Estimation of the Fundamental Frequency of the Speech Signal Compressed by G.723.1 Algorithm Applying PCC Interpolation

ITU-T Rec. G.723.1: Dual-rate Speech Coder For Multimedia Communications Transmitting at 5.3 and 6.3 kbit/s, 1996.Search in Google Scholar

KARAPANTAZIS, S.—PAVLIDOU, F. : VoIP: A Comprehensive Survey on a Promising Technology, Computer Networks 53 (2009), 2050-2090.10.1016/j.comnet.2009.03.010Search in Google Scholar

REGUERA, V.—PALIZA, F.—GODOY, W.—FERNANDEZ, E. : On the Impact of Active Queue Management on VoIP Quality of Service, Computer Communications 31 (2008), 73-87.10.1016/j.comcom.2007.10.016Search in Google Scholar

KAOSAR, G.—SHELTAMI, T. : Voice Transmission over ad hoc Network Adapting Optimum Approaches to Maximize the Performance, Computer Communications 32 (2009), 634-639.10.1016/j.comcom.2008.11.028Search in Google Scholar

ZOLGHADR, A.—GOODARZI, E.—MOOSAVINEZHAD, M. : Real-Time Implementation of G.723.1 Speech Coder, Iranian Journal of Information Science and Technology 2 No. 1 (2004), 3-12.Search in Google Scholar

JOEN, B.—KANG, S.—BAEK, S.—SUNG, K. : Filtering of a Dissonant Frequency Based on Improved Fundamental Frequency Estimation for Speech Enhancement, IEICE Trans. Fundamentals E86-A No. 8 (Aug 2003), 2063-2064.Search in Google Scholar

MILIVOJEVIC, Z.—BALANESKOVIC, D. : Enhancement of the Perceptive Quality of the Noisy Speech Signal by Using of DFF-FBC Algorithm, Facta Universitatis, Ser.: Elec. Energ. 22 No. 3 (Dec 2009), 379=-392.10.2298/FUEE0903391MSearch in Google Scholar

QIU, L.—YANG, H.—KOH, S. : Fundamental Frequency Determination on Instantaneous Frequency Estimation, IEEE Signal Process. 44 (1995), 233-241.10.1016/0165-1684(95)00027-BSearch in Google Scholar

CHEVEIGNE, A.—KAWAHARA, H. : YIN, a Fundamental Frequency Estimator for Speech and Music, J. Acoust. Soc. Am. 111 No. 4 (April 2002), 1917-1930.10.1121/1.1458024Search in Google Scholar

MURAKAMI, T.—ISHIDA. Y. : Fundamental Frequency Estimation of Speech Signal Using MUSIC Algorithm, Acoust. Sci. & Tech. 22 (2001), 293-297.10.1250/ast.22.293Search in Google Scholar

KACHAA,—GRENEZ, F.—BENMAHAMMED, K. : TimeFrequency Analysis and Instantaneous Frequency Estimation Using Two-Sided Linear Prediction, IEEE Signal Processing 85 (2005), 491-503.10.1016/j.sigpro.2004.10.015Search in Google Scholar

KEYS, R. : Cubic Convolution Interpolation for Digital Image Processing, IEEE Trans. Acoust., Speech & Signal Process 29 (1981), 1153-1160.10.1109/TASSP.1981.1163711Search in Google Scholar

PARK, K.—SCHOWENGERDT, R. : Image Reconstruction by Parametric Cubic Convolution, Computer Vision, Graphics & Image Processing 23 (1983), 258-272.10.1016/0734-189X(83)90026-9Search in Google Scholar

REICHENBACH, S. : Two-Dimensional Cubic Convolution, IEEE Transactions on Image Processing 12 No. 8 (Aug 2003), 857-865.10.1109/TIP.2003.81424818237960Search in Google Scholar

PANG, H.—BAEK, S.—SUNG, K. : Improved Fundamental Frequency Estimation Using Parametric Cubic Convolution, IEICE Trans. Fundamentals E83-A (2000), 2747-2750.Search in Google Scholar

MILIVOJEVIC, Z.—MIRKOVIC, D.—MILIVOJEVIC, S. : An Estimate of Fundamental Frequency Using PCC Interpolation - Comparative Analysis, Information Technology and Control 35 (2006), 131-136.Search in Google Scholar

MILIVOJEVIC, Z.—MIRKOVIC, M. : Estimation of the Fundamental Frequency of the Speech Signal Modeled by the SYMPES Method, Int. J. Electron. Commun. (AEÜ) 63 (2009), 200-208.10.1016/j.aeue.2007.12.006Search in Google Scholar