Simultaneous CIs for Ratios of Means of Log-Normal Populations with Zeros

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License: MIT License (Apache License, Version 2.0)

Author: Jing Xu, Xinmin Li, Hua Liang

Classifiers

Project description

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LN0SCIs

Jing Xu, Xinmin Li, Hua Liang

Introduction

This Python package based on the paper of Simultaneous Confidence Intervals for Ratios of Means of Log-normal Populations with Zeros by Xu et al. It provides some methods for construct simultaneous confidence intervals for ratios of means of Log-normal populations with excess zeros. At last, we select 4 excellent methods which based on generalized pivotal quantity with order statistics and two-step MOVER intervals. For the convenience of use, we make a Python package called LN0SCIs, and it also has a R version package on CRAN: https://CRAN.R-project.org/package=LN0SCIs

  • If you are a R User, you can install in your R kernal by Github:

    • devtools::install_github(‘DataXujing/LN0SCIs’)

  • Or you can also install by CRAN:

    • install.packages(‘LN0SCIs’)

  • If you are a Python user, you can

    • pip install LN0SCIs

Methods

We provaide four main functions in our LN0SCIs packages, FGW(),FGH(),MOVERW() and MOVERH(), if you want to deep understanding these four methods, you can read our paper: Simultaneous Confidence Intervals for Ratios of Means of Log-normal Populations with Zeros. the code we trust in GitHub. If you want to know how to realize them, you can read the source code.

Examples

  • FGW()

from LN0SCIs import *
#Example1:
alpha = 0.05
p = np.array([0.2,0.2,0.2])
n = np.array([30,30,30])
mu = np.array([0,0,0])
sigma = np.array([1,1,1])
N = 1000
FGW(n,p,mu,sigma,N)
#Example2:
p = np.array([0.1,0.1,0.1,0.1])
n = np.array([30,30,30,30])
mu = np.array([0,0,0,0])
sigma = np.array([1,1,1,1])
C2 = np.array([[-1,1,0,0],[-1,0,1,0],[-1,0,0,1],[0,-1,1,0],[0,-1,0,1],[0,0,-1,1]])
N = 1000
FGW(n,p,mu,sigma,N,C2 = C2)
====================Method: FGW=====================
The Simultaneous Confidence Intervals are:
     The1th CIs            The2th CIs            The3th CIs
0  【-0.843638,0.789044】  【-0.629208,1.075959】  【-0.604469,1.158544】
**********************Time**************************
The cost time is:0 secs
====================Method: FGW=====================
The Simultaneous Confidence Intervals are:
     The1th CIs           The2th CIs           The3th CIs  \
0  【-0.912169,1.578679】  【-1.02404,0.812882】  【-0.83778,1.382352】

     The4th CIs            The5th CIs           The6th CIs
0  【-1.597962,0.650222】  【-1.337939,1.203199】  【-0.546039,1.25945】
**********************Time**************************
The cost time is:0 secs

  • FGH()

alpha = 0.05
p = np.array([0.2,0.2,0.2])
n = np.array([30,30,30])
mu = np.array([0,0,0])
sigma = np.array([1,1,1])
N = 1000
FGH(n,p,mu,sigma,N)
#Example2:
p = np.array([0.1,0.1,0.1,0.1])
n = np.array([30,30,30,30])
mu = np.array([0,0,0,0])
sigma = np.array([1,1,1,1])
C2 = np.array([[-1,1,0,0],[-1,0,1,0],[-1,0,0,1],[0,-1,1,0],[0,-1,0,1],[0,0,-1,1]])
N = 1000
FGH(n,p,mu,sigma,N,C2 = C2)
====================Method: FGH=====================
The Simultaneous Confidence Intervals are:
     The1th CIs            The2th CIs            The3th CIs
0  【-0.992276,1.455247】  【-0.703231,1.372774】  【-1.005873,1.124758】
**********************Time**************************
The cost time is:0 secs
====================Method: FGH=====================
The Simultaneous Confidence Intervals are:
    The1th CIs            The2th CIs            The3th CIs  \
0  【-1.62426,0.624984】  【-1.514528,0.553936】  【-1.565943,0.911157】

    The4th CIs            The5th CIs           The6th CIs
0  【-0.66646,1.010746】  【-0.829753,1.269381】  【-0.762683,1.07889】
**********************Time**************************
The cost time is:0 secs

  • MOVERW()

alpha = 0.05
p = np.array([0.2,0.2,0.2])
n = np.array([30,30,30])
mu = np.array([0,0,0])
sigma = np.array([1,1,1])
N = 1000
MOVERW(n,p,mu,sigma,N)
#Example2:
p = np.array([0.1,0.1,0.1,0.1])
n = np.array([30,30,30,30])
mu = np.array([0,0,0,0])
sigma = np.array([1,1,1,1])
C2 = np.array([[-1,1,0,0],[-1,0,1,0],[-1,0,0,1],[0,-1,1,0],[0,-1,0,1],[0,0,-1,1]])
N = 1000
MOVERW(n,p,mu,sigma,N,C2 = C2)
====================Method: FGH=====================
The Simultaneous Confidence Intervals are:
     The1th CIs            The2th CIs            The3th CIs
0  【-1.103496,1.211033】  【-1.030952,0.888781】  【-1.314926,1.059975】
**********************Time**************************
The cost time is:0 secs
====================Method: FGH=====================
The Simultaneous Confidence Intervals are:
    The1th CIs            The2th CIs            The3th CIs  \
0  【-1.68825,0.349316】  【-1.270833,1.236153】  【-1.304731,1.053776】

     The4th CIs            The5th CIs            The6th CIs
0  【-0.349427,1.679719】  【-0.364992,1.484843】  【-1.294225,1.071433】
**********************Time**************************
The cost time is:0 secs

  • MOVERH()

alpha = 0.05
p = np.array([0.2,0.2,0.2])
n = np.array([30,30,30])
mu = np.array([0,0,0])
sigma = np.array([1,1,1])
N = 1000
MOVERH(n,p,mu,sigma,N)
#Example2:
p = np.array([0.1,0.1,0.1,0.1])
n = np.array([30,30,30,30])
mu = np.array([0,0,0,0])
sigma = np.array([1,1,1,1])
C2 = np.array([[-1,1,0,0],[-1,0,1,0],[-1,0,0,1],[0,-1,1,0],[0,-1,0,1],[0,0,-1,1]])
N = 1000
MOVERH(n,p,mu,sigma,N,C2 = C2)
====================Method: FGH=====================
The Simultaneous Confidence Intervals are:
     The1th CIs            The2th CIs          The3th CIs
0  【-1.013305,0.765726】  【-1.152934,0.823283】  【-0.914194,0.8239】
**********************Time**************************
The cost time is:0 secs
====================Method: FGH=====================
The Simultaneous Confidence Intervals are:
     The1th CIs            The2th CIs           The3th CIs  \
0  【-0.681666,1.693927】  【-0.750657,1.458978】  【-1.21012,0.855608】

     The4th CIs            The5th CIs            The6th CIs
0  【-1.302431,1.003355】  【-1.762379,0.407925】  【-1.527028,0.467458】
**********************Time**************************
The cost time is:0 secs

Supports

Tested on Python 2.7, 3.5, 3.6

you can log in Xujing’s home page: https://dataxujing.coding.me or https://dataxujing.github.io to find the author(s), and if you want to learn more about simultaneous confidence intervals for the mixture distribution, you shou read the paper: Simulataneous Confidence Intervals for ratios of Means of Log-normal Populations with Zeros, which written by Jing Xu, Xinmin Li, and Hua Liang.

Project details

Verified details

These details have been verified by PyPI
Maintainers
Avatar for DataXujing from gravatar.com DataXujing

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These details have not been verified by PyPI
Project links
GitHub Statistics

View statistics for this project via Libraries.io, or by using our public dataset on Google BigQuery

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License: MIT License (Apache License, Version 2.0)

Author: Jing Xu, Xinmin Li, Hua Liang

Classifiers

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