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Using Discriminant Analysis

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The applied silvicultural treatments were control (C), fertilization (F) ... Figure 1. DBH distribution of study stems associated with treatments. ... – PowerPoint PPT presentation

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Title: Using Discriminant Analysis


1
Using Discriminant Analysis Principal
Component Analysis in Evaluating the Impacts of
Silvicultural Treatments on Tree Growth
2
Impacts of Silvicultural Treatmentson Tree Growth
  • Assuming that the relationship between diameter
    at breast height (dbh, in) and tree height (ht,
    ft) varies with treatment, a tree can be
    characterized using a treatment class related
    criterion subject to stipulated dbh and ht
    values. A higher rate of correct judgement
    provides stronger evidence of the significant
    difference among treatment groups and vice versa.
    This method is so called discriminant technique
    of multivariate data analysis.

3
  • Study data came from a research project at the
    School of Forest Resources, UGA (CAPPS). The
    discriminant technique was applied for evaluating
    silvicultural treatment impacts on planted
    loblolly pines from two installations in the
    lower coastal plain of Georgia. The applied
    silvicultural treatments were control (C),
    fertilization (F), herbicide (H), and herbicide
    and fertilization (HF). Figs. (1) and (2) show
    the distributions of dbh and ht of study stems.

4
Figure 1. DBH distribution of study stems
associated with treatments.
5
Figure 2. Height distribution of study stems
associated with treatments.
6
  • During the analysis, the prior probability was
    assigned equally for each treatment (0.25) since
    the number of stems in each class is
    approximately the same. Cross validation was used
    to reduce bias in which discriminant functions
    are obtained from other n-1 observations and
    employed in classifying the one left out. The
    overall means of dbh and ht and the means of each
    treatment are presented in Table 1.

7
  • Table 1. Mean values of dbh (inch) and ht (feet)
    for all and each treatment groups.
  • Group Variable N Mean
    Standard

  • Deviation
  • All DBH 1199 6.78
    1.66
  • HT 1199 57.74
    10.07
  • C DBH 312 5.48
    1.49
  • HT 312
    48.31 8.47
  • F DBH 272 7.71
    1.45
  • HT 272
    64.58 5.44
  • H DBH 322 6.32
    1.19
  • HT 322
    53.40 6.66
  • HF DBH 293 7.78
    1.25
  • HT 293
    66.22 5.65

8
  • The multivariate analysis of variance showed
    significant differences among treatment groups
    for pooled dbh and ht, and a significant
    correlation between dbh and ht (correlation
    coefficient 0.8019). The derived linear
    discriminant functions are presented below and
    classification result is listed in Table 2
  • -29.9517-3.5473dbh1.6420ht for C
  • -51.7810-4.1344dbh2.0973ht for F
  • -35.5738-3.4972dbh1.7468ht for H
  • -54.9733-4.4319dbh2.1814ht for HF

9
  • Table 2. Number of observations and percentage
    classified into a treatment (italic).
  • TRT C F H
    HF Total
  • C 186 39 84
    3 312
  • 59.62 12.50 26.92
    0.96 100.00
  • F 5 92 33
    142 272
  • 1.84 33.82 12.13
    52.21 100.00
  • H 112 53 154
    3 322
  • 34.78 16.46 47.83
    0.93 100.00
  • HF 2 92 18
    181 293
  • 0.68 31.40 6.14
    61.77 100.00
  • Total 305 276 289
    329 1199
  • 25.44 23.02 24.10
    27.44 100.00
  • Error 0.40 0.66 0.52
    0.38 0.49

10
  • Large error rates of classification were between
    treatments C and H, and F and HF, i.e., 27 of
    the observations in C were misclassified into H
    and 35 of the observations in H were
    misclassified into C. Likewise, 52 of the
    observations in F were misclassified into HF and
    31 of the observations in HF were misclassified
    into F.
  • On the other hand, the classification for
    fertilized stands versus unfertilized stands was
    more accurate, i.e., only 15 of the observations
    from unfertilized stands were misclassified into
    fertilized stands, and 10 of the observations
    from fertilized stands were misclassified into
    unfertilized stands.

11
  • The above facts implied that the growth responses
    (for both dbh and ht) between treatment C and H
    or F and HF are much less significant than those
    between F involved treatments (F or HF) and F
    excluded treatments (C or H). Figure 3 shows the
    similar trends as the described above using the
    group-specific density estimates obtained from
    discriminant analysis.

12
Figure 3. Group-specific density estimates of
each treatment versus dbh.
13
  • The bell-shape distribution densities of
    treatments F and HF are fully overlapped,
    implying that the impacts of the two treatments
    on dbh growth are hard to separate. Likewise,
    most of the density estimates of treatments H and
    C are overlapped and one may expect that more
    misclassifications occur during separating the
    stems from H only and C stands. However,
    distinct differences of the density estimates
    exist between stems from fertilized stands and
    unfertilized stands, implying a more accurate
    classification of fertilized and unfertilized
    trees.

14
  • In discriminant analysis, the impacts of
    silvicultural treatments are evaluated using both
    dbh and ht simultaneously. An observation is
    classified into a group according to the nearest
    distance criterion. For example, the calculated
    discriminant value for the trees in F only stands
    is 52 and 36 for the trees in H only stands. For
    a tree from F only stands with dbh 5.0 inches and
    ht 55 feet, the calculated discriminant value is
    43, which is closer to that of H only stands (7
    versus 9 in absolute value). That is, this tree
    is too small to be classified into the trees in F
    only stands

15
  • Likewise, about 10 of such trees in fertilized
    stands were called too small and classified into
    the trees in unfertilized stands and about 15 of
    such trees in unfertilized stands were called too
    large and classified into the trees from
    fertilized stands. On the other hand, tree sizes
    in F only and HF stands were too close to call,
    which resulted in large percentage
    misclassification, i.e., the difference between
    impacts of the two treatments is negligible.

16
Impacts of Silvicultural Treatments on Tree Stem
Development
  • Table 1 shows that silvicultural treatments,
    especially fertilization involved treatments,
    increased dbh and ht growth, which may affect
    stem profile. If the proportion of ht growth is
    larger or smaller than that of dbh growth, the
    stem could be slimmer or chummier, and vice
    versa. In this study, we use principal component
    analysis technique to address this problem

17
  • Because only two continuous numerical variables
    (dbh and ht) are involved, two principal
    components can be constructed and the
    coefficients equal to the eigenvectors of the
    correlation matrix. Using study data, the two
    eigenvalues obtained are 1.9 with proportion 0.93
    and 0.13 with proportion 0.07 and the
    eigenvectors obtained are presented below
  • P1 0.4261(dbh-6.78)0.0702(ht-57.74)
  • P2 0.4261(dbh-6.78)-0.0702(ht-57.74)
  • where P1 and P2 are the first and second
    principal components.

18
  • Since the value of P1 increases with dbh and ht,
    it reflects the variation of tree size, that is,
    larger trees should have larger values of P1.
    Grouping all 1200 stems into four groups with 300
    observations each by ascending order of P1, the
    majorities from the stipulated treatment stands
    in each group are C and H (94), C and H (74), F
    and HF (63), and F and HF (94), respectively
    (Table 3).

19
  • Table 3. Numbers of stems in four even groups.
  • Group Treatment Number DBH HT
  • 1 C 188
    4.53 43.04
  • 1 F 10
    4.91 51.36
  • 1 H 95
    5.02 46.12
  • 1 HF 7
    4.70 52.03
  • 2 C 78
    6.44 54.13
  • 2 F 41
    5.90 59.11
  • 2 H 145
    6.40 54.20
  • 2 HF 36
    5.99 58.12

20
  • Table 3. Numbers of stems in four even groups.
  • Group Treatment Number DBH HT
  • 3 C 40
    7.53 59.59
  • 3 F 95
    7.19 63.23
  • 3 H 70
    7.56 59.83
  • 3 HF 95 7.21
    63.79
  • 4 C 6
    8.73 62.65
  • 4 F 126 8.92
    68.43
  • 4 H 12 8.60
    63.76
  • 4 HF 155 8.69
    70.22

21
  • On the other hand, the value of P2 decreases with
    ht and increases with dbh, that is, chunky stems
    have larger P2 value. Assuming that the stems in
    the lower range are the slimmest and the stems in
    the upper range are the chunkiest, study stems
    can be grouped into three groups according to the
    value of P2. The result showed that the
    percentages of the stems from fertilized stands
    are 72 of the total 400 stems in the lower range
    with a ratio of dbh to ht approximately 0.1 and
    34 of the total 400 stems in the upper range
    with a ratio of dbh to ht approximately 0.13
    (Table 4).

22
  • Table 4. The stems in the first and third groups
    obtained according to ascending order of the
    value of the second principal component
  • Group Treatment Number DBH HT
  • 1 C 52 4.80
    49.99
  • 1 F 122 6.74
    64.34
  • 1 H 59 5.48
    52.96
  • 1 HF 167 7.18
    65.76
  • 3 C 138 5.99
    47.75
  • 3 F 80 9.06
    65.03
  • 3 H 126 6.85
    52.49
  • 3 HF 55 8.95
    66.51

23
  • Note that more slim stems came from fertilized
    stands and more chunky stems came from
    unfertilized stands. The above statistics imply
    that, in general, fertilization affects stem
    profile development and the growth of these stems
    along vertical direction is faster than
    horizontal direction.
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