Fit distribution using moments

5 ビュー (過去 30 日間)
proy
proy 2024 年 1 月 23 日
編集済み: John D'Errico 2024 年 1 月 23 日
There is a `fitdist` function to find distribution based on the given data.
Is there a function to find a distribution given moments?
Thank you.

採用された回答

John D'Errico
John D'Errico 2024 年 1 月 23 日
編集済み: John D'Errico 2024 年 1 月 23 日
This is something commonly done using either the Pearson or Johnson family of distributions. (It has been many years since I looked at this, so there may be other choices by now too.) The MATLAB stats TB offers the Pearson family (which I think I recall is the better choice anyway.)
lookfor pearson
pearscdf - Pearson cumulative distribution function pearspdf - Pearson probability density function pearsrnd - Pearson system random numbers
For example, given the first 4 moments, we can use those tools.
help pearscdf
PEARSCDF Cumulative distribution function (CDF) for Pearson system of distributions F = PEARSCDF(X, MU, SIGMA, SKEW, KURT) returns an array F of the Pearson system's cumulative distribution function evaluated at double/single array X. The evaluated Pearson distribution has mean MU, standard deviation SIGMA, skewness SKEW, and kurtosis KURT. MU and SIGMA can be double/single scalars or arrays. If they are arrays, each must have the same size as X. SKEW, and KURT must be double/single scalars. The kurtosis KURT must be greater than the square of the skewness SKEW plus 1. The kurtosis of the normal distribution 3. F = PEARSCDF(__, 'upper') returns the complement of the CDF. For all Pearson types except 4, this syntax uses an algorithm that more accurately computes the extreme upper-tail probabilities. [F, TYPE] = PEARSCDF(__) returns the type TYPE of the specified distribution within the Pearson system. Type is a scalar integer from 0 to 7. The eight distribution types in the Pearson system correspond to the following distributions: Type 0: Normal distribution Type 1: Four-parameter beta Type 2: Symmetric four-parameter beta Type 3: Three-parameter gamma Type 4: Not related to any standard distribution. Density proportional to (1+((x-mu)/sigma)^2)^(-a) * exp(-b*arctan((x-mu)/sigma)) where a and b are quantities related to the differential equation that defines the Pearson system. Type 5: Inverse gamma location-scale Type 6: F location-scale Type 7: Student's t location-scale [F,TYPE,COEFS] = PEARSCDF(__) returns the coefficients of the quadratic polynomial that defines the distribution via the following differential equation: d(log(p(x)))/dx = -(a + x) / (COEFS(1) + COEFS(2)*x + COEFS(3)*x^2) Example: Evaluate the Pearson distribution CDF at parameters that correspond to the standard Normal: % mu=0, sigma=1, skew=0, kurt=3 for the Pearson distribtion % corresponds to the standard Normal distribution % Evaluate this CDF from -1 to 1 in increments of 0.1 [cdf, type] = pearscdf(-1:0.1:1, 1, 2, 0, 3) See also PEARSPDF, PEARSRND, CDF Documentation for pearscdf doc pearscdf
How would you use them? Simple enough. For example, I know the normal distribution has skewness zero, and kurtosis 3. So a normal distribution, with mean 1, and standard deviation 1/2 would have the cdf...
[~,T] = pearscdf([],1,1/2,0,3)
T = 0
A Pearson type 0 is a normal distribution. Whoopsie do! I got it right!
And we can plot the cdf as:
fplot(@(x) pearscdf(x,1,1/2,0,3))
You can use pearsrnd to generate random numbers from that distribution, etc.

その他の回答 (0 件)

カテゴリ

Help Center および File ExchangeRegression についてさらに検索

タグ

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by