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All issues Volume 60 / No 6 (September 2003) Ann. For. Sci., 60 6 (2003) 527-537 References
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Issue
Ann. For. Sci.
Volume 60, Number 6, September 2003
Page(s) 527 - 537
DOI https://doi.org/10.1051/forest:2003046
References of  Ann. For. Sci. 60 (2003) 527-537
  1. Abellanas B., Pardos J.A., Seasonal development of female strobilus of stone pine (Pinus pinea L.), Ann. Sci. For. 46 (1989) 51-53.
  2. Alía R., Gómez A., Agúndez M.D., Bueno M.A., Notivol E., Levels of genetic differentiation in Pinus halepensis Mill. in Spain using quantitative traits, isozymes, RAPDs and cp-microsatellites, in: Müller-Starck G., Schubert R. (Eds.): Genetic Response of Forest Systems to Changing Environmental Conditions, Vol. 70, Forestry Sciences, Kluwer Academic Publishers, Dordrecht, 2001, pp. 151-160.
  3. Baldini E., Arboricultura general, Mundi-Prensa, Madrid, 1992.
  4. Barthélémy D., Blaise F., Fourcaud T., Nicolini E., Modélisation et simulation de l'architecture des arbres : Bilan et perspectives, Rev. For. Fr. XLVII n° sp. (1995) 71-96.
  5. Bouchon J., Présentation de l'Action d'Intervention sur Programme sur l'architecture des arbres fruitiers et forestiers, in: Bouchon J. (Ed.), Architecture des arbres fruitiers et forestiers, Montpellier (France), 23-25 novembre 1993, Les Colloques n° 74, INRA Editions, Paris, 1995, pp. 7-16.
  6. Bouchon J., Houllier F., Une brève histoire de la modélisation de la production des peuplements forestiers : place des méthodes architecturales, in: Bouchon J. (Ed.), Architecture des arbres fruitiers et forestiers. Montpellier (France), 23-25 novembre 1993, Les Colloques n° 74, INRA éditions, Paris, 1995, pp. 17-25.
  7. Burczyk J., Chalupka W., Flowering and cone production variability and its effects on parental balance in a Scots pine clonal seed orchard, Ann. Sci. For. 54 (1997) 129-144.
  8. Cannell M.G.R., Thompson S., Lines R., An analysis of inherent differences in shoot growth within some northern temperate conifers, in: Cannell M.G.R., Last F.T. (Eds.), Tree physiology and yield improvement, Academic Press, New York, 1976, pp. 173-205.
  9. Cara J.A. de, Gallego T., Gómez M., Agrometeorología 1997/98, in: Calendario meteorológico 1999, Instituto Nacional de Meteorología, Madrid, 1998, pp. 113-127.
  10. Caraglio Y., Barthélémy D., Revue critique des termes relatifs à la croissance et à la ramification des tiges des végétaux vasculaires, in: Bouchon J., de Reffye Ph., Barthélémy D. (Eds.), Modélisation et simulation de l'architecture des végétaux, INRA, Paris, 1997, pp. 11-87.
  11. Catalán G., Current Situation and Prospects of the Stonepine as Nut Producer, FAO - Nucis-Newsletter 7 (1998) 28-32.
  12. Chmielewski F.M., Rötzer Th., Response of tree phenology to climate change across Europe, Agric. For. Meteorol. 108 (2001) 101-112  [CROSSREF link].
  13. Chuine I., Cour P., Rousseau D.D., Selecting models to predict the timing of flowering of temperate trees: implications for tree phenology modelling, Plant Cell Environ. 22 (1999) 1-13  [CROSSREF link].
  14. Chuine I., Aitken S.N., Ying C.C., Temperature thresholds of shoot elongation in provenance of Pinus contorta, Can. J. For. Res. 31 (2001) 1444-1455  [CROSSREF link].
  15. Chung M.S., Flowering Characteristics of Pinus sylvestris L. with Special Emphasis on the Reproductive Adaptation to Local Temperature Factor, Acta Forestalia Fennica 169 (1981) 5-68.
  16. Coudurier T., Barthélémy D., Chanson B., Courdier F., Loup C., Modélisation de l'architecture du Pin maritime Pinus pinaster Ait. (Pinaceae) : Premiers résultats, in: Bouchon J. (Ed.), Architecture des arbres fruitiers et forestiers. Montpellier (France), 23-25 novembre 1993, Les Colloques n° 74, INRA Éditions, Paris, 1995, pp. 305-321.
  17. Cremer K.W., Relations between reproductive growth and vegetative growth of Pinus radiata, For. Ecol. Manage. 52 (1992) 179-199.
  18. Desprez-Loustau M.L., Dupuis F., Variation in the phenology of shoot elongation between geographic provenances of maritime pine (Pinus pinaster) - implications for the synchrony with phenology of the twisting rust fungus Melampsora pinitorca, Ann. Sci. For. 51 (1994) 553-568.
  19. Draper N.R., Smith H., Applied Regression Analysis, John Wiley & Sons, New York, 1980.
  20. Gordo J., Mutke S., Gil L., La producción de piña de Pinus pinea L. en los montes públicos de la provincia de Valladolid. in: Primer Simposio del Pino Piñonero (Pinus pinea L.) (II) Valladolid, 2000, pp. 269-278.
  21. Granier C., Tardieu F., Spatial and Temporal Analyses of Expansion and Cell Cycle in Sunflower Leaves, Plant Physiol. 116 (1998) 991-1001  [PUBMED link].
  22. Granier C., Tardieu F., Is thermal time adequate for expressing the effects of temperature on sunflower leaf development? Plant Cell Environ. 21 (1998) 695-703  [CROSSREF link].
  23. Guyon J.P., Influence du climat sur l'expression des composantes de la croissance en hauteur chez le pin noir d'Autriche (Pinus nigra Arn. ssp. nigricans), Ann. Sci. For. 43 (1986) 207-226.
  24. Hänninen H., Modelling bud dormancy release in trees from cool and temperate regions, Acta Forestalia Fennica 213 (1990) 1-47.
  25. Hänninen H., Effects of climatic change on trees from cool and temperate regions: an ecophysiological approach to modelling of bud burst phenology, Can. J. Bot. 73 (1995) 183-199.
  26. Isik K., Seasonal course of height and needle growth in Pinus nigra grown in summer-dry Central Anatolia, For. Ecol. Manage. 35 (1990) 261-270.
  27. Kramer K., Leionen I., Loustau D., The importance of phenology for the evaluation of impact of climate change on growth of boreal, temperate and Mediterranean forest ecosystems: an overview, Int. J. Biometereol. 44 (2000) 67-75.
  28. Kremer A., Component Analysis of Height Growth, Compensation between Components and Seasonal Stability of Shoot Elongation in Maritime Pine (Pinus pinaster Ait.), in: Proceedings of IUFRO Conference on Crop Physiology of Forest Trees, Helsinki, 1984.
  29. Kremer A., Décomposition de la croissance en hauteur du pin maritime (Pinus pinaster Ait.) : architecture génétique et application à la sélection précoce, Thèse de Doctorat, Université de Paris XI, Centre d'Orsay, 1992.
  30. Kurth W., Die Simulation der Baumarchitektur mit Wachstumsgrammatiken. Stochastische, sensitive L-Systeme als formale Basis für dynamische, morphologische Modelle der Verzweigungsstruktur von Gehölzen. Wissenschaftlicher Verlag Berlin, Berlin, 1999.
  31. Kurth W., Sloboda B., Growth grammars simulating trees - an extension of L-systems incorporating local variables and sensitivity, Silva Fenn. 31 (1997) 285-295.
  32. Lanner R.M., Patterns of shoot development in Pinus and their relationship to growth potential, in: Cannel M.G.R., Last F.T. (Eds.), Tree physiology and yield improvement, Academic Press, New York, 1976.
  33. Le Roux X., Sinoquet H., Foreword 2nd International Workshop of Functional-Structural Tree Models, Ann. For. Sci. 57 (2000) 393-394.
  34. Loup C., La variabilité architecturale chez le Pin d'Alep Pinus halepensis Mill., in: Architecture, structure, mécanique de l'arbre, Sixième Séminaire Interne, Laboratoire de mécanique et de génie civil, Université de Montpellier II, 1993, pp 4-16.
  35. Matziris D.I., Genetic Variation in the Phenology of Flowering in Black Pine, Silvae Genet. 43 (1994) 321-328.
  36. Meredieu C., Croissance et branchaison du Pin laricio (Pinus nigra Arnold ssp. laricio (Poiret) Maire) : Élaboration et évaluation d'un système de modèles pur la prévision de caractéristiques des arbres et du bois, thèse de Doctorat, Université Claude Bernard-Lyon I, 1998.
  37. Mutke S., Fenología de Pinus pinea L. en un Banco Clonal (Valladolid), MSc dissertation, Universidad de Valladolid, 2000.
  38. Mutke S., Díaz-Balteiro L., Gordo J., Análisis comparativo de la rentabilidad comercial privada de plantaciones de Pinus pinea L. en tierras agrarias de la provincia de Valladolid, Investig. Agrar. Sist. Recur. For. 9 (2000) 269-303.
  39. Mutke S., Gordo J., Gil L., The Stone Pine (Pinus pinea L.) Breeding Programme In Castile-Leon (Central Spain), FAO-CIHEAM NUCIS-Newsletter 9 (2000) 50-55.
  40. Openshaw S., Openshaw C., Artificial Intelligence in Geography, J. Wiley and Sons, Chichester, 1997.
  41. Parker A.J., Parker K.C., Faust T.D., Fuller M.M., The effects of climatic variability on radial growth of two varieties of sand pine (Pinus clausa) in Florida, USA, Ann. For. Sci. 58 (2001) 333-350  [EDPS link].
  42. Perttunen J., Sievänen R., Nikinmaa E., Salminen H., Saarenmaa H., Väkevä J., LIGNUM: A tree model based on simple structural units, Ann. Bot. 77 (1996) 87-98  [CROSSREF link].
  43. Prada M.A., Gordo J., de Miguel J., Mutke S., Catalán G., Iglesias S., Gil L., Las regiones de procedencia de Pinus pinea L. en España, Organismo Autónomo de Parques Naturales, Madrid, 1997.
  44. Reffye Ph. de, Dinouard P., Barthélémy D., Modélisation et simulation de l'architecture de l'orme du Japon Zelkova serrata (Thunb.) Makino (Ulmaceae) : La notion d'axe de référence, in: Edelin C. (Ed.), L'arbre. Biologie et Développement, Naturalia Monspeliensa n° h.s., 1991, pp. 251-266.
  45. Santos F.D., Forbes K., Moita R. (Eds.), Mudança Climática em Portugal. Cenarios, Impactes e Medidas de Adaptação - SIAM. Sumário Executivo e Conclusões, Gradivia, Lisboa, 2001.
  46. SAS Inc., SAS-STAT User's Manual, Ver. 6.0, SAS Inc., 1996.
  47. Schwalm C., Ek A.R., Climate change and site: relevant mechanisms and modelling techniques, For. Ecol. Manage. 150 (2001) 241-257.