kuswanto-2012
DESCRIPTION
Rancangan Bujur Sangkar Latin (RBL) (Latin Square Design). Kuswanto-2012. Rancangan Bujur Sangkar Latin: RBL adalah pengembangan dari RAK. Dimana RBL diterapkan untuk lahan yang mempunyai 2 arah gradien penyebab heterogenitas. - PowerPoint PPT PresentationTRANSCRIPT
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Kuswanto-2012
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Rancangan Bujur Sangkar Latin:
RBL adalah pengembangan dari RAK.Dimana RBL diterapkan untuk lahan yang mempunyai 2 arah gradien penyebab heterogenitas
Sangat tepat untuk penelitian dengan gradien kemiringan dan kelembaban tanah
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Imagine a field with a slope and fertility gradient:
fertility
slope B C A D E
C D E B A
B C
C D
A E
D B
E AA B C D E
B C D E A
C D E A B
D E A B C
E A B C D
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Imagine a field with a slope and fertility gradient:
fertility
slope B C A D E
C D E B A
B C
C D
A E
D B
E AA B C D E
B C D E A
C D E A B
D E A B C
E A B C D
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Imagine a field with a slope and fertility gradient:
fertility
slope B C A D E
C D E B A
B C
C D
A E
D B
E AA B C D E
B C D E A
C D E A B
D E A B C
E A B C D
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We refer to Latin Squares as 3x3 or 5x5 etc.A Latin square requires the same number of replications as we have treatments.
Degrees of freedom are calculated as follows (6x6 example):Total = (6x6) – 1 = 35Rows = r -1 = 6 – 1 = 5Columns = c – 1 = 6 – 1 = 5Treatments = k – 1 = 6 – 1 = 5Error = 35 – 5 – 5 – 5 = 20
or (r-1)(c-1) – (k – 1) = (5x5) – 5 = 20
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Example: We are interested in the effect of 4 fertilizers (A,B,C,D) on corn yield. We have seed which was stored under four conditions and we have four fields in which we are conducting the experiment.
stor1 stor2 stor3 stor4
Field1 B D A C
Field2 C A B D
Field3 A C D B
Field4 D B C A
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stor1 stor2 stor3 stor4
fld1 B D A C
fld2 C A B D
fld3 A C D B
fld4 D B C A
Each treatment appears in each row and column once.
Treatments are assigned randomly, but as each is assigned, constraints are placed on the next treatment to be assigned.
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A B C D E
B C D E A
C D E A B
D E A B C
E A B C D
1 2 3 4 5
1
2
3
4
5
How to randomizing??
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Then randomize the rows:
B C D E A
E A B C D
D E A B C
C D E A B
A B C D E
1 2 3 4 5
1
2
3
4
5
Pay attention the row position!
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Then randomize the rows:
B C D E A
E A B C D
D E A B C
C D E A B
A B C D E
1 2 3 4 5
1
2
3
4
5
Pay attention the row position!
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Then Randomize columns, then randomly assign treatments to letters:
E C B D A
A D C E B
B E D A C
C A E B D
D B A C E
5 3 2 4 1
1
2
3
4
5
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Then Randomize columns, then randomly assign treatments to letters:
E C B D A
A D C E B
B E D A C
C A E B D
D B A C E
5 3 2 4 1
1
2
3
4
5
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The LS design is most often used with a field to account for gradients in soil, fertility, or moisture.
In a greenhouse, plants on different shelves (rak) and benches (bangku) may be blocked.
Latin Squares are also useful when we know (or suspect variation) of a linear nature, but do not know the direction it will take (eg bark beetle study).
The Latin Square design is only useful if both rows and columns vary appreciably. If they do not, a RCBD (RAK) or Completely randomized design (RAL) would be better (more degrees of freedom in the error term for F test)
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How to analysis of a Latin Square:Three way model, treatment fixed effect, rows and columns are both random effects.
No replication so same problem as RCB design (RAL) with experimental error. Must remove interaction from model – assume no interaction.
Model Source of VariabilityTreatment (fixed)Row (random)Column (random)
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Example: We want to compare effect of 5 different fertilizer on yield of potatoes.
B D C A
C A D B
A C B D
D B A C
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Contoh : Hasil pipilan 4 varietas jagung
Lajur
Baris 1 2 3 4 Jlh baris
1 1,64 (B) 1,21(D) 1,42(C) 1,34(A) 5,62
2 1,47(C) 1,18(A) 1,40(D) 1,29(B) 5,35
3 1,67(A) 0,71(C) 1,66(B) 1,18(D) 5,225
4 1,56(D) 1,29(B) 1,65(A) 0,66(C) 5,17
Jlh lajur 6,35 4,395 6,145 4,475 21,365
Hitung jumlah perlakuan (P) dan rata-ratanya
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Jumlah perlakuan dan rerata
Perlakuan Jumlah Rerata
A 5,855 1,464
B 5,885 1,471
C 4,270 1,068
D 5,355 1,339
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Hitung JK
FK = (21,365)²/16 = 28,529JKt = {(1,640)² + …+ 0,660)² -FK = 1,4139JKb = (5,62)² + …+ (5,170)² -FK = 0,03015JKl = (6,350)² +…+ (4,475)² -FK = 0,8273JKp = (5,855)² + …+ (5,355)² -FK = 0,4268JKe = JKt-JKb-JKl-JKp = 0,1295
Masukkan ke tabel ANOVA
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Tabel AnovaSK DB JK KT F hit Ft5% Ft1%
Baris 3 0,03015 0,01005
Lajur 3 0,8273 0,2757
Perlakuan 3 0,4268 0,1422 6,59* 4,76 9,78
Galat 6 0,1295 0,0215
Total 15 1,4139
Kesimpulan : Perlakuan berbeda nyata
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Interpretasi
F hitung perlakuan berbeda nyata berarti 4 perlakuan tersebut secara statistik berbeda nyata
Perbedaan antar perlakuan menyebabkan keragaman, dan keragaman yang disebabkan oleh perlakuan lebih besar daripada keragaman yang disebabkan oleh faktor sesatan percobaan (faktor lain)
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