Presentation is loading. Please wait.

Presentation is loading. Please wait.

The Purpose of an Experiment We usually want to answer certain questions posed by the objectives of the experiment Irrigation experiment (a 2 x 2 factorial)

Published byCameron Goodman Modified over 8 years ago

Similar presentations

Presentation on theme: "The Purpose of an Experiment We usually want to answer certain questions posed by the objectives of the experiment Irrigation experiment (a 2 x 2 factorial)"— Presentation transcript:

1 The Purpose of an Experiment We usually want to answer certain questions posed by the objectives of the experiment Irrigation experiment (a 2 x 2 factorial) –1 cm/ha applied early    –1 cm/ha applied late    –2 cm/ha applied early    –2 cm/ha applied late   

2 Questions we might ask: Is there a yield difference between 2 cm/ha and 1 ha-cm of water applied?       vs      Does it make a difference whether the water is applied early or late?       vs      Does the difference between 1 and 2 cm/ha depend on whether the water is applied early or late?       vs     

3 To test the hypothesis We would test the hypothesis that the grouped means are equal or said another way - that the difference between the two groups is zero.      =       or          = 

4 Contrasts of Means Think of the contrast as a linear function of the means L =          t  t H 0 : L = 0 H a : L  0 This would be a legitimate contrast if and only if:  j = 0 To estimate the contrast: L(L) = L+ t  V(L) The variance of a contrast V(L) = (  k j 2 )/r * MSE for equal replication V(L) = (k 1 2 /r 1 + k 2 2 /r 2 +... k t 2 /r t )*MSE for unequal replication Interval estimate of a contrast

5 Orthogonal Contrasts With t treatments, it is possible to form t-1 contrasts that are statistically independent of each other (i.e., one contrast conveys no information about the other) In order to be statistically independent, they must be orthogonal Contrasts are orthogonal if and only if the sum of the products of the coefficients equals 0 Where j = the j th mean in the linear contrast

6 For Example: A 2 factor factorial: P(2 levels), K(2 levels) –no P, no K (P 0 K 0 ) –20 kg/ha P, no K (P 1 K 0 ) –no P, 20 kg/ha K(P 0 K 1 ) –20 kg/ha P, 20 kg/ha K (P 1 K 1 ) Questions we might ask –Any difference between P and K when used alone? –Any difference when the two fertilizers are used alone versus together? –Any difference when there is no fertilizer versus when there is some?

7 Table of Contrasts ContrastP 0 K 0 P 1 K 0 P 0 K 1 P 1 K 1 Sum P vs K0+1-100 Alone vs Together0-1-1+20 None vs Some-3+1+1+10 Test for Orthogonality (0x0) + (1x-1) + (-1x-1) + (0x2) = 0 - 1 + 1 + 0 =0 (0x-3) + (1x1) + (-1x1) + (0x1) = 0 + 1 - 1 + 0 =0 (0x -3) + (-1 x 1) + (-1 x 1) + (2 x 1) = 0 - 1 - 1 + 2 = 0

8 Or another set: ContrastP 0 K 0 P 1 K 0 P 0 K 1 P 1 K 1 Sum P (Main Effect)-1+1-1+10 K (Main Effect)-1-1+1+10 PK (Interaction)+1-1-1+10 Test for Orthogonality (-1 x -1) + (1 x -1) + (-1 x 1) + (1 x 1) = 1 - 1 - 1 + 1 =0 (-1 x 1) + (1 x -1) + (-1 x -1) + (1 x 1) = -1 - 1 + 1 + 1 = 0 (-1 x 1) + (-1 x -1) + (1 x -1) + (1 x 1) = -1 + 1 - 1 + 1 = 0

9 Here is another example: A fertilizer experiment with 5 treatments: –C=Control, no fertilizer –PB=Banded phosphate –PS=Broadcast (surface) phosphate –NPB=Nitrogen with banded phosphate –NPS=Nitrogen with broadcast phosphate We might want to answer the following: –Is there a difference between fertilizer and no fertilizer? –Does the method of P application make a difference? –Does added N make a difference? –Does the effect of N depend on the method of P application?

10 Table of Contrasts: ContrastCPBPSNPBNPSSum None vs some-4+1+1+1+10 Band vs broadcast 0+1-1+1-10 N vs no N 0-1-1+1+10 N vs (B vs S) 0-1+1+1-10 Test for Orthogonality (-4x0) + (1x1) + (+1x-1) + (1x1) + (1x-1) = 0+1-1+1-1= 0 (-4x0) + (1x-1) + (1x-1) + (1x1) + (1x1) = 0-1-1+1+1= 0 (-4x0) + (1x-1) + (1x1) + (1x1) + (1x-1) = 0-1+1+1-1= 0 (0x0) + (1x-1) + (-1x-1) + (1x1) + (-1x1) = 0-1+1+1-1= 0 (0x0) + (1x-1) + (-1x1) + (1x1) + (-1x-1) = 0-1-1+1+1= 0 (0x0) + (-1x-1) + (-1x1) + (1x1) + (1x-1) = 0+1-1+1-1= 0

11 Contrast of Means We can partition the treatment SS into SS for contrasts with the following conditions: –Treatments are equally replicated –t = number of treatments –r = number of replications per treatment – = mean of yields on the j-th treatment – Contrast SS will add up to SST (if you have a complete set of t-1 orthogonal contrasts) It is not necessary to have a complete set of contrasts provided that those in your subset are orthogonal to each other

12 Contrast of Means Under these conditions – – V(L) = [(  j 2 )/r] * MSE for equal replication Caution – old notes, old homework, and old exams – Calculations are based on totals – SSL = MSL = – V(L) = (r  j 2 ) * MSE for equal replication

13 Drawing the contrasts - Not always easy Between group comparison NumberSet 1Set 2Single df contrast 1g1,g2,g3g4,g52(G1+G2+G3)-3(G4+G5) 2g1g2,g32G1-(G2+G3) 3g2g3G2-G3 4g4g5G4-G5 Divide and conquer

14 Revisiting the PxK Experiment ContrastP 0 K 0 P 1 K 0 P 0 K 1 P 1 K 1 LSS(L) P vs K 0+1-1 026.00 Alone vs Together 0-1-1+248.00 None vs Some-3+1+1+11130.25 TreatmentP 0 K 0 P 1 K 0 P 0 K 1 P 1 K 1 Means (3 reps)12161417 SST=44.25 44.25 SS(L i )= r*L i 2 /  j k ij 2

15 Another example A weed scientist wanted to study the effect of a new, all- purpose herbicide to control grassy weeds in lentils. He decided to try the herbicide both as a preemergent and as a postemergent spray. He also wanted to test the effect of phosphorus. –ControlC –Hand weedingW1 –Preemergent sprayW2 –Postemergent sprayW3 –Hand weeding + phosphorusPW1 –Preemergent spray + phosphorusPW2 –Postemergent spray + phosphorusPW3

16 Treatment Means TreatmentIIIIIIMean C218180192196.7 W1357353345351.7 W2325311297311.0 W3321297291303.0 PW1462458399439.7 PW2407409381399.0 PW3410392362388.0 Mean357.1342.9323.9341.3

17 ANOVA SourcedfSSMSF Total20121,670.29 Block23,903.721,951.8611.86 Treatment6115,792.2919,298.72117.30** Error121,974.28164.52 Treatments are highly significant so we can divide into contrasts

18 Orthogonal Contrasts CW1W2W3PW1PW2PW3 Contrast196.7351.7311303439.7399388LSS(L)F 1-61111111012.373201.34444.94** 2 0-1-1-111126134060.50207.03** 3 02-1-12-1-1181.78250.7050.15** 4 00-110-11-19270.751.64ns 5 0-211+2-1-132.250.01ns 6 001-10-11-36.750.04ns 1 =Some vs none 2 =P vs no P 3 =Hand vs Chemical 4 =pre vs post emergence 5 =Interaction 2 x 3 6 =Interaction 2 x 4 ControlC Hand weedingW1 Preemergent sprayW2 Postemergent sprayW3 Hand weeding + PPW1 Preemergent spray + PPW2 Postemergent spray + PPW3

19 So What Does This Mean? The treated plots outyielded the untreated check plots Fertilized plots outyielded unfertilized plots by an average of about 87 kg/plot Hand weeding resulted in higher yield than did herbicide regardless of when applied by about 45 kg/plot No difference in effect between preemergence and postemergence application of the herbicide The differences in weed control treatments did not depend on the presence or absence of phosphorus fertilizer

Download ppt "The Purpose of an Experiment We usually want to answer certain questions posed by the objectives of the experiment Irrigation experiment (a 2 x 2 factorial)"

Similar presentations

Week 2 – PART III POST-HOC TESTS. POST HOC TESTS When we get a significant F test result in an ANOVA test for a main effect of a factor with more than.

Week 2 – PART III POST-HOC TESTS. POST HOC TESTS When we get a significant F test result in an ANOVA test for a main effect of a factor with more than.
Analysis of Variance (ANOVA)

Analysis of Variance (ANOVA)
The Purpose of an Experiment We usually want to answer certain questions posed by the objectives of the experiment Irrigation experiment (a 2 x 2 factorial)

The Purpose of an Experiment We usually want to answer certain questions posed by the objectives of the experiment Irrigation experiment (a 2 x 2 factorial)
1 Chapter 4 Experiments with Blocking Factors. 2 4.1 The Randomized Complete Block Design Nuisance factor: a design factor that probably has an effect.

1 Chapter 4 Experiments with Blocking Factors The Randomized Complete Block Design Nuisance factor: a design factor that probably has an effect.
Chapter 4 Randomized Blocks, Latin Squares, and Related Designs

Chapter 4 Randomized Blocks, Latin Squares, and Related Designs
Design of Experiments and Analysis of Variance

Design of Experiments and Analysis of Variance
Three-Factor Experiments Design selection, treatment composition, and randomization remain the same Each additional factor adds a layer of complexity to.

Three-Factor Experiments Design selection, treatment composition, and randomization remain the same Each additional factor adds a layer of complexity to.
N-way ANOVA. Two-factor ANOVA with equal replications Experimental design: 2  2 (or 2 2 ) factorial with n = 5 replicate Total number of observations:

N-way ANOVA. Two-factor ANOVA with equal replications Experimental design: 2  2 (or 2 2 ) factorial with n = 5 replicate Total number of observations:
1 Multifactor ANOVA. 2 What We Will Learn Two-factor ANOVA K ij =1 Two-factor ANOVA K ij =1 –Interaction –Tukey’s with multiple comparisons –Concept of.

1 Multifactor ANOVA. 2 What We Will Learn Two-factor ANOVA K ij =1 Two-factor ANOVA K ij =1 –Interaction –Tukey’s with multiple comparisons –Concept of.
Part I – MULTIVARIATE ANALYSIS

Part I – MULTIVARIATE ANALYSIS
The Statistical Analysis Partitions the total variation in the data into components associated with sources of variation –For a Completely Randomized Design.

The Statistical Analysis Partitions the total variation in the data into components associated with sources of variation –For a Completely Randomized Design.
Chapter 3 Experiments with a Single Factor: The Analysis of Variance

Chapter 3 Experiments with a Single Factor: The Analysis of Variance
Lecture 9: One Way ANOVA Between Subjects

Lecture 9: One Way ANOVA Between Subjects
Chapter 10 - Part 1 Factorial Experiments.

Chapter 10 - Part 1 Factorial Experiments.
Introduction to Probability and Statistics Linear Regression and Correlation.

Introduction to Probability and Statistics Linear Regression and Correlation.
Analysis of Variance & Multivariate Analysis of Variance

Analysis of Variance & Multivariate Analysis of Variance
One-Way ANOVA Independent Samples. Basic Design Grouping variable with 2 or more levels Continuous dependent/criterion variable H  :  1 =  2 =... =

One-Way ANOVA Independent Samples. Basic Design Grouping variable with 2 or more levels Continuous dependent/criterion variable H  :  1 =  2 =... =
If = 10 and = 0.05 per experiment = 0.5 Type I Error Rates I.Per Comparison II.Per Experiment (frequency) = error rate of any comparison = # of comparisons.

If = 10 and = 0.05 per experiment = 0.5 Type I Error Rates I.Per Comparison II.Per Experiment (frequency) = error rate of any comparison = # of comparisons.
Chapter 12: Analysis of Variance

Chapter 12: Analysis of Variance
22-1 Factorial Treatments (§ 14.3, 14.4, 15.4) Completely randomized designs - One treatment factor at t levels. Randomized block design - One treatment.

22-1 Factorial Treatments (§ 14.3, 14.4, 15.4) Completely randomized designs - One treatment factor at t levels. Randomized block design - One treatment.

Similar presentations

Ads by Google