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Ashmawy,, F. (2004). INCREASING PRECISION OF FIELD EXPERIMENTS IN MAIZE USING UNIFORMITY TRIALS. Journal of Plant Production, 29(3), 1065-1076. doi: 10.21608/jpp.2004.238515
F. Ashmawy,. "INCREASING PRECISION OF FIELD EXPERIMENTS IN MAIZE USING UNIFORMITY TRIALS". Journal of Plant Production, 29, 3, 2004, 1065-1076. doi: 10.21608/jpp.2004.238515
Ashmawy,, F. (2004). 'INCREASING PRECISION OF FIELD EXPERIMENTS IN MAIZE USING UNIFORMITY TRIALS', Journal of Plant Production, 29(3), pp. 1065-1076. doi: 10.21608/jpp.2004.238515
Ashmawy,, F. INCREASING PRECISION OF FIELD EXPERIMENTS IN MAIZE USING UNIFORMITY TRIALS. Journal of Plant Production, 2004; 29(3): 1065-1076. doi: 10.21608/jpp.2004.238515

INCREASING PRECISION OF FIELD EXPERIMENTS IN MAIZE USING UNIFORMITY TRIALS

Article 4, Volume 29, Issue 3, March 2004, Page 1065-1076  XML PDF (185.25 K)
Document Type: Original Article
DOI: 10.21608/jpp.2004.238515
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Author
F. Ashmawy,
Cent. Lab. For Design & Stat. Analysis Research, ARC.
Abstract
The present study aimed to find out optimum plot size. shape and the proper
number of replications in maize experiments. Two uniformity trials were carried out at
the Agricultural Research Station of Sids, Beni-Sowef Governorate during the
successive growing seasons of 2002 and 2003 using maize cultivar Three Way Cross
310 (T.WC 310). The actual area of each field trial was divided into 8 strips, each
consisted of 100 rows of 3.0 m long and 70 cm apart. Each row was considered as a
basic unit i.e 2.1 m2. Consequently, a total of 800 basic units was utilized for each trial
in the two seasons. Optimum plot size was estimated using Smith method and
maximum curvature procedure.
Increasing plot size decreased variance per basic unit and C.V. However, the
reduction was not in proportion with the increase in plot size. Index of soil
heterogeneity was 0.5430 and 0.6679 for the first and second seasons, reppectively,
indicating moderate variation in the soil.
Increasing plot size from one basic unit to 400 basic units reduced C.V from
20.187 to 4.925 respectively. in the first season and correspondingly from 26.731 for
one basic unit plot size to 3.582 for a plot size of 400 basic units in the second
season. The exponential relationshi~s between C.v and plot size (X) were C.V =
20.187X.o·m and C.v = 26.731x.o3 5 for the first and second seasons, repectively.
Optimum plot size was one and two basic units (112000 and 111000 fed) for both
seasons, respectively, using Smith method while it was 3 and 5 basic units (1/667 and
11400 fed) using maximum curvature method.
Plot shape had no clear effect in all cases. However, long and narrow plots
were more efficient as it decreased variance per basic unit and C.V. Increasing plot
size generally decreased number of replications required to detect differences of 15 %
and 20 % of the mean.
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