Free Access
Issue
Ann. For. Sci.
Volume 63, Number 1, January-February 2006
Page(s) 73 - 81
DOI https://doi.org/10.1051/forest:2005099
Published online 28 January 2006
References of Ann. For. Sci. 63 73-81
  1. Bismarck G., Sharpness as an attribute of the timbre of steady sounds, Acustica J. 30 (1974) 146-158.
  2. Bordonné P.A., Module Dynamique et Frottement Intérieur dans le Bois - Mesures sur Poutres Flottantes en Vibrations Naturelles, Ph.D. thesis, Institut National Polytechnique de Lorraine, 1989.
  3. Brancheriau L., Expertise mécanique des sciages par analyses des vibrations dans le domaine acoustique, Ph.D. thesis, École supérieure de mécanique de Marseille, 2002.
  4. Brancheriau L., Baillères H., Natural vibration analysis of clear wooden beams: a theoretical review, Wood Sci. Technol. J. 36 (2002) 347-365.
  5. Bucur V., Acoustics of wood, CRC Press, 1995, pp. 135-143.
  6. Grey J.M., Multidimensional perceptual scaling of musical timbres, J. Acous. Soc. Am. 61 (1977) 1270-1277.
  7. Holz D., Tropical hardwoods used in musical instruments - can we substitute them by temperate zone species? Holzforschung J. 50 (1996) 121-129.
  8. Kollmann F.F.P., Côté W.A.J., Principles of wood science and technology, Springer-Verlag, Berlin, 1968, pp. 274-281.
  9. Martinis R., Valentina Socco L., Sambuelli L., Nicolotti G., Schmitt O., Bucur V., Tomographie ultrasonore pour les arbres sur pied, Ann. For. Sci. 61 (2004) 157-162 [EDP Sciences] [CrossRef].
  10. Matsunaga M., Sugiyama M., Minato K., Norimoto M., Physical and mechanical properties required for violin bow materials, Holzforschung J. 50 (1996) 511-517.
  11. Matsunaga M., Minato K., Physical and mechanical properties required for violin bow materials. II: Comparison of the processing properties and durability between pernambuco and substitutable wood species, J. Wood Sci. 44 (1998) 142-146 [CrossRef].
  12. Matsunaga M., Minato K., Nakatsubo F., Vibrational property changes of spruce wood by impregnating with water-soluble extractives of pernambuco (Guilandina echinata Spreng.), J. Wood Sci. 45 (1999) 470-474 [CrossRef].
  13. McAdams S., Winsberg S., Donnadieu S., De Soete G., Krimphoff J., Perceptual scaling of synthesized musical timbres: common dimensions, specificities and latent subject classes, Psychol. Res. J. 58 (1995) 177-192.
  14. Obataya E., Umezawa T., Nakatsubo F., Norimoto M., The effects of water soluble extractives on the acoustic properties of reed (Arundo donax L.), Holzforschung J. 53 (1999) 63-67.
  15. Ono T., Norimoto M., Study on Young's modulus and internal friction of wood in relation to the evaluation of wood for musical instruments, Jap. J. Appl. Phys. 22 (1983) 611-614 [CrossRef].
  16. Ouis D., Vibrational and acoustical experiments on logs of spruce, Wood Sci. Technol. J. 33 (1999) 151-184.
  17. Ouis D., Detection of decay in logs through measuring the dampening of bending vibrations by means of a room acoustical technique, Wood Sci. Technol. J. 34 (2000) 221-236.
  18. Ouis D., On the frequency dependence of the modulus of elasticity of wood, Wood Sci. Technol. J. 36 (2002) 335-346.
  19. Pellerin R.F., Vibrational approach to nondestructive testing of structural lumber, For. Prod. J. 15 (1965) 93-101.
  20. Steiglitz K., McBride L.E., A Technique for the Identification of Linear Systems, IEEE Trans. Automat. Contr. 10 (1965) 461-464 [CrossRef].
  21. Sugiyama M., Matsunaga M., Minato K., Norimoto M., Physical and mechanical properties of pernambuco (Guilandina echinata Spreng.) used for violin bows, Mokuzai Gakkaishi 40 (1994) 905-910.
  22. Tenenhaus M., La Régression PLS : Théorie et Pratique, Technip, Paris, 1998.