Laplacedf: Difference between revisions
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===Purpose=== | ===Purpose=== | ||
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This distribution is a symmetric distribution also known as the double exponential distribution. It is more peaked than the normal distribution Leptokurtic rather than mesokurtic means that it has a sharper peak at the mean in the density plot than a similar normal density | This distribution is a symmetric distribution also known as the double exponential distribution. It is more peaked than the normal distribution Leptokurtic rather than mesokurtic means that it has a sharper peak at the mean in the density plot than a similar normal density | ||
::<math>f(x) = \frac {1} {2b} \exp \left ( - \frac {|x-a|} {b} \right )</math> | |||
::<math>F(x) = \frac {1} {2} \exp \left [ - \frac {a-x} {b} \right ] \mathrm {I} \left ( x<a \right) +1 - \frac {1} {2} \exp \left [ - \frac {x-a} {b} \right ] \mathrm {I} \left ( x \ge a \right )</math> | |||
====Inputs==== | ====Inputs==== | ||
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* '''x''' = matrix in which the sample data is stored, in the interval (0,1). | * '''x''' = matrix in which the sample data is stored, in the interval (0,1). | ||
:: for function=quantile - matrix with values in the interval (0,1). | |||
:: for function=random - vector indicating the size of the random matrix to create. | |||
* '''a''' = scale parameter (real and positive). | * '''a''' = scale parameter (real and positive). | ||
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'''Note''': If inputs (x, a, and b) are not equal in size, the function will attempt to resize all inputs to the largest input using the RESIZE function. | '''Note''': If inputs (x, a, and b) are not equal in size, the function will attempt to resize all inputs to the largest input using the RESIZE function. | ||
'''Note''': Functions will typically allow input values outside of the acceptable range to be passed but such values will return NaN in the results. | '''Note''': Functions will typically allow input values outside of the acceptable range to be passed but such values will return NaN in the results. | ||
===Examples=== | ===Examples=== | ||
====Cumulative | ====Cumulative==== | ||
<pre> | |||
>> prob = laplacedf('c',0.99,1,2) | >> prob = laplacedf('c',0.99,1,2) | ||
prob = | prob = | ||
0.4975 | 0.4975 | ||
>> x = [0:0.1:10]; | >> x = [0:0.1:10]; | ||
>> plot(x,laplacedf('c',x,1,2),'b-',x,laplacedf('c',x,3,7),'r-') | >> plot(x,laplacedf('c',x,1,2),'b-',x,laplacedf('c',x,3,7),'r-') | ||
</pre> | |||
====Density | ====Density==== | ||
<pre> | |||
>> prob = laplacedf('d',0.99,1,1) | >> prob = laplacedf('d',0.99,1,1) | ||
prob = | prob = | ||
0.4950 | 0.4950 | ||
>> x = [0:0.1:10]; | >> x = [0:0.1:10]; | ||
>> plot(x,laplacedf('d',x,2,1),'b-',x,laplacedf('d',x,0.5,1),'r-') | >> plot(x,laplacedf('d',x,2,1),'b-',x,laplacedf('d',x,0.5,1),'r-') | ||
</pre> | |||
====Quantile | ====Quantile==== | ||
<pre> | |||
>> prob = laplacedf('q',0.99,0.5,1) | >> prob = laplacedf('q',0.99,0.5,1) | ||
prob = | prob = | ||
4.4120 | 4.4120 | ||
</pre> | |||
====Random==== | |||
<pre>>> prob = laplacedf('r',[4 1],2,1) | |||
>> prob = laplacedf('r',[4 1],2,1) | |||
ans = | ans = | ||
0.4549 | 0.4549 | ||
0.4638 | 0.4638 | ||
0.3426 | 0.3426 | ||
0.5011 | 0.5011 | ||
</pre> | |||
===See Also=== | ===See Also=== | ||
[[ | [[betadf]], [[cauchydf]], [[chidf]], [[expdf]], [[gammadf]], [[gumbeldf]], [[logisdf]], [[lognormdf]], [[normdf]], [[paretodf]], [[raydf]], [[triangledf]], [[unifdf]], [[weibulldf]] | ||
Latest revision as of 05:24, 10 October 2008
Purpose
Laplace distribution.
Synopsis
- prob = laplacedf(function,x,a,b)
Description
Estimates cumulative distribution function (cumulative, cdf), probability density function (density, pdf), quantile (inverse of cdf), or random numbers for a Laplace distribution.
This distribution is a symmetric distribution also known as the double exponential distribution. It is more peaked than the normal distribution Leptokurtic rather than mesokurtic means that it has a sharper peak at the mean in the density plot than a similar normal density
![{\displaystyle F(x)={\frac {1}{2}}\exp \left[-{\frac {a-x}{b}}\right]\mathrm {I} \left(x<a\right)+1-{\frac {1}{2}}\exp \left[-{\frac {x-a}{b}}\right]\mathrm {I} \left(x\geq a\right)}](https://wikimedia.org/api/rest_v1/media/math/render/svg/b6e73fd291359d44ce650aa4c18a55504559ff14)
Inputs
- function = [ {'cumulative'} | 'density' | 'quantile' | 'random' ], defines the functionality to be used. Note that the function recognizes the first letter of each string so that the string could be: [ 'c' | 'd' | 'q' | 'r' ].
- x = matrix in which the sample data is stored, in the interval (0,1).
- for function=quantile - matrix with values in the interval (0,1).
- for function=random - vector indicating the size of the random matrix to create.
- a = scale parameter (real and positive).
- b = shape parameter (real and positive).
Note: If inputs (x, a, and b) are not equal in size, the function will attempt to resize all inputs to the largest input using the RESIZE function.
Note: Functions will typically allow input values outside of the acceptable range to be passed but such values will return NaN in the results.
Examples
Cumulative
>> prob = laplacedf('c',0.99,1,2)
prob =
0.4975
>> x = [0:0.1:10];
>> plot(x,laplacedf('c',x,1,2),'b-',x,laplacedf('c',x,3,7),'r-')
Density
>> prob = laplacedf('d',0.99,1,1)
prob =
0.4950
>> x = [0:0.1:10];
>> plot(x,laplacedf('d',x,2,1),'b-',x,laplacedf('d',x,0.5,1),'r-')
Quantile
>> prob = laplacedf('q',0.99,0.5,1)
prob =
4.4120
Random
>> prob = laplacedf('r',[4 1],2,1)
ans =
0.4549
0.4638
0.3426
0.5011
See Also
betadf, cauchydf, chidf, expdf, gammadf, gumbeldf, logisdf, lognormdf, normdf, paretodf, raydf, triangledf, unifdf, weibulldf