8.2. EXTREME VALUE ANALYSIS
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0.4
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0.35
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0.35
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0.3
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DENSITY
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DENSITY
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0.25
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BUT NOT
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0.3
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0.25
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OUTLIERS
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PROBABILITY
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PROBABILITY
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0.2
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EXTREME VALUES
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0.2
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0.15
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0.15
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0.1
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LOWER
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UPPER
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0.1
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LOWER
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UPPER
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TAIL
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TAIL
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DENSITY
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DENSITY THRESHOLD
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0.05
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0.05
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THRESHOLD
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0
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−4
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−3
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−2
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−1
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0
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1
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2
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3
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4
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5
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0
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−4
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−3
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−2
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−1
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0
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1
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2
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3
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4
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5
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−5
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−5
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VALUE
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VALUE
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(a) Symmetric distribution (b) Asymmetric distribution
Figure 8.2: Tails of a symmetric and asymmetric distribution
distributions. Some asymmetric distributions, such as an exponential distribution, may not even have a tail at one end of the distribution.
A model distribution is selected for quantifying the tail probability. The most commonly used model is the normal distribution. The density function fX (x) of the normal distribution with mean μ and standard deviation σ is defined as follows:
fX (x) =
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1
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−(x−μ)2
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(8.1)
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e
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.
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2·σ2
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√2·π
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·
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σ ·
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A standard normal distribution is one in which the mean is 0, and the standard deviation σ is 1. In some application scenarios, the mean μ and standard deviation σ of the distribution may be known through prior domain knowledge. Alternatively, when a large number of data samples is available, the mean and standard deviation may be estimated very accurately. These can be used to compute the Z-value for a random variable. The Z-number zi of an observed value xi can be computed as follows:
Large positive values of zi correspond to the upper tail, whereas large negative values correspond to the lower tail. The normal distribution can be expressed directly in terms of the Z-number because it corresponds to a scaled and translated random variable with a mean 0 and standard deviation of 1. The normal distribution of Eq. 8.3 can be written directly in terms of the Z-number, with the use of a standard normal distribution as follows:
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