SlideShare a Scribd company logo

A random variable may assume any value between 10 and 50 with equal .pdf

R
ramjadhavrt4

A random variable may assume any value between 10 and 50 with equal likelihoods. (Uniform distribution) Determine the following values for this probability distribution: a) µ b) s c) f(x) = d) P(x < 25) e) P(x > 15) f) P( 12 < x < 30) Solution The distribution of a random variable X for which the probability density function f is given by The parameters µ and s2 are, respectively, the mean and variance of the distribution. The distribution is denoted by N(µ, s2). If the random variable X has such a distribution, then this is denoted by X ~ N(µ, s2) and the random variable may be referred to as a normal variable. The graph of f(x) approaches the x-axis extremely quickly, and is effectively zero if |x-µ| < 3s (hence the three-sigma rule). In fact, P(|X-µ| < 2s)˜95.5% and P(|X-µ| < 3s)˜99.7%. The first derivation of the form of f is believed to be that of de Moivre in 1733. The description \'normal distribution\' was used by Galton in 1889, whereas \'Gaussian distribution\' was used by Karl Pearson in 1905. The normal distribution is the basis of a large proportion of statistical analysis. Its importance and ubiquity are largely a consequence of the Central Limit Theorem, which implies that averaging almost always leads to a bell-shaped distribution (hence the name \'normal\'). See bell-curve. Normal distribution. The diagram illustrates the probability density function of a normal random variable X having expectation µ and variance s2. The distribution has mean, median, and mode at x=µ, where the density function has value 1/(svp). Note that almost all the distribution (99.7%) lies within 3s of the central value. The standard normal distribution has mean 0 and variance 1. A random variable with this distribution is often denoted by Z and we write Z ~ N(0, 1). Its probability density function is usually denoted by ? and is given by If X has a general normal distribution N(µ, s2) then Z, defined by the standardizing transformation has a standard normal distribution. It follows that the graph of the probability density function of X is obtained from the corresponding graph for Z by a stretch parallel to the z-axis, with centre at the origin and scale-factor s, followed by a translation along the z-axis by µ. Standard normal distribution. The distribution is centred on 0, with 99.7% falling between -3 and 3 and 95% falling between -1.96 and 1.96. The cumulative probability function of Z is usually denoted by F and tables of values of F(z) are commonly available (see The Standard Normal Distribution Function; see also Upper-Tail Percentage Points for the Standard Normal Distribution). These tables usually give F(z) only for z>0, since values for negative values of z can be found using F(z)=1-F(-z).The tables can be used to find cumulative probabilities for X ~ N(µ, s2) via the standardizing transformation given above, since, for example, As an example, if X ~ N(7, 25) then the probability of X taking a value between 5 and 10 is given by The normal d.

Education
1 of 2
Download to read offline
A random variable may assume any value between 10 and 50 with equal likelihoods. (Uniform distribution) Determine the following values for this probability distribution: a) µ b) s c) f(x) = d) P(x < 25) e) P(x > 15) f) P( 12 < x < 30) Solution The distribution of a random variable X for which the probability density function f is given by The parameters µ and s2 are, respectively, the mean and variance of the distribution. The distribution is denoted by N(µ, s2). If the random variable X has such a distribution, then this is denoted by X ~ N(µ, s2) and the random variable may be referred to as a normal variable. The graph of f(x) approaches the x-axis extremely quickly, and is effectively zero if |x-µ| < 3s (hence the three-sigma rule). In fact, P(|X-µ| < 2s)˜95.5% and P(|X-µ| < 3s)˜99.7%. The first derivation of the form of f is believed to be that of de Moivre in 1733. The description 'normal distribution' was used by Galton in 1889, whereas 'Gaussian distribution' was used by Karl Pearson in 1905. The normal distribution is the basis of a large proportion of statistical analysis. Its importance and ubiquity are largely a consequence of the Central Limit Theorem, which implies that averaging almost always leads to a bell-shaped distribution (hence the name 'normal'). See bell-curve. Normal distribution. The diagram illustrates the probability density function of a normal random variable X having expectation µ and variance s2. The distribution has mean, median, and mode at x=µ, where the density function has value 1/(svp). Note that almost all the distribution (99.7%) lies within 3s of the central value. The standard normal distribution has mean 0 and variance 1. A random variable with this distribution is often denoted by Z and we write Z ~ N(0, 1). Its probability density function is usually
denoted by ? and is given by If X has a general normal distribution N(µ, s2) then Z, defined by the standardizing transformation has a standard normal distribution. It follows that the graph of the probability density function of X is obtained from the corresponding graph for Z by a stretch parallel to the z-axis, with centre at the origin and scale-factor s, followed by a translation along the z-axis by µ. Standard normal distribution. The distribution is centred on 0, with 99.7% falling between -3 and 3 and 95% falling between -1.96 and 1.96. The cumulative probability function of Z is usually denoted by F and tables of values of F(z) are commonly available (see The Standard Normal Distribution Function; see also Upper-Tail Percentage Points for the Standard Normal Distribution). These tables usually give F(z) only for z>0, since values for negative values of z can be found using F(z)=1-F(-z).The tables can be used to find cumulative probabilities for X ~ N(µ, s2) via the standardizing transformation given above, since, for example, As an example, if X ~ N(7, 25) then the probability of X taking a value between 5 and 10 is given by The normal distribution plays a central part in the theory of errors that was developed by Gauss. In the theory of errors, the error function (erf) is defined by erf(x)=2F(xv2)- 1.An important property of the normal distribution is that any linear combination of independent normal variables is normal: if are independent, and a and b are constants, thenaX1+bX2~N(aµ1+bµ2,a2s21+b2s22),with the obvious generalization to n independent normal variables. Many distributions can be approximated by a normal distribution for suitably large values of the relevant parameters. See also binomial distribution; chi-squared distribution; Poisson distribution; t-distribution.

Recommended

Econometrics 2.pptx
Econometrics 2.pptxEconometrics 2.pptx
Econometrics 2.pptx
fuad80
 
Multivariate Gaussin, Rayleigh & Rician distributions
Multivariate Gaussin, Rayleigh & Rician distributionsMultivariate Gaussin, Rayleigh & Rician distributions
Multivariate Gaussin, Rayleigh & Rician distributions
HAmindavarLectures
 
Distributions
DistributionsDistributions
Distributions
adnan gilani
 
Continuous random variables and probability distribution
Continuous random variables and probability distributionContinuous random variables and probability distribution
Continuous random variables and probability distribution
pkwilambo
 
Appendix 2 Probability And Statistics
Appendix 2 Probability And StatisticsAppendix 2 Probability And Statistics
Appendix 2 Probability And Statistics
Sarah Morrow
 
Normal distribution
Normal distributionNormal distribution
Normal distribution
Alok Roy
 
Probability and Statistics
Probability and StatisticsProbability and Statistics
Probability and Statistics
Malik Sb
 
Dr. IU Khan Assignment
Dr. IU Khan AssignmentDr. IU Khan Assignment
Dr. IU Khan Assignment
khadeeja ikram01
 

Recommended

Econometrics 2.pptx
Econometrics 2.pptxEconometrics 2.pptx
Econometrics 2.pptx
fuad80
 
Multivariate Gaussin, Rayleigh & Rician distributions
Multivariate Gaussin, Rayleigh & Rician distributionsMultivariate Gaussin, Rayleigh & Rician distributions
Multivariate Gaussin, Rayleigh & Rician distributions
HAmindavarLectures
 
Distributions
DistributionsDistributions
Distributions
adnan gilani
 
Continuous random variables and probability distribution
Continuous random variables and probability distributionContinuous random variables and probability distribution
Continuous random variables and probability distribution
pkwilambo
 
Appendix 2 Probability And Statistics
Appendix 2 Probability And StatisticsAppendix 2 Probability And Statistics
Appendix 2 Probability And Statistics
Sarah Morrow
 
Normal distribution
Normal distributionNormal distribution
Normal distribution
Alok Roy
 
Probability and Statistics
Probability and StatisticsProbability and Statistics
Probability and Statistics
Malik Sb
 
Dr. IU Khan Assignment
Dr. IU Khan AssignmentDr. IU Khan Assignment
Dr. IU Khan Assignment
khadeeja ikram01
 
Dr. iu khan assignment
Dr. iu khan assignmentDr. iu khan assignment
Dr. iu khan assignment
khadeeja ikram01
 
The Normal Distribution.ppt
The Normal Distribution.pptThe Normal Distribution.ppt
The Normal Distribution.ppt
Aravind Reddy
 
Ch3 Probability and The Normal Distribution
Ch3 Probability and The Normal Distribution Ch3 Probability and The Normal Distribution
Ch3 Probability and The Normal Distribution
Farhan Alfin
 
New test123
New test123New test123
New test123
Imperial Business School
 
The Normal Probability Distribution
The Normal Probability DistributionThe Normal Probability Distribution
The Normal Probability Distribution
mandalina landy
 
this materials is useful for the students who studying masters level in elect...
this materials is useful for the students who studying masters level in elect...this materials is useful for the students who studying masters level in elect...
this materials is useful for the students who studying masters level in elect...
BhojRajAdhikari5
 
QT1 - 06 - Normal Distribution
QT1 - 06 - Normal DistributionQT1 - 06 - Normal Distribution
QT1 - 06 - Normal Distribution
Prithwis Mukerjee
 
QT1 - 06 - Normal Distribution
QT1 - 06 - Normal DistributionQT1 - 06 - Normal Distribution
QT1 - 06 - Normal Distribution
Prithwis Mukerjee
 
Calc 3.9a
Calc 3.9aCalc 3.9a
Calc 3.9a
hartcher
 
Calc 3.9a
Calc 3.9aCalc 3.9a
Calc 3.9a
hartcher
 
multivariate normal distribution.pdf
multivariate normal distribution.pdfmultivariate normal distribution.pdf
multivariate normal distribution.pdf
rishumaurya10
 
Probability distributionv1
Probability distributionv1Probability distributionv1
Probability distributionv1
Beatrice van Eden
 
Quadrature
QuadratureQuadrature
Quadrature
Linh Tran
 
Probility distribution
Probility distributionProbility distribution
Probility distribution
Vinya P
 
The Wishart and inverse-wishart distribution
The Wishart and inverse-wishart distribution The Wishart and inverse-wishart distribution
The Wishart and inverse-wishart distribution
Pankaj Das
 
Doe02 statistics
Doe02 statisticsDoe02 statistics
Doe02 statistics
Arif Rahman
 
APPLICATION OF PARTIAL DIFFERENTIATION
APPLICATION OF PARTIAL DIFFERENTIATIONAPPLICATION OF PARTIAL DIFFERENTIATION
APPLICATION OF PARTIAL DIFFERENTIATION
Dhrupal Patel
 
A generalisation of the ratio-of-uniform algorithm
A generalisation of the ratio-of-uniform algorithmA generalisation of the ratio-of-uniform algorithm
A generalisation of the ratio-of-uniform algorithm
Christian Robert
 
Probability concept and Probability distribution_Contd
Probability concept and Probability distribution_ContdProbability concept and Probability distribution_Contd
Probability concept and Probability distribution_Contd
Southern Range, Berhampur, Odisha
 
stochastic notes
stochastic notes stochastic notes
stochastic notes
cairo university
 
How to setup Pycharm environment for Odoo 17.pptx
How to setup Pycharm environment for Odoo 17.pptxHow to setup Pycharm environment for Odoo 17.pptx
How to setup Pycharm environment for Odoo 17.pptx
Celine George
 
Beyond_Borders_Understanding_Anime_and_Manga_Fandom_A_Comprehensive_Audience_...
Beyond_Borders_Understanding_Anime_and_Manga_Fandom_A_Comprehensive_Audience_...Beyond_Borders_Understanding_Anime_and_Manga_Fandom_A_Comprehensive_Audience_...
Beyond_Borders_Understanding_Anime_and_Manga_Fandom_A_Comprehensive_Audience_...
Pooja Bhuva
 

More Related Content

Similar to A random variable may assume any value between 10 and 50 with equal .pdf

The Normal Probability Distribution
The Normal Probability DistributionThe Normal Probability Distribution
The Normal Probability Distribution
mandalina landy
 
this materials is useful for the students who studying masters level in elect...
this materials is useful for the students who studying masters level in elect...this materials is useful for the students who studying masters level in elect...
this materials is useful for the students who studying masters level in elect...
BhojRajAdhikari5
 

Similar to A random variable may assume any value between 10 and 50 with equal .pdf (20)

Dr. iu khan assignment
Dr. iu khan assignmentDr. iu khan assignment
Dr. iu khan assignment
 
The Normal Distribution.ppt
The Normal Distribution.pptThe Normal Distribution.ppt
The Normal Distribution.ppt
 
Ch3 Probability and The Normal Distribution
Ch3 Probability and The Normal Distribution Ch3 Probability and The Normal Distribution
Ch3 Probability and The Normal Distribution
 
New test123
New test123New test123
New test123
 
The Normal Probability Distribution
The Normal Probability DistributionThe Normal Probability Distribution
The Normal Probability Distribution
 
this materials is useful for the students who studying masters level in elect...
this materials is useful for the students who studying masters level in elect...this materials is useful for the students who studying masters level in elect...
this materials is useful for the students who studying masters level in elect...
 
QT1 - 06 - Normal Distribution
QT1 - 06 - Normal DistributionQT1 - 06 - Normal Distribution
QT1 - 06 - Normal Distribution
 
QT1 - 06 - Normal Distribution
QT1 - 06 - Normal DistributionQT1 - 06 - Normal Distribution
QT1 - 06 - Normal Distribution
 
Calc 3.9a
Calc 3.9aCalc 3.9a
Calc 3.9a
 
Calc 3.9a
Calc 3.9aCalc 3.9a
Calc 3.9a
 
multivariate normal distribution.pdf
multivariate normal distribution.pdfmultivariate normal distribution.pdf
multivariate normal distribution.pdf
 
Probability distributionv1
Probability distributionv1Probability distributionv1
Probability distributionv1
 
Quadrature
QuadratureQuadrature
Quadrature
 
Probility distribution
Probility distributionProbility distribution
Probility distribution
 
The Wishart and inverse-wishart distribution
The Wishart and inverse-wishart distribution The Wishart and inverse-wishart distribution
The Wishart and inverse-wishart distribution
 
Doe02 statistics
Doe02 statisticsDoe02 statistics
Doe02 statistics
 
APPLICATION OF PARTIAL DIFFERENTIATION
APPLICATION OF PARTIAL DIFFERENTIATIONAPPLICATION OF PARTIAL DIFFERENTIATION
APPLICATION OF PARTIAL DIFFERENTIATION
 
A generalisation of the ratio-of-uniform algorithm
A generalisation of the ratio-of-uniform algorithmA generalisation of the ratio-of-uniform algorithm
A generalisation of the ratio-of-uniform algorithm
 
Probability concept and Probability distribution_Contd
Probability concept and Probability distribution_ContdProbability concept and Probability distribution_Contd
Probability concept and Probability distribution_Contd
 
stochastic notes
stochastic notes stochastic notes
stochastic notes
 

Recently uploaded

Making communications land - Are they received and understood as intended? we...
Making communications land - Are they received and understood as intended? we...Making communications land - Are they received and understood as intended? we...
Making communications land - Are they received and understood as intended? we...
Association for Project Management
 

Recently uploaded (20)

How to setup Pycharm environment for Odoo 17.pptx
How to setup Pycharm environment for Odoo 17.pptxHow to setup Pycharm environment for Odoo 17.pptx
How to setup Pycharm environment for Odoo 17.pptx
 
Beyond_Borders_Understanding_Anime_and_Manga_Fandom_A_Comprehensive_Audience_...
Beyond_Borders_Understanding_Anime_and_Manga_Fandom_A_Comprehensive_Audience_...Beyond_Borders_Understanding_Anime_and_Manga_Fandom_A_Comprehensive_Audience_...
Beyond_Borders_Understanding_Anime_and_Manga_Fandom_A_Comprehensive_Audience_...
 
ICT role in 21st century education and it's challenges.
ICT role in 21st century education and it's challenges.ICT role in 21st century education and it's challenges.
ICT role in 21st century education and it's challenges.
 
Jamworks pilot and AI at Jisc (20/03/2024)
Jamworks pilot and AI at Jisc (20/03/2024)Jamworks pilot and AI at Jisc (20/03/2024)
Jamworks pilot and AI at Jisc (20/03/2024)
 
Mehran University Newsletter Vol-X, Issue-I, 2024
Mehran University Newsletter Vol-X, Issue-I, 2024Mehran University Newsletter Vol-X, Issue-I, 2024
Mehran University Newsletter Vol-X, Issue-I, 2024
 
Making communications land - Are they received and understood as intended? we...
Making communications land - Are they received and understood as intended? we...Making communications land - Are they received and understood as intended? we...
Making communications land - Are they received and understood as intended? we...
 
Introduction to Nonprofit Accounting: The Basics
Introduction to Nonprofit Accounting: The BasicsIntroduction to Nonprofit Accounting: The Basics
Introduction to Nonprofit Accounting: The Basics
 
Fostering Friendships - Enhancing Social Bonds in the Classroom
Fostering Friendships - Enhancing Social Bonds in the ClassroomFostering Friendships - Enhancing Social Bonds in the Classroom
Fostering Friendships - Enhancing Social Bonds in the Classroom
 
2024-NATIONAL-LEARNING-CAMP-AND-OTHER.pptx
2024-NATIONAL-LEARNING-CAMP-AND-OTHER.pptx2024-NATIONAL-LEARNING-CAMP-AND-OTHER.pptx
2024-NATIONAL-LEARNING-CAMP-AND-OTHER.pptx
 
80 ĐỀ THI THỬ TUYỂN SINH TIẾNG ANH VÀO 10 SỞ GD – ĐT THÀNH PHỐ HỒ CHÍ MINH NĂ...
80 ĐỀ THI THỬ TUYỂN SINH TIẾNG ANH VÀO 10 SỞ GD – ĐT THÀNH PHỐ HỒ CHÍ MINH NĂ...80 ĐỀ THI THỬ TUYỂN SINH TIẾNG ANH VÀO 10 SỞ GD – ĐT THÀNH PHỐ HỒ CHÍ MINH NĂ...
80 ĐỀ THI THỬ TUYỂN SINH TIẾNG ANH VÀO 10 SỞ GD – ĐT THÀNH PHỐ HỒ CHÍ MINH NĂ...
 
Accessible Digital Futures project (20/03/2024)
Accessible Digital Futures project (20/03/2024)Accessible Digital Futures project (20/03/2024)
Accessible Digital Futures project (20/03/2024)
 
Single or Multiple melodic lines structure
Single or Multiple melodic lines structureSingle or Multiple melodic lines structure
Single or Multiple melodic lines structure
 
Application orientated numerical on hev.ppt
Application orientated numerical on hev.pptApplication orientated numerical on hev.ppt
Application orientated numerical on hev.ppt
 
Kodo Millet PPT made by Ghanshyam bairwa college of Agriculture kumher bhara...
Kodo Millet PPT made by Ghanshyam bairwa college of Agriculture kumher bhara...Kodo Millet PPT made by Ghanshyam bairwa college of Agriculture kumher bhara...
Kodo Millet PPT made by Ghanshyam bairwa college of Agriculture kumher bhara...
 
How to Give a Domain for a Field in Odoo 17
How to Give a Domain for a Field in Odoo 17How to Give a Domain for a Field in Odoo 17
How to Give a Domain for a Field in Odoo 17
 
Google Gemini An AI Revolution in Education.pptx
Google Gemini An AI Revolution in Education.pptxGoogle Gemini An AI Revolution in Education.pptx
Google Gemini An AI Revolution in Education.pptx
 
Unit-V; Pricing (Pharma Marketing Management).pptx
Unit-V; Pricing (Pharma Marketing Management).pptxUnit-V; Pricing (Pharma Marketing Management).pptx
Unit-V; Pricing (Pharma Marketing Management).pptx
 
Holdier Curriculum Vitae (April 2024).pdf
Holdier Curriculum Vitae (April 2024).pdfHoldier Curriculum Vitae (April 2024).pdf
Holdier Curriculum Vitae (April 2024).pdf
 
UGC NET Paper 1 Mathematical Reasoning & Aptitude.pdf
UGC NET Paper 1 Mathematical Reasoning & Aptitude.pdfUGC NET Paper 1 Mathematical Reasoning & Aptitude.pdf
UGC NET Paper 1 Mathematical Reasoning & Aptitude.pdf
 
Key note speaker Neum_Admir Softic_ENG.pdf
Key note speaker Neum_Admir Softic_ENG.pdfKey note speaker Neum_Admir Softic_ENG.pdf
Key note speaker Neum_Admir Softic_ENG.pdf
 

A random variable may assume any value between 10 and 50 with equal .pdf

  • 1. A random variable may assume any value between 10 and 50 with equal likelihoods. (Uniform distribution) Determine the following values for this probability distribution: a) µ b) s c) f(x) = d) P(x < 25) e) P(x > 15) f) P( 12 < x < 30) Solution The distribution of a random variable X for which the probability density function f is given by The parameters µ and s2 are, respectively, the mean and variance of the distribution. The distribution is denoted by N(µ, s2). If the random variable X has such a distribution, then this is denoted by X ~ N(µ, s2) and the random variable may be referred to as a normal variable. The graph of f(x) approaches the x-axis extremely quickly, and is effectively zero if |x-µ| < 3s (hence the three-sigma rule). In fact, P(|X-µ| < 2s)˜95.5% and P(|X-µ| < 3s)˜99.7%. The first derivation of the form of f is believed to be that of de Moivre in 1733. The description 'normal distribution' was used by Galton in 1889, whereas 'Gaussian distribution' was used by Karl Pearson in 1905. The normal distribution is the basis of a large proportion of statistical analysis. Its importance and ubiquity are largely a consequence of the Central Limit Theorem, which implies that averaging almost always leads to a bell-shaped distribution (hence the name 'normal'). See bell-curve. Normal distribution. The diagram illustrates the probability density function of a normal random variable X having expectation µ and variance s2. The distribution has mean, median, and mode at x=µ, where the density function has value 1/(svp). Note that almost all the distribution (99.7%) lies within 3s of the central value. The standard normal distribution has mean 0 and variance 1. A random variable with this distribution is often denoted by Z and we write Z ~ N(0, 1). Its probability density function is usually
  • 2. denoted by ? and is given by If X has a general normal distribution N(µ, s2) then Z, defined by the standardizing transformation has a standard normal distribution. It follows that the graph of the probability density function of X is obtained from the corresponding graph for Z by a stretch parallel to the z-axis, with centre at the origin and scale-factor s, followed by a translation along the z-axis by µ. Standard normal distribution. The distribution is centred on 0, with 99.7% falling between -3 and 3 and 95% falling between -1.96 and 1.96. The cumulative probability function of Z is usually denoted by F and tables of values of F(z) are commonly available (see The Standard Normal Distribution Function; see also Upper-Tail Percentage Points for the Standard Normal Distribution). These tables usually give F(z) only for z>0, since values for negative values of z can be found using F(z)=1-F(-z).The tables can be used to find cumulative probabilities for X ~ N(µ, s2) via the standardizing transformation given above, since, for example, As an example, if X ~ N(7, 25) then the probability of X taking a value between 5 and 10 is given by The normal distribution plays a central part in the theory of errors that was developed by Gauss. In the theory of errors, the error function (erf) is defined by erf(x)=2F(xv2)- 1.An important property of the normal distribution is that any linear combination of independent normal variables is normal: if are independent, and a and b are constants, thenaX1+bX2~N(aµ1+bµ2,a2s21+b2s22),with the obvious generalization to n independent normal variables. Many distributions can be approximated by a normal distribution for suitably large values of the relevant parameters. See also binomial distribution; chi-squared distribution; Poisson distribution; t-distribution.