Probability distributions
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Probability Distributions: Concepts, Moments, and Special Distributions, Slides of Environmental Law and Policy
An overview of probability distributions, including concepts of probability density function (p.d.f.) and cumulative distribution function (c.d.f.), moments of distributions (mean, variance, skewness), and special distributions such as gaussian (normal), lognormal, weibull, and poisson distributions. It also covers extreme value distributions and the generalized extreme value (g.e.v.) and generalized pareto distributions.
Typology: Slides
2012/2013
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Download Probability Distributions: Concepts, Moments, and Special Distributions and more Slides Environmental Law and Policy in PDF only on Docsity!
- Topics :
- Concepts of probability density function (p.d.f.) and
cumulative distribution function (c.d.f.)
- Moments of distributions (mean, variance, skewness)
- Parent distributions
- Extreme value distributions
Ref. : Book - Appendix C
- Probability density function :
- Probability that X lies between the values a and b is the area under the
graph of fX(x) defined by x=a and x=b
- i.e. a^^ x b f xdx
b
a x
Pr ( )
- Since all values of X must fall between - and + : (^ ) ^1
fx xdx
- i.e. total area under the graph of fX(x) is equal to 1
fX(x)
x
Pr(a<x<b)
x = a b
- Cumulative distribution function :
- The cumulative distribution function (c.d.f.) is the integral between -
and x of fX(x)
- Denoted by FX(x)
fX(x)
x
x = a
Fx(a)
- Area to the left of the x = a line is : FX(a)
This is the probability that X is less than a
- Moments of a distribution :
- Mean value
fX(x)
x
N
i
x xi N
X xf xdx
1
- The mean value is the first moment of the probability distribution, i.e.
the x coordinate of the centroid of the graph of fX(x)
x =X
- Moments of a distribution :
- Variance (^)
N
i
x x xi X N
x X f x dx
1
- The variance, X
2
, is the second moment of the probability distribution
about the mean value
fX(x)
x =X
x
- It is equivalent to the second moment of area of a cross section about
the centroid
X
- The standard deviation, X, is the square root of the variance
- Gaussian (normal) distribution :
- p.d.f.
2 x
2
x
x 2 σ
x X exp 2 π σ
f (x)
fX(x)
x
0
-4 -3 -2 -1 0 1 2 3 4
allows all values of x : -<x< +
bell-shaped distribution, zero skewness
- Gaussian (normal) distribution :
- c.d.f. FX(x) =
( ) is the cumulative distribution function of a normally distributed
variable with mean of zero and unit standard deviation (tabulated in
textbooks on probability and statistics)
(u) =
X
x X
dz
u z
(^)
exp 2
2
Used for turbulent velocity fluctuations about the mean wind speed,
dynamic structural response, but not for pressure fluctuations or scalar
wind speed
- Weibull distribution :
p.d.f. fX(x) =
c.d.f. FX(x) =
c = scale parameter (same units as X)
k= shape parameter (dimensionless)
X must be positive, but no upper limit.
k
k
k
c
x
c
kx exp
1
k
c
x 1 exp
Weibull distribution widely used for wind speeds, and sometimes for pressure
coefficients
complementary
c.d.f. FX(x) =
k
c
x exp
- Weibull distribution :
Special cases : k=1 Exponential distribution
k=2 Rayleigh distribution
k=
k=
k=
x
0 1 2 3 4
fx(x)
- Extreme Value distributions :
Previous distributions used for all values of a random variables, X
- known as ‘parent distributions
In many cases in civil engineering we are interested in the largest
values, or extremes, of a population for design purposes
Examples : flood heights, wind speeds
c.d.f of Y : FY(y) = FX1(y). FX2(y). ……….FXn(y)
Let Y be the maximum of n independent random variables, X 1 , X 2 , …….Xn
Special case - all Xi have the same c.d.f : FY(y) = [FX1(y)]n
- Generalized Extreme Value distribution (G.E.V.) :
c.d.f. FY(y) =
k is the shape factor; a is the scale factor; u is the location parameter
Special cases : Type I (k=0) Gumbel
Type III (k>0) ‘Reverse Weibull’
Type II (k<0) Frechet
k
a
k y u
1 / ( ) exp 1
G.E.V (or Types I, II, III separately) - used for extreme wind speeds and
pressure coefficients
- Generalized Pareto distribution (G.P.D.) :
c.d.f. FX(x) =
k is the shape factor is the scale factor
p.d.f. fX(x) =
k>0 : 0 < X< (/k) i.e. upper limit
k = 0 or k<0 : 0 < X <
G.P.D. is appropriate distribution for independent observations of excesses
over defined thresholds
e.g. thunderstorm downburst of 70 knots. Excess over 40 knots is 30 knots
k
1
σ
kx 1
1 k
1
σ
kx 1 σ
- Generalized Pareto distribution :
0 1 2 3 4
fx(x)
x/
k=+0.
k=-0.
0