About stdlib...
We believe in a future in which the web is a preferred environment for numerical computation. To help realize this future, we've built stdlib. stdlib is a standard library, with an emphasis on numerical and scientific computation, written in JavaScript (and C) for execution in browsers and in Node.js.
The library is fully decomposable, being architected in such a way that you can swap out and mix and match APIs and functionality to cater to your exact preferences and use cases.
When you use stdlib, you can be absolutely certain that you are using the most thorough, rigorous, well-written, studied, documented, tested, measured, and high-quality code out there.
To join us in bringing numerical computing to the web, get started by checking us out on GitHub, and please consider financially supporting stdlib. We greatly appreciate your continued support!
Perform a chi-square goodness-of-fit test.
npm install @stdlib/stats-chi2gof
Alternatively,
- To load the package in a website via a
script
tag without installation and bundlers, use the ES Module available on theesm
branch (see README). - If you are using Deno, visit the
deno
branch (see README for usage intructions). - For use in Observable, or in browser/node environments, use the Universal Module Definition (UMD) build available on the
umd
branch (see README).
The branches.md file summarizes the available branches and displays a diagram illustrating their relationships.
To view installation and usage instructions specific to each branch build, be sure to explicitly navigate to the respective README files on each branch, as linked to above.
var chi2gof = require( '@stdlib/stats-chi2gof' );
Computes a chi-square goodness-of-fit test for the null hypothesis that the values of x
come from the discrete probability distribution specified by y
.
// Observed counts:
var x = [ 30, 20, 23, 27 ];
// Expected counts:
var y = [ 25, 25, 25, 25 ];
var res = chi2gof( x, y );
var o = res.toJSON();
/* returns
{
'rejected': false,
'alpha': 0.05,
'pValue': ~0.5087,
'df': 3,
'statistic': ~2.32,
...
}
*/
The second argument can either be an array-like object (or 1-dimensional ndarray
) of expected frequencies, an array-like object (or 1-dimensional ndarray
) of population probabilities summing to one, or a discrete probability distribution name to test against.
// Observed counts:
var x = [ 89, 37, 30, 28, 2 ];
// Expected probabilities:
var y = [ 0.40, 0.20, 0.20, 0.15, 0.05 ];
var res = chi2gof( x, y );
var o = res.toJSON();
/* returns
{
'rejected': true,
'alpha': 0.05,
'pValue': ~0.0187,
'df': 3,
'statistic': ~9.9901,
...
}
*/
When specifying a discrete probability distribution name, distribution parameters must be provided as additional arguments.
var Int32Array = require( '@stdlib/array-int32' );
var discreteUniform = require( '@stdlib/random-base-discrete-uniform' );
var res;
var x;
var v;
var i;
// Simulate expected counts...
x = new Int32Array( 100 );
for ( i = 0; i < x.length; i++ ) {
v = discreteUniform( 0, 99 );
x[ v ] += 1;
}
res = chi2gof( x, 'discrete-uniform', 0, 99 );
// returns {...}
The function accepts the following options
:
- alpha: significance level of the hypothesis test. Must be on the interval
[0,1]
. Default:0.05
. - ddof: "delta degrees of freedom" adjustment. Must be a nonnegative integer. Default:
0
. - simulate:
boolean
indicating whether to calculate p-values by Monte Carlo simulation. Default:false
. - iterations: number of Monte Carlo iterations. Default:
500
.
By default, the test is performed at a significance level of 0.05
. To adjust the significance level, set the alpha
option.
var x = [ 89, 37, 30, 28, 2 ];
var p = [ 0.40, 0.20, 0.20, 0.15, 0.05 ];
var res = chi2gof( x, p );
var table = res.toString();
/* e.g., returns
Chi-square goodness-of-fit test
Null hypothesis: population probabilities are equal to those in p
pValue: 0.0186
statistic: 9.9901
degrees of freedom: 3
Test Decision: Reject null in favor of alternative at 5% significance level
*/
res = chi2gof( x, p, {
'alpha': 0.01
});
table = res.toString();
/* e.g., returns
Chi-square goodness-of-fit test
Null hypothesis: population probabilities are equal to those in p
pValue: 0.0186
statistic: 9.9901
degrees of freedom: 3
Test Decision: Fail to reject null in favor of alternative at 1% significance level
*/
By default, the p-value is computed using a chi-square distribution with k-1
degrees of freedom, where k
is the length of x
. If provided distribution arguments are estimated (e.g., via maximum likelihood estimation), the degrees of freedom should be corrected. Set the ddof
option to use k-1-n
degrees of freedom, where n
is the degrees of freedom adjustment.
var x = [ 89, 37, 30, 28, 2 ];
var p = [ 0.40, 0.20, 0.20, 0.15, 0.05 ];
var res = chi2gof( x, p, {
'ddof': 1
});
var o = res.toJSON();
// returns { 'pValue': ~0.0186, 'statistic': ~9.9901, 'df': 3, ... }
Instead of relying on chi-square approximation to calculate the p-value, one can use Monte Carlo simulation. When the simulate
option is true
, the simulation is performed by re-sampling from the discrete probability distribution specified by y
.
var x = [ 89, 37, 30, 28, 2 ];
var p = [ 0.40, 0.20, 0.20, 0.15, 0.05 ];
var res = chi2gof( x, p, {
'simulate': true,
'iterations': 1000 // explicitly set the number of Monte Carlo simulations
});
// returns {...}
The function returns a results object
having the following properties:
- alpha: significance level.
- rejected:
boolean
indicating the test decision. - pValue: test p-value.
- statistic: test statistic.
- df: degrees of freedom.
- method: test name.
- toString: serializes results as formatted test output.
- toJSON: serializes results as a JSON object.
To print formatted test output, invoke the toString
method. The method accepts the following options:
- digits: number of displayed decimal digits. Default:
4
. - decision:
boolean
indicating whether to show the test decision. Default:true
.
var x = [ 89, 37, 30, 28, 2 ];
var p = [ 0.40, 0.20, 0.20, 0.15, 0.05 ];
var res = chi2gof( x, p );
var table = res.toString({
'decision': false
});
/* e.g., returns
Chi-square goodness-of-fit test
Null hypothesis: population probabilities are equal to those in p
pValue: 0.0186
statistic: 9.9901
degrees of freedom: 3
*/
- The chi-square approximation may be incorrect if the observed or expected frequencies in each category are too small. Common practice is to require frequencies greater than five.
var poisson = require( '@stdlib/random-base-poisson' );
var Int32Array = require( '@stdlib/array-int32' );
var chi2gof = require( '@stdlib/stats-chi2gof' );
var N = 400;
var lambda = 3.0;
var rpois = poisson.factory( lambda );
// Draw samples from a Poisson distribution:
var x = [];
var i;
for ( i = 0; i < N; i++ ) {
x.push( rpois() );
}
// Generate a frequency table:
var freqs = new Int32Array( N );
for ( i = 0; i < N; i++ ) {
freqs[ x[ i ] ] += 1;
}
// Assess whether the simulated values come from a Poisson distribution:
var out = chi2gof( freqs, 'poisson', lambda );
// returns {...}
console.log( out.toString() );
This package is part of stdlib, a standard library for JavaScript and Node.js, with an emphasis on numerical and scientific computing. The library provides a collection of robust, high performance libraries for mathematics, statistics, streams, utilities, and more.
For more information on the project, filing bug reports and feature requests, and guidance on how to develop stdlib, see the main project repository.
See LICENSE.
Copyright © 2016-2024. The Stdlib Authors.