Cauchy distribution quantile function.
The quantile function for a Cauchy random variable is
for 0 <= p < 1, where x0 is the location parameter and gamma > 0 is the scale parameter.
$ npm install distributions-cauchy-quantileFor use in the browser, use browserify.
var quantile = require( 'distributions-cauchy-quantile' );Evaluates the quantile function for the Cauchy distribution. p may be either a number between 0 and 1, an array, a typed array, or a matrix.
var matrix = require( 'dstructs-matrix' ),
mat,
out,
x,
i;
out = quantile( 0.25 );
// returns ~-1
x = [ 0, 0.2, 0.4, 0.6, 0.8, 1 ];
out = quantile( x );
// returns [ -Infinity, ~-1.38, ~-0.325, ~0.325, ~1.38, +Infinity ]
x = new Float32Array( x );
out = quantile( x );
// returns Float64Array( [-Infinity,~-1.38,~-0.325,~0.325,~1.38,+Infinity] )
x = new Float32Array( 6 );
for ( i = 0; i < 6; i++ ) {
x[ i ] = i / 6;
}
mat = matrix( x, [3,2], 'float32' );
/*
[ 0 1/6
2/6 3/6
4/5 5/6 ]
*/
out = quantile( mat );
/*
[ -Infinity ~-1.73
~-0.577 ~0
~0.577 ~1.73 ]
*/The function accepts the following options:
- x0: location parameter. Default:
0. - gamma: scale parameter. Default:
1. - accessor: accessor
functionfor accessingarrayvalues. - dtype: output
typed arrayormatrixdata type. Default:float64. - copy:
booleanindicating if thefunctionshould return a new data structure. Default:true. - path: deepget/deepset key path.
- sep: deepget/deepset key path separator. Default:
'.'.
A Cauchy distribution is a function of two parameters: x0(location parameter) and gamma > 0(scale parameter). By default, x0 is equal to 0 and gamma is equal to 1. To adjust either parameter, set the corresponding options.
var x = [ 0, 0.2, 0.4, 0.6, 0.8, 1 ];
var out = quantile( x, {
'x0': 2,
'gamma': 1,
});
// returns [ -Infinity, ~0.624, ~1.68, ~2.32, ~3.38, +Infinity ]For non-numeric arrays, provide an accessor function for accessing array values.
var data = [
[0,0],
[1,0.2],
[2,0.4],
[3,0.6],
[4,0.8],
[5,1]
];
function getValue( d, i ) {
return d[ 1 ];
}
var out = quantile( data, {
'accessor': getValue
});
// returns [ -Infinity, ~0.624, ~1.68, ~2.32, ~3.38, +Infinity ]To deepset an object array, provide a key path and, optionally, a key path separator.
var data = [
{'x':[0,0]},
{'x':[1,0.2]},
{'x':[2,0.4]},
{'x':[3,0.6]},
{'x':[4,0.8]},
{'x':[5,1]}
];
var out = quantile( data, {
'path': 'x/1',
'sep': '/'
});
/*
[
{'x':[0,-Infinity]},
{'x':[1,~0.624]},
{'x':[2,~1.68]},
{'x':[3,~2.32]},
{'x':[4,~3.38]},
{'x':[5,+Infinity]}
]
*/
var bool = ( data === out );
// returns trueBy default, when provided a typed array or matrix, the output data structure is float64 in order to preserve precision. To specify a different data type, set the dtype option (see matrix for a list of acceptable data types).
var x, out;
x = new Float32Array( [0,0.2,0.4,0.6,0.8,1] );
out = quantile( x, {
'dtype': 'int32'
});
// returns Int32Array( [0,0,1,2,3,0] )
// BEWARE: Infinity is cast to `0` for integer arrays
// Works for plain arrays, as well...
out = quantile( [0,0.2,0.4,0.6,0.8,1], {
'dtype': 'float32'
});
// returns Float32Array( [-Infinity,~0.624,~1.68,~2.32,~3.38, +Infinity] )By default, the function returns a new data structure. To mutate the input data structure (e.g., when input values can be discarded or when optimizing memory usage), set the copy option to false.
var bool,
mat,
out,
x,
i;
x = [ 0, 0.2, 0.4, 0.6, 0.8, 1 ];
out = quantile( x, {
'copy': false
});
// returns [ -Infinity, ~0.624, ~1.68, ~2.32, ~3.38, +Infinity ]
bool = ( x === out );
// returns true
x = new Float32Array( 6 );
for ( i = 0; i < 6; i++ ) {
x[ i ] = i / 6 ;
}
mat = matrix( x, [3,2], 'float32' );
/*
[ 0 1/6
2/6 3/6
4/5 5/6 ]
*/
out = quantile( mat, {
'copy': false
});
/*
[ -Infinity ~-1.73
~-0.577 ~0
~0.577 ~1.73 ]
*/
bool = ( mat === out );
// returns true-
For any
poutside the interval[0,1], the the evaluated quantile function isNaN.var out; out = quantile( 1.1 ); // returns NaN out = quantile( -0.1 ); // returns NaN
-
If an element is not a numeric value, the evaluated quantile function is
NaN.var data, out; out = quantile( null ); // returns NaN out = quantile( true ); // returns NaN out = quantile( {'a':'b'} ); // returns NaN out = quantile( [ true, null, [] ] ); // returns [ NaN, NaN, NaN ] function getValue( d, i ) { return d.x; } data = [ {'x':true}, {'x':[]}, {'x':{}}, {'x':null} ]; out = quantile( data, { 'accessor': getValue }); // returns [ NaN, NaN, NaN, NaN ] out = quantile( data, { 'path': 'x' }); /* [ {'x':NaN}, {'x':NaN}, {'x':NaN, {'x':NaN} ] */
-
Be careful when providing a data structure which contains non-numeric elements and specifying an
integeroutput data type, asNaNvalues are cast to0.var out = quantile( [ true, null, [] ], { 'dtype': 'int8' }); // returns Int8Array( [0,0,0] );
var quantile = require( 'distributions-cauchy-quantile' ),
matrix = require( 'dstructs-matrix' );
var data,
mat,
out,
tmp,
i;
// Plain arrays...
data = new Array( 10 );
for ( i = 0; i < data.length; i++ ) {
data[ i ] = i / 10;
}
out = quantile( data );
// Object arrays (accessors)...
function getValue( d ) {
return d.x;
}
for ( i = 0; i < data.length; i++ ) {
data[ i ] = {
'x': data[ i ]
};
}
out = quantile( data, {
'accessor': getValue
});
// Deep set arrays...
for ( i = 0; i < data.length; i++ ) {
data[ i ] = {
'x': [ i, data[ i ].x ]
};
}
out = quantile( data, {
'path': 'x/1',
'sep': '/'
});
// Typed arrays...
data = new Float32Array( 10 );
for ( i = 0; i < data.length; i++ ) {
data[ i ] = i / 10;
}
out = quantile( data );
// Matrices...
mat = matrix( data, [5,2], 'float32' );
out = quantile( mat );
// Matrices (custom output data type)...
out = quantile( mat, {
'dtype': 'uint8'
});To run the example code from the top-level application directory,
$ node ./examples/index.jsUnit tests use the Mocha test framework with Chai assertions. To run the tests, execute the following command in the top-level application directory:
$ make testAll new feature development should have corresponding unit tests to validate correct functionality.
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$ make view-covCopyright © 2015. The Compute.io Authors.