Filter Bank Channelizers for Multi-Standard Software Defined Radio Receivers

Mitola, J. (2000). Software radio architecture, John Wiley.

Hentschel, T., Henker, M., & Fettweis, G. (1999). “The digital front-end of software radio terminals,” IEEE Person. Commun. Magazine, pp. 40–46.

Vinod, A. P., Premkumar, A. B., & Lai, E. M.-K. (2003). “An optimal Entropy coding scheme for efficient implementation of pulse shaping FIR filters in digital receivers,” in Proc. of IEEE International Symposium on Circuits and Systems, vol. 4, pp. 229–232, Bangkok, Thailand.

Vinod, A. P., & Lai, E. M-K. (2006). “Low Power and High-Speed implementation of FIR filters for software defined radio receivers,” IEEE Transactions on Wireless Communications, pp. 1669–1675, no. 5, vol. 7.

Hentschel, T. (2002). “Channelization for software defined base-stations.”. Annales des Telecommunications, 57(5-6), 386–420 ISSN 0003-4347.

Zabre, S., Palicot, J., Louet, Y., Moy, C., & Lereau, C. (2006). “Carrier per Carrier Analysis of SDR Signals Power Ratio”, SDR Forum Technical Conference, Orlando, US.

Phil Schniter: http://cnx.org/content/m10424/latest/ .

Kim, C., Shin, Y., Im, S., & Lee, W. (2000). “SDR-based digital channelizer/de-channelizer for multiple CDMA signals,” in Proceedings of IEEE Vehicular technology Conference, vol. 6, pp. 2862–2869.

Fung, C. Y., & Chan, S. C. (2002). “A multistage filter bank-based channelizer and its multiplier less realization”, in Proceedings of IEEE International Symposium on Circuits and Systems, vol.3, pp. 429–432.

Abu-Al-Saud, W. A., & Stuber, G. L. (2004). Efficient wideband channelizer for software radio systems using modulated PR filter banks. IEEE transactions on signal processing, 52(10), 2807–2820. doi: 10.1109/TSP.2004.834242 .

Lillington, J. (2003). “Comparison of wideband channelization architectures,” http://www.techonline.com/community/techgroup/dsp/tech_paper/33204 .

Vinod, A. P., Lai, E. M.-K., Premkumar, A. B., & Lau, C. T. (2003). “A reconfigurable multi-standard channelizer using QMF trees for software radio receivers,” in proceedings of 14th IEEE International Symposium on Personal, Indoor and Mobile Radio Communication, pp. 119–123.

Lillington, J. (2002). “TPFT–Tunable pipelined frequency transform,” RF Engines Ltd, Technical Report. http://www.rfel.com/whipapdat.asp .

Zangi, K., & Koilpillai, R. (1999). Software radio issues in cellular base stations. IEEE journal on selected areas in communications, 17(4), 561–573. doi: 10.1109/49.761036 .

Zangi, K., & Koilpillai, R. (1998). “Efficient filter bank channelizers for software radio receivers,” in Proceedings of International Conference on Communications, vol. 3, pp. 1566–1570.

Mahesh, R., & Vinod, A. P. (2008). Christophe Moy and Jacques Palicot, “A low complexity reconfigurable filter bank architecture for spectrum sensing in cognitive radios,” Proceedings of 3rd International Conference on Cognitive Radio Oriented Wireless Networks and Communications, Singapore.

Lim, Y. C. (1986). Frequency-response masking approach for the synthesis of sharp linear phase digital filters. IEEE transactions on circuits and systems, 33, 357–364. doi: 10.1109/TCS.1986.1085988 .

Delahaye, J. P., Leray, P., Moy, C., & Palicot, J. (2005). "Managing Dynamic Partial Reconfiguration on Actual Heterogeneous Platform", SDR Forum Technical Conference’05, Anaheim (USA).

Mahesh, R., & Vinod, A. P. (2008). “Coefficient decimation approach for realizing reconfigurable finite impulse response filters,” in Proceedings of IEEE International Symposium on Circuits and Systems, pp. 81–84, Seattle, USA.

Mahesh, R., & Vinod, A. P. (2008). “Reconfigurable frequency response masking filters for software radio channelization.”. IEEE Transactions on Circuits and Systems-II, 55(3), 274–278.