Free access
Volume 64, Number 1, January-February 2009
Page(s) 45 - 51
Published online 23 January 2009
  1. Smart R.E., Photosynthesis by grapevine canopies, J. Appl. Ecol. 11 (1974) 997–1006. [CrossRef]
  2. Barlow H.W.B., The relationship between leaf size and shoot length in apple, Hortic. Sci. 55 (1980) 279–283.
  3. Hughes B.R., Proctor J.T.A., Estimation of leaflet, leaf and total leaf area of Panax quinquefolius L. using linear measurements, J. Am. Soc. Hortic. Sci. 106 (1981) 167–170.
  4. Smith R.J., Kliewer W.M., Estimation of Thompson seedless grapevine leaf area, Am. J. Enol. Vitic. 35 (1984) 16–22.
  5. Smart R.E., Principles of grapevine canopy microclimate manipulation with implications for yield and quality: a review, Am. J. Enol. Vitic. 36 (1985) 230–239.
  6. Williams L.E., Growth of ‘Thompson seedless’ grapevines. I. Leaf area development and dry weight distribution, J. Am. Soc. Hortic. Sci. 112 (1987) 325–330.
  7. Kalina J., Slovak V., The inexpensive tool for the determination of projected leaf area, Ekol. Bratisl. 23 (2004) 163–167.
  8. Potdar M.V., Pawar K.R., Non-destructive leaf area estimation in banana, Sci. Hortic. 45 (1991) 251–254. [CrossRef]
  9. Rieger M., Duemmel M.J., Comparison of drought resistance among Prunus species from divergent habitats, Tree Physiol. 11 (1992) 369–380. [PubMed]
  10. Horsley S.B., Gottschalk K.W., Leaf area and net photosynthesis during development of Prunus serotina seedlings, Tree Physiol. 12 (1) (1993) 55–69. [PubMed]
  11. Gottschalk K.W., Shade, leaf growth and crown development of Quercus rubra, Quercus velutina, Prunus serotina and Acer rubrum seedlings, Tree Physiol. 14 (1994) 735–749. [PubMed]
  12. Kerstiens G., Hawes C.W., Response of growth and carbon allocation to elevated CO2 in young cherry (Prunus avium L.) saplings in relation to root environment, New Phytol. 128 (1994) 607–614. [CrossRef]
  13. Picchioni G.A., Weinbaum S.A., Retention and the kinetics of uptake and export of foliage-applied, labelled boron by apple, pear, prune, and sweet cherry leaves, J. Am. Soc. Hortic. Sci. 120 (1995) 28–35.
  14. Uzun S., The quantitative effects of temperature and light environment on the growth, development and yield of tomato (Lycopersicon esculentum Mill.) and aubergine (Solanum melongena L.), Univ. Reading, thesis, UK, 1996, 221 p.
  15. Centritto M., Loreto F., Massacci A., Pietrini F., Villani M.C., Zacchine M., Improved growth and water use efficiency of cherry saplings under reduced light intensity, Ecol. Res. 15 (2000) 385–392. [CrossRef]
  16. Sparks D., A rapid method for estimating the leaf area of the Stuart pecan, Carya illinoensis Koch., HortSci. 1 (1966) 93–94.
  17. Kobayashi K.D., Estimating leaf area of ‘Beaumont’ guava, Trop. Agric. 65 (1988) 173–175.
  18. Ramkhelawan E., Brathwaite R.A.I., Leaf area estimation by non destructive methods in sour orange (Citrus aurantium L.), Trop. Agric. 67 (1990) 203–206.
  19. Lang G.A., Underlying principles of high-density sweet cherry production, Acta Hortic. 667 (2005) 325–335.
  20. Anderson R.L., Robinson T., Lang G.A., Managing the Gisela cherry rootstocks. N.Y., Fruit Quarterly 7 (1999) 19–22.
  21. Sepulveda G.R., Kliewer W.M., Estimation of leaf area of two grapevine cultivars (Vitis vinifera L.) using laminae linear measurements and fresh weight, Am. J. Enol. Vitic. 34 (1983) 221–226.
  22. Elsner E.A., Jubb G.L., Leaf area estimation of concord grape leaves from simple linear measurements, Am. J. Enol. Vitic. 39 (1988) 95–97.
  23. Lang G.A., Precocious, dwarfing and productive – How will new cherry rootstocks impact the sweet cherry industry? HortTechnol. 10 (2000) 719–725.
  24. Lu H.Y., Lu C.T., Wei M.L., Chan F.L., Comparison of different models for non-destructive leaf area estimation in Taro, Agron. J. 96 (2004) 448–453. [CrossRef]
  25. Silva P.S.L., Barbin D., Gonçalvez R.J.S., Firmino J.D.C., Fonseca I.C., Leaf area estimates of custard apple tree progenies, Rev. Bras. Frutic. 26 (2004) 558–560.
  26. Fladung M., Ritter, E., Plant leaf area measurements by personal computers, J. Agron. Crop Sci. 166 (1991) 69–70. [CrossRef]
  27. Mori S., Kawasaki T., Takeuchi L., Non-destructive measurement of the growth of leaf area by means of a portable copying machine, J. Jpn. For. Soc. 73 (1991) 298–300.
  28. Smith W.K., Schoettle A.W., Cui M., Importance of the method of leaf area measurement to the interpretation of gas exchange of complex shoots, Tree Physiol. 8 (1991) 121–127. [PubMed]
  29. Blanke M., Scanner for leaf area measurement – leaves keep their form, Gartenbaumag. 3 (1995) 27–28.
  30. Ebert G., Leaf area measurement with laser optics, Erwerbsobstbau 37 (1995) 87–188.
  31. Villalobos F.J., Orgaz F., Mateos L., Non-destructive measurement of leaf area in olive (Olea europaea L.) trees using a gap inversion method, Agric. For. Meteorol. 73 (1995) 29–42. [CrossRef]
  32. Beverly R.B., van Lersel M.V., Calibration of a video image analysis system for measurement of stem length, leaf area, and percent ground coverage, Commun. Soil Sci. Plant Anal. 29 (1998) 1071–1081. [CrossRef]
  33. Igathinathane C., Prakash V.S.S., Padma U., Babu G.R., Womac A.R., Interactive computer software development for leaf area measurement, Comput. Electron. Agric. 51 (2006) 1–16. [CrossRef]
  34. Manivel L., Weaver R.J., Biometric correlations between leaf area and length measurements of ‘Grenache’ grape leaves, HortSci. 9 (1974) 27–28.
  35. Robbins N.S., Pharr D.M., Leaf area prediction models for cucumber from linear measurements, HortSci. 22 (1987) 1264–1266.
  36. Tsonev T., Sergiev I., Leaf-area measurement using hand scanner, Photosynth. 29 (1993) 625–630.
  37. Baker B., Olszyk D.M., Tingey D., Digital image analysis to estimate leaf area, J. Plant. Physiol. 148 (1996) 530–535.
  38. Korva J.T., Forbes G.A., A simple and low cost method for leaf area measurement of detached leaves, Exp. Agric. 33 (1997) 65–72. [CrossRef]
  39. O'Neal M.E., Landis D.A., Isaacs R., An inexpensive, accurate method for measuring leaf area and defoliation through digital image analysis, J. Econ. Entomol. 95 (2002) 1190–1194. [CrossRef] [PubMed]
  40. Gamiely S., Randle W.M., Mills H.A., Smittle D.A., A rapid and non-destructive method for estimating leaf area of onions. HortSci. 26 (1991) 206.
  41. Gutierrez T., Lavin A., Linear measurements for non-destructive estimation of leaf area ‘Chardonnay’ vines, Agric. Tec. 60 (2000) 67–69.
  42. Boyuton D., Harris R.W., Relationship between leaf dimensions, leaf, and shoot length in the McIntosh apple, Elberta peach, and Italian prune, Proc. Am. Soc. Hortic. Sci. 55 (1950) 16–20.
  43. Kumar K., Srivastava R.P., Singh A.K., Bana D.S., Use of linear measurement in the estimation of leaf area of some apricot, peach, plum, pear and guava varieties, Indian J. Hortic. 34 (1977) 229–234.
  44. Demirsoy H., Demirsoy L., Uzun S., Ersoy B., Non-destructive leaf area estimation in peach, Eur. J. Hortic. Sci. 69 (2004) 144–146.
  45. Demirsoy H., Demirsoy L., Ozturk A., Improved model for the non-destructive estimation of strawberry leaf area, Fruits 60 (2005) 69–73. [CrossRef] [EDP Sciences]
  46. Cittadini E.D., Peri L., Estimation of leaf area in sweet cherry using a non-destructive method, RIA (INTA) 35 (2006) 143–150.
  47. Ackley W.B., Crandall P.C., Russell T.S., The use of linear measurements in estimating leaf areas, Proc. Am. Soc. Hortic. Sci. 72 (1958) 326–330.
  48. Uzun S., Çelik H., Leaf area prediction models (uzçelik-1) for different horticultural plants, Turk. J. Agric. For. 23 (1999) 645–650.
  49. Reynolds S.G.A., A note on estimation of leaf areas of Cacao (Theobroma cacao L.) from three leaf parameters, Trop. Agric. 48 (1971) 177–179.
  50. Demirsoy L., Demirsoy H., Leaf area estimation model for some local cherry genotypes in Turkey, Pak. J. Biol. Sci. 6 (2003) 153–156. [CrossRef]
  51. Demirsoy H., Demirsoy L., A validated leaf area prediction model for some cherry cultivars in Turkey, Pak. J. Bot. 35 (2003) 361–367.
  52. Serdar U., Demirsoy H., Non-destructive leaf area estimation in chestnut, Scientia Hortic. 108 (2006) 227–230. [CrossRef]
  53. Williams L., Martinson T.E., Non-destructive leaf area estimation of ‘Niagara’ and ‘De Chaunac’ grapevines, Scientia Hortic. 98 (2003) 493–498. [CrossRef]
  54. Mendoza-De Gyves E., Rouphael Y., Cristofori V., Mira F.R., A non-destructive, simple and accurate model for estimating the individual leaf area of kiwi (Actinidia deliciosa), Fruits 62 (2007) 171–176. [CrossRef] [EDP Sciences]
  55. Ranjbar A., Damme P. van, Estimation of leaf area by non–destructive methods in three Iranian pistachio species (Pistacia mutica subsp. cabulica, Pistacia khinjuk subsp. oblonda and Pistacia khinjuk subsp. populifolia), Mededelingen – Fac. Landbouwkd. Toegep. Biol. Wet. Univ. Gent 64 (2) (1999) 49–56.
  56. Nesmith D.S., Non-destructive leaf area estimation of rabbiteye blueberries, HortSci. 26 (1991) 132.
  57. Mandal K.K., Ghosh S.K., Gayen P., A non-destructive way of leaf area estimation in the strawberry, Ann. Biol. 18 (2002) 19–24.
  58. Satpathy B., Shivnath A., Rao K.M., Ghosh P.L., Nair B.P., An easy and rapid method of leaf area estimation in white mulberry (Morus alba), Indian J. Agric. Sci. 62 (1992) 489–491.
  59. Celik H., Uzun S., Validation of leaf area estimation models (Uzçelik-1) evaluated for some horticultural plants, Pak. J. Bot. 34 (2002) 41–46.
  60. Cristofori V., Rouphael Y., Mendoza-de Gyves E., Bignami, C., A simple model for estimating leaf area of hazelnut from linear measurements, Scientia Hortic. 113 (2007) 221–225. [CrossRef]