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LDR 5301-22.01.00-1B23-S1, Methods of Analysis for Business Operations•Unit IV Essay

Connie StanleyTotal Score: High risk80%Submission UUID: f340538d-e0b6-61ad-e982-abb88dbf7e53Total Score

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  1

  NORMAL, POISSON, AND EXPONENTIAL DISTRIBUTIONS 2 Normal, Poisson, and Exponential Distributions

  Connie Stanley

  1

  Columbia Southern University

  September 3, 2022

  1

  The differences between Poisson, Normal, and Exponential Distributions

  2

  Continuous random variables and discrete random variables are the two types of random variables.

  As a result, there are two kinds of continuous distributions:

  3

  probability distributions and discrete probability distributions.

  4

  The exponential and normal distributions are continuous distributions, whereas the Poisson distribution is discontinuous.

  Any statistician must understand their definition, qualities, and application in real-world circumstances.

  5

  As a result, this essay analyzes the significant differences between the normal, exponential, and Poisson distributions.

  1

  Furthermore, it provides a full explanation of the exponential distribution while discussing the conditions in which it is useful for data analysis and one real-world application.

  Equivalent distribution

  1

  The time between events in a toxic process is represented by the exponential distribution, a kind of continuous probability distribution (Australian Mathematical Sciences Institute (AMSI), 2020).

  3

  In essence, it denotes the amount of time that must pass following one occurrence before the next can take place.

  Its mathematical formula is:

  1

  f(x) = ex Where e is the base of natural logarithms and equals 2.718, x is the random variable, is the average number of units, and is the average number of units.

  6

  The following formula represents the probability distribution function (pdf) of x:

  3

  fx(x) = {µe−µxif x>0 0otherwise

  The exponential distribution is crucial for predicting radioactive decay, detecting the spread of a novel disease like COVID-19 among a broader population, and evaluating internet packet data.

  They deal with information that occurs over time periods such a day, a day, a month, a term, and a year.

  6

  For instance, we may utilize exponential distribution to examine how many births take place in a particular hospital across the nation.

  If we assume that X is the space in time between hospital births, with a 30-day median, then.

  1

  Once more under the presumption that the distribution of births is exponential, every birth is treated as a single birth regardless of whether it is triplets or twins. In this situation, a single day with an aggregate becomes the unit of time of birth after every 30 days as µ =.

  Thus X d = exp( ) and fx(x) = 301 e−301 xif x>0{

  else

  The outcomes are as follows when using the exponential distribution's mean and variance properties:

  1

  αx = E(X) = 30 days (for mean) σ2x = var(X) = 900 σx = sd(X) = 30 days

  Using the preceding results, the following basic formula can be used to calculate the likelihood of giving birth within the next 15 days:

  7

  −1 x for x ?0

  1

  Fx(x) = 1- e 30 As a result, the likelihood that the waiting period for the next birth will be fifteen days in the following fifteen days is provided by: Fx(15) = 1 - e for x ?0 = 1 - e−0.5 = 0.39346

  The below graph of f(x) versus x will be used to show the example:x

  Because the process does not retain memories of previous events, the exponential distribution has the characteristic of lacking memory, and the helping time distribution surpasses that length of time at x = 0.

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  It produces a result of zero when the random variable x is negative or less than zero.

  The aforementioned findings can be used in my company to investigate the rate of sales since they can be used to examine daily sales patterns.

  1

  The time between sales, which is typically 12 hours, can represent the random variable T. In calculating the chances of making the following sale in the next hour, 2 hours, or ten hours, it will adhere to the example given. The Significant Differences The normality test is a continuous symmetric probability distribution with a central limit theorem. According to the Australian Mathematical Sciences Institute (2020), if X has a Normally distributed with mean and standard deviation, we write X d = N(, 2); the probability density function of X is provided by: fx(x) = for x ∈ ℝ.

  3

  In contrast to the Poisson and exponential distributions, the normal probability features a bell curve with a symmetric probability distribution that has one peak at the position x =.

  1

  The Poisson distribution only considers occurrences with a set duration (Zhao et al., 2020). The time between events in a toxic process, however, is represented by the exponential distribution.

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  Once more, the exponential and normal distributions are continuous, whereas the Poisson distribution is discontinuous.

  3

  The Poisson and exponential distributions each have one pdf, whereas the normal distribution contains two pdfs with two inflection points of distinct signs: x = and x = +.

  References

  3

  Australian Mathematical Sciences Institute (AMSI), (2020).

  8

  Probability and Statistics:

  1

  Module 22 on Exponential and Normal Distributions. Zhao, J., Zhang, F., Zhao, C., Wu, G., Wang, H., & Cao, X.

  (2020, May).

  1

  The Properties and Application of Poisson Distribution. In Journal of Physics:

  Conference Series This study source was downloaded by 100000848136341 from CourseHero.com on 08-31-2022 15:05:18 GMT -05:00

  https://www.coursehero.com/file/84832081/Unit-IV-Essay-MSL-5080docx/

  Source Matches (29)
  • 1Student paper94%

    Student paper

    NORMAL, POISSON, AND EXPONENTIAL DISTRIBUTIONS 2 Normal, Poisson, and Exponential Distributions

    Original source

    Normal, Poisson, and Exponential Distributions Normal, Poisson, and Exponential Distributions

  • 1Student paper100%

    Student paper

    Columbia Southern University

    Original source

    Columbia Southern University

  • 1Student paper83%

    Student paper

    The differences between Poisson, Normal, and Exponential Distributions

    Original source

    Normal, Poisson, and Exponential Distributions

  • 2Student paper76%

    Student paper

    Continuous random variables and discrete random variables are the two types of random variables.

    Original source

    Continuous random variables are classified two different ways, either continuous random variables or discrete random variables

  • 3Student paper89%

    Student paper

    probability distributions and discrete probability distributions.

    Original source

    That creates probability distributions and discrete probability distributions

  • 4Student paper74%

    Student paper

    The exponential and normal distributions are continuous distributions, whereas the Poisson distribution is discontinuous.

    Original source

    Normal and exponential are both continuous distributions whereas Poisson distribution is discrete and always changing

  • 5Student paper68%

    Student paper

    As a result, this essay analyzes the significant differences between the normal, exponential, and Poisson distributions.

    Original source

    In this this essay, I will discuss the major differences between normal, exponential, and Poisson distributions

  • 1Student paper71%

    Student paper

    Furthermore, it provides a full explanation of the exponential distribution while discussing the conditions in which it is useful for data analysis and one real-world application.

    Original source

    Besides, it provides a detailed explanation of exponential distribution while describing the situations in which it is useful for analyzing data and one real-world example of its application

  • 1Student paper84%

    Student paper

    The time between events in a toxic process is represented by the exponential distribution, a kind of continuous probability distribution (Australian Mathematical Sciences Institute (AMSI), 2020).

    Original source

    The exponential distribution is a type of continuous probability distribution that represents the time between events in a poison process (Australian Mathematical Sciences Institute (AMSI), 2020)

  • 3Student paper63%

    Student paper

    In essence, it denotes the amount of time that must pass following one occurrence before the next can take place.

    Original source

    For one thing, it stands for the amount of time that must pass before something else can take place

  • 1Student paper85%

    Student paper

    f(x) = ex Where e is the base of natural logarithms and equals 2.718, x is the random variable, is the average number of units, and is the average number of units.

    Original source

    f(x) = µ Where x is the random variable, µ is the average number of units, and e is the base of natural logarithms and it equals to 2.718

  • 6Student paper71%

    Student paper

    The following formula represents the probability distribution function (pdf) of x:

    Original source

    Thus the probability distribution function (pdf) of x is

  • 3Student paper64%

    Student paper

    fx(x) = {µe−µxif x>0 0otherwise

    Original source

    fx (x) = { 1 e 1 x if x>0 30 30 0otherwise

  • 6Student paper67%

    Student paper

    For instance, we may utilize exponential distribution to examine how many births take place in a particular hospital across the nation.

    Original source

    For instance, we can utilize exponential distribution to study the amount of births that take place in a hospital in our country

  • 1Student paper73%

    Student paper

    Once more under the presumption that the distribution of births is exponential, every birth is treated as a single birth regardless of whether it is triplets or twins. In this situation, a single day with an aggregate becomes the unit of time of birth after every 30 days as µ =.

    Original source

    Again, with the assumption that the distribution between the births is exponential and does not consider birth of triplets or twins but treats every birth as a single birth In this case, the unit time becomes a day with an average of birth after every 30 days as µ =

  • 1Student paper81%

    Student paper

    αx = E(X) = 30 days (for mean) σ2x = var(X) = 900 σx = sd(X) = 30 days

    Original source

    αx = E(X) = 30 days (for mean) σ2x = var(X) = 900

  • 7dokumen80%

    Student paper

    −1 x for x ?0

    Original source

    x 1 0

  • 1Student paper76%

    Student paper

    Fx(x) = 1- e 30 As a result, the likelihood that the waiting period for the next birth will be fifteen days in the following fifteen days is provided by: Fx(15) = 1 - e for x ?0 = 1 - e−0.5 = 0.39346

    Original source

    Fx(x) = 1- for x Therefore in the next fifteen days the probability that with waiting time for the next birth will be fifteen days is given by Fx(15) = 1 - for x = 1 - = 0.39346

  • 1Student paper84%

    Student paper

    It produces a result of zero when the random variable x is negative or less than zero.

    Original source

    Where the random variable x is negative or less than zero, it returns a zero result

  • 1Student paper71%

    Student paper

    The time between sales, which is typically 12 hours, can represent the random variable T. In calculating the chances of making the following sale in the next hour, 2 hours, or ten hours, it will adhere to the example given. The Significant Differences The normality test is a continuous symmetric probability distribution with a central limit theorem. According to the Australian Mathematical Sciences Institute (2020), if X has a Normally distributed with mean and standard deviation, we write X d = N(, 2);

    Original source

    The random variable T can be the interval between sales, and the average time for sales is 12 hours It will follow the example provided in determining the probability of making the next sale within an hour, two hours, or ten hours The normal distribution is symmetric continuous probability distribution of a central limit theorem Australian Mathematical Sciences Institute (2020) defines that If X has a Normal distribution with mean µ and standard deviation σ, then we write that X d = N(µ,σ 2 )

  • 1Student paper92%

    Student paper

    the probability density function of X is provided by: fx(x) = for x ∈ ℝ.

    Original source

    the probability density function of X is given by fx(x) = for x ∈ ℝ

  • 3Student paper82%

    Student paper

    In contrast to the Poisson and exponential distributions, the normal probability features a bell curve with a symmetric probability distribution that has one peak at the position x =.

    Original source

    Unlike Poisson and exponential distributions, normal probability has a symmetric bell curve with one peak at x =

  • 1Student paper68%

    Student paper

    The Poisson distribution only considers occurrences with a set duration (Zhao et al., 2020). The time between events in a toxic process, however, is represented by the exponential distribution.

    Original source

    Poisson distribution only deals with events that have a fixed period of time (Zhao et al., 2020) However, the exponential distribution represents the time between events in a poison process

  • 4Student paper73%

    Student paper

    Once more, the exponential and normal distributions are continuous, whereas the Poisson distribution is discontinuous.

    Original source

    Normal and exponential are both continuous distributions whereas Poisson distribution is discrete and always changing

  • 3Student paper82%

    Student paper

    The Poisson and exponential distributions each have one pdf, whereas the normal distribution contains two pdfs with two inflection points of distinct signs: x = and x = +.

    Original source

    Normal distribution pdf contains two inflection points with different signs x = and x = +

  • 3Student paper100%

    Student paper

    Australian Mathematical Sciences Institute (AMSI), (2020).

    Original source

    Australian Mathematical Sciences Institute (AMSI), (2020)

  • 8wikipedia100%

    Student paper

    Probability and Statistics:

    Original source

    Probability and statistics

  • 1Student paper100%

    Student paper

    Module 22 on Exponential and Normal Distributions. Zhao, J., Zhang, F., Zhao, C., Wu, G., Wang, H., & Cao, X.

    Original source

    Module 22 on Exponential and Normal Distributions Zhao, J., Zhang, F., Zhao, C., Wu, G., Wang, H., & Cao, X

  • 1Student paper100%

    Student paper

    The Properties and Application of Poisson Distribution. In Journal of Physics:

    Original source

    The Properties and Application of Poisson Distribution In Journal of Physics