packet-switching fabric based on wavelength-division and space-division optical switch architecture for use in the photonic core node,” J. Opt. Commun. Networking 2(7), 213–228 (2003).
  7. R. Luijten and R. Grzybowski, “The OSMOSIS optical packet switch for supercomputers,” in Proc. OFC’09 (2009), OTuF3.
    [CrossRef]
  8. A. Rohit, R. Stabile, and K. A. Williams, “8×8 space and wavelength selective cross-connect for simultaneous dynamic multi-wavelength routing,” in Proc. OFC’13 (2013), OW1C.4.
  9. R. Stabile, A. Rohit, and K. A. Williams, “Dynamic multi-path WDM routing in a monolithically integrated 8x8 cross-connect,” in Proc. 39th European Conference on Optical Communication 2013 (2013), We.4.B.2.
  10. R. Stabile, A. Rohit, K. A. Williams, “Monolithically integrated 8×8 space and wavelength selective cross-connect,” J. Lightwave Technol. 32(2), 201–207 (2013).
  11. A. Rohit, J. Bolk, X. Leijtens, K. A. Williams, “Monolithic nanosecond-reconfigurable 4x4 space and wavelength selective cross-connect,” J. Lightwave Technol. 30(17), 2913–2921 (2012).
    [CrossRef]
  12. X. J. M. Leijtens, B. Kuhlow, and M. K. Smit, “Arrayed waveguide gratings,” in Wavelength Filters in Fiber Optics, H. Venghaus, ed. (Springer, 2006), pp. 125–187.
  13. C. D. Lee, W. Chen, Q. Wang, Y.-J. Chen, W. T. Beard, D. Stone, R. F. Smith, R. Mincher, I. R. Stewart, “The role of photomask resolution on the performance of arrayed-waveguide grating devices,” J. Lightwave Technol. 19(11), 1726–1733 (2001).
    [CrossRef]
  14. I. Moerman, P. P. van Daele, P. M. Demeester, “A review on fabrication technologies for the monolithic integration of tapers with III-V semiconductor devices,” IEEE J. Sel. Top. Quantum Electron. 3(6), 1308–1320 (1997).
    [CrossRef]
  15. E. Ciaramella, A. D’Errico, V. Donzella, “Using semiconductor-optical amplifiers with constant envelope WDM signals,” IEEE J. Quantum Electron. 44(5), 403–409 (2008).
    [CrossRef]

2013 (1)

2012 (1)

2010 (2)

N. Madamopoulos, V. Kaman, S. Yuan, O. Jerphagnon, R. J. Helkey, J. E. Bowers, “Applications of large-scale optical 3D MEMS switches in fiber-based broadband-access networks,” Photonic Network Commun. 19(1), 62–73 (2010).
[CrossRef]

O. Tamm, C. Hermsmeyer, A. M. Rush, “Eco-sustainable system and network architecture for future transport network,” Bell Labs Tech. J. 14(4), 311–327 (2010).
[CrossRef]

2008 (1)

E. Ciaramella, A. D’Errico, V. Donzella, “Using semiconductor-optical amplifiers with constant envelope WDM signals,” IEEE J. Quantum Electron. 44(5), 403–409 (2008).
[CrossRef]

2004 (1)

R. Hemenway, R. R. Grzybowski, C. Minkenberg, R. Luijten, “Optical-packet-switched interconnect for supercomputer applications,” J. Opt. Commun. Networking 3(12), 900–913 (2004).

2003 (2)

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

S. Araki, Y. Suemura, N. Henmi, Y. Maeno, A. Tajima, S. Takahashi, “Highly scalable optoelectronics packet-switching fabric based on wavelength-division and space-division optical switch architecture for use in the photonic core node,” J. Opt. Commun. Networking 2(7), 213–228 (2003).

2001 (1)

1997 (1)

I. Moerman, P. P. van Daele, P. M. Demeester, “A review on fabrication technologies for the monolithic integration of tapers with III-V semiconductor devices,” IEEE J. Sel. Top. Quantum Electron. 3(6), 1308–1320 (1997).
[CrossRef]

Araki, S.

S. Araki, Y. Suemura, N. Henmi, Y. Maeno, A. Tajima, S. Takahashi, “Highly scalable optoelectronics packet-switching fabric based on wavelength-division and space-division optical switch architecture for use in the photonic core node,” J. Opt. Commun. Networking 2(7), 213–228 (2003).

Beard, W. T.

Berde, B.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Bolk, J.

Bowers, J. E.

N. Madamopoulos, V. Kaman, S. Yuan, O. Jerphagnon, R. J. Helkey, J. E. Bowers, “Applications of large-scale optical 3D MEMS switches in fiber-based broadband-access networks,” Photonic Network Commun. 19(1), 62–73 (2010).
[CrossRef]

Callegati, F.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Cerroni, W.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Chen, W.

Chen, Y.-J.

Chiaroni, D.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Ciaramella, E.

E. Ciaramella, A. D’Errico, V. Donzella, “Using semiconductor-optical amplifiers with constant envelope WDM signals,” IEEE J. Quantum Electron. 44(5), 403–409 (2008).
[CrossRef]

D’Errico, A.

E. Ciaramella, A. D’Errico, V. Donzella, “Using semiconductor-optical amplifiers with constant envelope WDM signals,” IEEE J. Quantum Electron. 44(5), 403–409 (2008).
[CrossRef]

Dembeck, L.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Demeester, P. M.

I. Moerman, P. P. van Daele, P. M. Demeester, “A review on fabrication technologies for the monolithic integration of tapers with III-V semiconductor devices,” IEEE J. Sel. Top. Quantum Electron. 3(6), 1308–1320 (1997).
[CrossRef]

Develder, C.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Dittmann, L.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Donzella, V.

E. Ciaramella, A. D’Errico, V. Donzella, “Using semiconductor-optical amplifiers with constant envelope WDM signals,” IEEE J. Quantum Electron. 44(5), 403–409 (2008).
[CrossRef]

Eilenberger, G.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Grzybowski, R. R.

R. Hemenway, R. R. Grzybowski, C. Minkenberg, R. Luijten, “Optical-packet-switched interconnect for supercomputer applications,” J. Opt. Commun. Networking 3(12), 900–913 (2004).

Helkey, R. J.

N. Madamopoulos, V. Kaman, S. Yuan, O. Jerphagnon, R. J. Helkey, J. E. Bowers, “Applications of large-scale optical 3D MEMS switches in fiber-based broadband-access networks,” Photonic Network Commun. 19(1), 62–73 (2010).
[CrossRef]

Hemenway, R.

R. Hemenway, R. R. Grzybowski, C. Minkenberg, R. Luijten, “Optical-packet-switched interconnect for supercomputer applications,” J. Opt. Commun. Networking 3(12), 900–913 (2004).

Henmi, N.

S. Araki, Y. Suemura, N. Henmi, Y. Maeno, A. Tajima, S. Takahashi, “Highly scalable optoelectronics packet-switching fabric based on wavelength-division and space-division optical switch architecture for use in the photonic core node,” J. Opt. Commun. Networking 2(7), 213–228 (2003).

Hermsmeyer, C.

O. Tamm, C. Hermsmeyer, A. M. Rush, “Eco-sustainable system and network architecture for future transport network,” Bell Labs Tech. J. 14(4), 311–327 (2010).
[CrossRef]

Jerphagnon, O.

N. Madamopoulos, V. Kaman, S. Yuan, O. Jerphagnon, R. J. Helkey, J. E. Bowers, “Applications of large-scale optical 3D MEMS switches in fiber-based broadband-access networks,” Photonic Network Commun. 19(1), 62–73 (2010).
[CrossRef]

Kaman, V.

N. Madamopoulos, V. Kaman, S. Yuan, O. Jerphagnon, R. J. Helkey, J. E. Bowers, “Applications of large-scale optical 3D MEMS switches in fiber-based broadband-access networks,” Photonic Network Commun. 19(1), 62–73 (2010).
[CrossRef]

Koerber, W.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Le Sauze, N.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Lee, C. D.

Leijtens, X.

Leligou, N.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Luijten, R.

R. Hemenway, R. R. Grzybowski, C. Minkenberg, R. Luijten, “Optical-packet-switched interconnect for supercomputer applications,” J. Opt. Commun. Networking 3(12), 900–913 (2004).

Madamopoulos, N.

N. Madamopoulos, V. Kaman, S. Yuan, O. Jerphagnon, R. J. Helkey, J. E. Bowers, “Applications of large-scale optical 3D MEMS switches in fiber-based broadband-access networks,” Photonic Network Commun. 19(1), 62–73 (2010).
[CrossRef]

Maeno, Y.

S. Araki, Y. Suemura, N. Henmi, Y. Maeno, A. Tajima, S. Takahashi, “Highly scalable optoelectronics packet-switching fabric based on wavelength-division and space-division optical switch architecture for use in the photonic core node,” J. Opt. Commun. Networking 2(7), 213–228 (2003).

Mahony, M.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Mincher, R.

Minkenberg, C.

R. Hemenway, R. R. Grzybowski, C. Minkenberg, R. Luijten, “Optical-packet-switched interconnect for supercomputer applications,” J. Opt. Commun. Networking 3(12), 900–913 (2004).

Moerman, I.

I. Moerman, P. P. van Daele, P. M. Demeester, “A review on fabrication technologies for the monolithic integration of tapers with III-V semiconductor devices,” IEEE J. Sel. Top. Quantum Electron. 3(6), 1308–1320 (1997).
[CrossRef]

Mortensen, B.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Neri, F.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Pickavet, M.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Rafel, A.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Renaud, M.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Rohit, A.

Rush, A. M.

O. Tamm, C. Hermsmeyer, A. M. Rush, “Eco-sustainable system and network architecture for future transport network,” Bell Labs Tech. J. 14(4), 311–327 (2010).
[CrossRef]

Smith, R. F.

Solè-Pareta, J.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Stabile, R.

Stavdas, A.

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

Stewart, I. R.

Stone, D.

Suemura, Y.

S. Araki, Y. Suemura, N. Henmi, Y. Maeno, A. Tajima, S. Takahashi, “Highly scalable optoelectronics packet-switching fabric based on wavelength-division and space-division optical switch architecture for use in the photonic core node,” J. Opt. Commun. Networking 2(7), 213–228 (2003).

Tajima, A.

S. Araki, Y. Suemura, N. Henmi, Y. Maeno, A. Tajima, S. Takahashi, “Highly scalable optoelectronics packet-switching fabric based on wavelength-division and space-division optical switch architecture for use in the photonic core node,” J. Opt. Commun. Networking 2(7), 213–228 (2003).

Takahashi, S.

S. Araki, Y. Suemura, N. Henmi, Y. Maeno, A. Tajima, S. Takahashi, “Highly scalable optoelectronics packet-switching fabric based on wavelength-division and space-division optical switch architecture for use in the photonic core node,” J. Opt. Commun. Networking 2(7), 213–228 (2003).

Tamm, O.

O. Tamm, C. Hermsmeyer, A. M. Rush, “Eco-sustainable system and network architecture for future transport network,” Bell Labs Tech. J. 14(4), 311–327 (2010).
[CrossRef]

van Daele, P. P.

I. Moerman, P. P. van Daele, P. M. Demeester, “A review on fabrication technologies for the monolithic integration of tapers with III-V semiconductor devices,” IEEE J. Sel. Top. Quantum Electron. 3(6), 1308–1320 (1997).
[CrossRef]

Wang, Q.

Williams, K. A.

Yuan, S.

N. Madamopoulos, V. Kaman, S. Yuan, O. Jerphagnon, R. J. Helkey, J. E. Bowers, “Applications of large-scale optical 3D MEMS switches in fiber-based broadband-access networks,” Photonic Network Commun. 19(1), 62–73 (2010).
[CrossRef]

Bell Labs Tech. J. (1)

O. Tamm, C. Hermsmeyer, A. M. Rush, “Eco-sustainable system and network architecture for future transport network,” Bell Labs Tech. J. 14(4), 311–327 (2010).
[CrossRef]

IEEE J. Quantum Electron. (1)

E. Ciaramella, A. D’Errico, V. Donzella, “Using semiconductor-optical amplifiers with constant envelope WDM signals,” IEEE J. Quantum Electron. 44(5), 403–409 (2008).
[CrossRef]

IEEE J. Sel. Areas Commun. (1)

L. Dittmann, C. Develder, D. Chiaroni, F. Neri, F. Callegati, W. Koerber, A. Stavdas, M. Renaud, A. Rafel, J. Solè-Pareta, W. Cerroni, N. Leligou, L. Dembeck, B. Mortensen, M. Pickavet, N. Le Sauze, M. Mahony, B. Berde, G. Eilenberger, “The European IST project DAVID: a viable approach toward optical packet switching,” IEEE J. Sel. Areas Commun. 21(7), 1026–1040 (2003).

IEEE J. Sel. Top. Quantum Electron. (1)

I. Moerman, P. P. van Daele, P. M. Demeester, “A review on fabrication technologies for the monolithic integration of tapers with III-V semiconductor devices,” IEEE J. Sel. Top. Quantum Electron. 3(6), 1308–1320 (1997).
[CrossRef]

J. Lightwave Technol. (3)

J. Opt. Commun. Networking (2)

R. Hemenway, R. R. Grzybowski, C. Minkenberg, R. Luijten, “Optical-packet-switched interconnect for supercomputer applications,” J. Opt. Commun. Networking 3(12), 900–913 (2004).

S. Araki, Y. Suemura, N. Henmi, Y. Maeno, A. Tajima, S. Takahashi, “Highly scalable optoelectronics packet-switching fabric based on wavelength-division and space-division optical switch architecture for use in the photonic core node,” J. Opt. Commun. Networking 2(7), 213–228 (2003).

Photonic Network Commun. (1)

N. Madamopoulos, V. Kaman, S. Yuan, O. Jerphagnon, R. J. Helkey, J. E. Bowers, “Applications of large-scale optical 3D MEMS switches in fiber-based broadband-access networks,” Photonic Network Commun. 19(1), 62–73 (2010).
[CrossRef]

Other (5)

G. Baxter, S. Frisken, D. Abakoumov, H. Zhou, I. Clarke, A. Bartos, and S. Poole, “Highly programmable wavelength selective switch based on liquid crystal on silicon switching elements,” in Proc. OFC (2006), OTuF2.
[CrossRef]

R. Luijten and R. Grzybowski, “The OSMOSIS optical packet switch for supercomputers,” in Proc. OFC’09 (2009), OTuF3.
[CrossRef]

A. Rohit, R. Stabile, and K. A. Williams, “8×8 space and wavelength selective cross-connect for simultaneous dynamic multi-wavelength routing,” in Proc. OFC’13 (2013), OW1C.4.

R. Stabile, A. Rohit, and K. A. Williams, “Dynamic multi-path WDM routing in a monolithically integrated 8x8 cross-connect,” in Proc. 39th European Conference on Optical Communication 2013 (2013), We.4.B.2.

X. J. M. Leijtens, B. Kuhlow, and M. K. Smit, “Arrayed waveguide gratings,” in Wavelength Filters in Fiber Optics, H. Venghaus, ed. (Springer, 2006), pp. 125–187.

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Figures (5)

Fig. 1
Fig. 1

(a) Architecture and (b) photograph of the fabricated 8 × 8 cross-connect.

Fig. 2
Fig. 2

Test-bed for WDM control and assessment of the 8 × 8 cross-connect.

Fig. 3
Fig. 3

Spectra for 10Gb/s WDM at the input I0 (dashed) and at the output O0 (solid).

Fig. 4
Fig. 4

BER measurements for 10Gb/s WDM data from input I0 to output O0.

Fig. 5
Fig. 5

(a) Control signal for the cyclically enables B-SOAs for input port selection. (b) Time traces for all the wavelength of the 4 WDM input signals and (c) corresponding falling and rising time for λ1 at time slot 5→0.

Tables (2)

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Table 1 Broadband Port Select SOA Connections

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Table 2 Wavelength Mapping to Output O0

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