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The '''binomial distribution''' with parameters <math>m</math> and <math>q</math> is the number of successes in a sequence of <math>m</math> independent yes/no experiments, each of which yields success with probability <math>q</math>. | The '''binomial distribution''' with parameters <math>m</math> and <math>q</math> is the number of successes in a sequence of <math>m</math> independent yes/no experiments, each of which yields success with probability <math>q</math>. | ||
A success/failure experiment is also called a Bernoulli experiment or [[ | A success/failure experiment is also called a Bernoulli experiment or [[Bernoulli trial|Bernoulli trial]]; when <math>m = 1</math>, the binomial distribution is a [[Bernoulli distribution|Bernoulli distribution]]. | ||
===Probability Mass Function === | ===Probability Mass Function === | ||
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In creating reference tables for binomial distribution probability, usually the table is filled in up to <math>m/2</math> values. This is because for <math>k \gt m/2</math>, the probability can be calculated by its complement as <math display="block">f(k,n,q)=f(n-k,n,1-q). </math> | In creating reference tables for binomial distribution probability, usually the table is filled in up to <math>m/2</math> values. This is because for <math>k \gt m/2</math>, the probability can be calculated by its complement as <math display="block">f(k,n,q)=f(n-k,n,1-q). </math> | ||
The probability mass function satisfies the following [[ | The probability mass function satisfies the following [[recurrence relation|recurrence relation]], for every <math>m,q</math> :<math display="block">\left\{\begin{array}{l} | ||
q (m-k) f(k,m,q) = (k+1) (1-q) | q (m-k) f(k,m,q) = (k+1) (1-q) | ||
f(k+1,m,q), \\ | f(k+1,m,q), \\ | ||
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==Poisson== | ==Poisson== | ||
In probability theory and statistics, the '''Poisson distribution''', named after French mathematician [[ | In probability theory and statistics, the '''Poisson distribution''', named after French mathematician [[Siméon Denis Poisson|Siméon Denis Poisson]], is a discrete probability distribution that expresses the probability of a given number of events occurring in a fixed interval of time and/or space if these events occur with a known average rate and independently of the time since the last event.<ref name=haight>{{cite book|author=Frank A. Haight|title=Handbook of the Poisson Distribution|publisher=John Wiley & Sons|location=New York|year=1967|ref=harv}}</ref> The Poisson distribution can also be used for the number of events in other specified intervals such as distance, area or volume. Within the context of insurance, the Poisson distribution can be used to model the number (frequency) of claims during a given time period. | ||
===Probability Mass Function === | ===Probability Mass Function === | ||
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A discrete random variable <math>N</math> is said to have a Poisson distribution with parameter <math>\lambda > 0</math>, if, for <math>k=0,1,2,...</math> the probability mass function of <math>N</math> is given by: <math display="block">\!p_k= \operatorname{P}(N = k)= \frac{\lambda^k e^{-\lambda}}{k!}.</math> | A discrete random variable <math>N</math> is said to have a Poisson distribution with parameter <math>\lambda > 0</math>, if, for <math>k=0,1,2,...</math> the probability mass function of <math>N</math> is given by: <math display="block">\!p_k= \operatorname{P}(N = k)= \frac{\lambda^k e^{-\lambda}}{k!}.</math> | ||
The probability mass function satisfies the following [[ | The probability mass function satisfies the following [[recurrence relation|recurrence relation]]:<math display="block">\left\{\begin{array}{l} | ||
(k+1) f(k+1)-\lambda f(k)=0, \\ | (k+1) f(k+1)-\lambda f(k)=0, \\ | ||
f(0)=e^{-\lambda} | f(0)=e^{-\lambda} | ||
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==Negative Binomial== | ==Negative Binomial== | ||
The '''negative binomial distribution''' is a discrete probability distribution of the number of failures in a sequence of independent and identically distributed [[ | The '''negative binomial distribution''' is a discrete probability distribution of the number of failures in a sequence of independent and identically distributed [[Bernoulli trial|Bernoulli trial]]s before a specified number of successes (denoted <math>r</math>) occurs. More precisely, suppose there is a sequence of independent Bernoulli trials. Thus, each trial has two potential outcomes called “success” and “failure”. In each trial the probability of failure is <math>q</math> and of success is <math>1 - q</math>. We are observing this sequence until a predefined number <math>r</math> of successes has occurred. | ||
===Probability Mass Function === | ===Probability Mass Function === | ||
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===Extension to real-valued ''r''=== | ===Extension to real-valued ''r''=== | ||
It is possible to extend the definition of the negative binomial distribution to the case of a positive [[ | It is possible to extend the definition of the negative binomial distribution to the case of a positive [[real number|real]] parameter <math>r</math>. Although it is impossible to visualize a non-integer number of “successes”, we can still formally define the distribution through its probability mass function. | ||
In the spirit of being consistent with the parametrizations found in <ref name="tables">https://www.soa.org/globalassets/assets/Files/Edu/2019/2019-02-exam-stam-tables.pdf</ref>, we consider the alternative parametrization defined implicitly by <math>q = \beta/(1+\beta)</math>. | In the spirit of being consistent with the parametrizations found in <ref name="tables">https://www.soa.org/globalassets/assets/Files/Edu/2019/2019-02-exam-stam-tables.pdf</ref>, we consider the alternative parametrization defined implicitly by <math>q = \beta/(1+\beta)</math>. | ||
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f(k; r, \beta) \equiv \operatorname{P}(N = k) = \binom{k+r-1}{k} \frac{\beta^k}{(1 + \beta)^{r + k}} \quad\text{for }k = 0, 1, 2, \dotsc | f(k; r, \beta) \equiv \operatorname{P}(N = k) = \binom{k+r-1}{k} \frac{\beta^k}{(1 + \beta)^{r + k}} \quad\text{for }k = 0, 1, 2, \dotsc | ||
</math> | </math> | ||
Here <math>r</math> is a real, positive number. The binomial coefficient is then defined by the [[ | Here <math>r</math> is a real, positive number. The binomial coefficient is then defined by the [[binomial coefficient#Multiplicative formula|multiplicative formula]] and can also be rewritten using the [[gamma function|gamma function]]:<math display="block"> | ||
\binom{k+r-1}{k} = \frac{(k+r-1)(k+r-2)\dotsm(r)}{k!} = \frac{\Gamma(k+r)}{k!\,\Gamma(r)}. | \binom{k+r-1}{k} = \frac{(k+r-1)(k+r-2)\dotsm(r)}{k!} = \frac{\Gamma(k+r)}{k!\,\Gamma(r)}. | ||
</math> | </math> | ||
To show that the probability mass function adds up to one, we have, by the [[ | To show that the probability mass function adds up to one, we have, by the [[binomial series|binomial series]] | ||
<math display="block"> | <math display="block"> | ||
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</math> | </math> | ||
Finally, the following [[ | Finally, the following [[recurrence relation|recurrence relation]] holds:<math display="block">\begin{array}{l} | ||
(k+1) \operatorname{P} (k+1)- q \operatorname{P} (k) (k+r)=0, \\ | (k+1) \operatorname{P} (k+1)- q \operatorname{P} (k) (k+r)=0, \\ | ||
\operatorname{P} (0) = (1-q)^r. | \operatorname{P} (0) = (1-q)^r. |
Latest revision as of 22:34, 6 April 2024
A frequency distribution is a discrete distribution that is supported on [math]\mathbb{N} = \{0,1,2,\ldots\}[/math]. Frequency distributions are useful in actuarial science since they can be used to model the number of insurance claims generated in a fixed time period.
(a, b, 0) Class
The distribution of a discrete random variable [math]N[/math] whose values are nonnegative integers is said to be a member of the (a, b, 0) class of distributions if its probability mass function obeys
where [math]p_k = \operatorname{P}(N = k)[/math] (provided [math]a[/math] and [math]b[/math] exist and are real). There are only three discrete distributions that satisfy the full form of this relationship: the Poisson, binomial and negative binomial distributions.
If a distribution belongs to the [math](a,b,0)[/math] class, then its mean equals [math](a + b)/(1 - a)[/math] and its variance equals [math](a+b)/(1−a)^2 [/math].
Show ProofSet [math]\mu = \operatorname{E}[N][/math] and [math]\mu_{(2)} = \operatorname{E}[N^2][/math]. We have
Hence [math] \mu_{(2)} = [a + b + \mu(2a + b)]/(1-a)[/math]. Using [math]\operatorname{Var}[N] = \mu_{(2)} - \mu^2[/math]:
(a, b, 1) Class
The (a,b,1) class of distributions is a family of discrete distributions related the (a,b,0) class in the sense that the probability mass function of any distribution belonging to that class satisfies the recurrence relation
Notice that the (a,b,1) class is not a subclass of (a,b,0) since we don't require that the recurrence relation hold for [math]k = 1[/math]. The (a,b,1) class is made up of two subclasses: the zero-truncated subclass and the zero-modified subclass.
The zero-truncated subclass
This class contains discrete distributions belonging to (a,b,1) with the additional property that no probability mass is attributed to the value 0. The probability mass function of any distribution belonging to this class will be denoted by [math]p_{k}^T[/math]; consequently, a random variable [math]N[/math] has a distribution contained in the zero-truncated subclass if and only if the following holds:
It is clear that every distribution in the zero truncated subclass can be obtained by conditioning a distribution from (a,b,0) to be non-zero.
The zero-modified subclass
This class contains discrete distributions belonging to (a,b,1) with the additional property that a positive mass is attributed to the value 0, i.e., the zero-modified subclass is the compliment of the zero-truncated subclass in (a,b,1). The probability mass function of any distribution belonging to this class will be denoted by [math]p_{k}^M[/math]; consequently, a random variable [math]N[/math] has a distribution contained in the zero-truncated subclass if and only if the following holds:
Notice that a distribution belonging to the zero-modified subclass doesn't necessarily belong to the (a,b,0) class since [math]p_0^M[/math] can be set independently of [math]p_1^M[/math]. The zero-modified subclass can be constructed from the zero-truncated subclass by the following procedure:
- Let [math]p_k^T[/math] be the probability mass function for a zero-truncated distribution.
- Set [math]p_k^M = p_k^T \cdot (1-p_0^M)[/math] for [math]k \geq 1[/math] with [math]0 \lt p_0^M \leq 1[/math], then [math]p_k^M[/math] is the probability mass function of a zero-modified distribution.
Binomial
The binomial distribution with parameters [math]m[/math] and [math]q[/math] is the number of successes in a sequence of [math]m[/math] independent yes/no experiments, each of which yields success with probability [math]q[/math]. A success/failure experiment is also called a Bernoulli experiment or Bernoulli trial; when [math]m = 1[/math], the binomial distribution is a Bernoulli distribution.
Probability Mass Function
In general, if the random variable [math]N[/math] follows the binomial distribution with parameters [math]m \in \mathbb{N}[/math] and [math]q \in [0,1][/math], we write [math]N \sim \operatorname{B}(m,q)[/math]. The probability of getting exactly [math]k[/math] successes in [math]m[/math] trials is given by the probability mass function:
for [math]k=0,1,2,...,m[/math], where
is the binomial coefficient, hence the name of the distribution. The formula can be understood as follows: we want exactly [math]k[/math] successes ([math]q^k[/math]) and [math]m-k[/math] failures ([math](1 - q)^{m-k}[/math]). However, the [math]k[/math] successes can occur anywhere among the [math]m[/math] trials, and there are [math]{n\choose k}[/math] different ways of distributing [math]k[/math] successes in a sequence of [math]m[/math] trials.
In creating reference tables for binomial distribution probability, usually the table is filled in up to [math]m/2[/math] values. This is because for [math]k \gt m/2[/math], the probability can be calculated by its complement as
The probability mass function satisfies the following recurrence relation, for every [math]m,q[/math] :
i.e., a binomial distribution belongs to the [math](a,b,0)[/math] class with [math] a = -q/(1-q) [/math] and [math] b = (m + 1)q/(1-q)[/math].
Poisson
In probability theory and statistics, the Poisson distribution, named after French mathematician Siméon Denis Poisson, is a discrete probability distribution that expresses the probability of a given number of events occurring in a fixed interval of time and/or space if these events occur with a known average rate and independently of the time since the last event.[1] The Poisson distribution can also be used for the number of events in other specified intervals such as distance, area or volume. Within the context of insurance, the Poisson distribution can be used to model the number (frequency) of claims during a given time period.
Probability Mass Function
A discrete random variable [math]N[/math] is said to have a Poisson distribution with parameter [math]\lambda \gt 0[/math], if, for [math]k=0,1,2,...[/math] the probability mass function of [math]N[/math] is given by:
The probability mass function satisfies the following recurrence relation:
i.e., a poisson distribution belongs to the [math](a,b,0)[/math] class with [math] a = 0 [/math] and [math] b = \lambda[/math].
Negative Binomial
The negative binomial distribution is a discrete probability distribution of the number of failures in a sequence of independent and identically distributed Bernoulli trials before a specified number of successes (denoted [math]r[/math]) occurs. More precisely, suppose there is a sequence of independent Bernoulli trials. Thus, each trial has two potential outcomes called “success” and “failure”. In each trial the probability of failure is [math]q[/math] and of success is [math]1 - q[/math]. We are observing this sequence until a predefined number [math]r[/math] of successes has occurred.
Probability Mass Function
The probability mass function of the negative binomial distribution is
The binomial coefficient can be written in the following manner, explaining the name “negative binomial”:
To understand the above definition of the probability mass function, note that the probability for every specific sequence of [math]k[/math] failures and [math]r[/math] successes is [math](1-q)^rq^k[/math], because the outcomes of the [math]k[/math] trials are supposed to happen independently. Since the [math]r[/math]th success comes last, it remains to choose the [math]k[/math] trials with failures out of the remaining [math]r-1[/math] trials. The above binomial coefficient gives precisely the number of all these sequences of length [math]k-1[/math].
Extension to real-valued r
It is possible to extend the definition of the negative binomial distribution to the case of a positive real parameter [math]r[/math]. Although it is impossible to visualize a non-integer number of “successes”, we can still formally define the distribution through its probability mass function.
In the spirit of being consistent with the parametrizations found in [2], we consider the alternative parametrization defined implicitly by [math]q = \beta/(1+\beta)[/math].
As before, we say that [math]N[/math] has a negative binomial (or Pólya) distribution if it has a probability mass function:
Here [math]r[/math] is a real, positive number. The binomial coefficient is then defined by the multiplicative formula and can also be rewritten using the gamma function:
To show that the probability mass function adds up to one, we have, by the binomial series
Finally, the following recurrence relation holds:
In particular, the negative binomial distribution belongs to the [math](a,b,0)[/math] class with [math] a = \beta/(1 + \beta)[/math] and [math] b = \beta(r-1)/(1 + \beta)[/math].
Geometric
The geometric distribution is the negative binomial distribution with [math]r = 1[/math] and can be interpreted (in the actuarial context) as the number of succeses before the first failure.
Summary
The following table summarizes key information regarding the distributions covered on this page:
Distribution | [math] \operatorname{P}[N=k]\, [/math] | [math] a\, [/math] | [math] b \,[/math] | [math] P(z)\, [/math] | [math] \operatorname{E}[N]\, [/math] | [math] \operatorname{Var}(N)\, [/math] |
---|---|---|---|---|---|---|
Binomial | [math] \binom{n}{k} q^k (1-q)^{n-k} [/math] | [math] \frac{-q}{1-q} [/math] | [math] \frac{q(n+1)}{1-q} [/math] | [math] [qz+(1-q)]^{n} \,[/math] | [math] nq\, [/math] | [math] nq(1-q) \,[/math] |
Poisson | [math] e^{-\lambda}\frac{ \lambda^k}{k!}\, [/math] | [math] 0\, [/math] | [math] \lambda \,[/math] | [math] e^{\lambda(z-1)} \,[/math] | [math] \lambda\, [/math] | [math] \lambda \,[/math] |
Negative Binomial | [math] (-1)^k \binom{-r}{k}\frac{\beta^k}{(1 + \beta)^{r + k}} [/math] | [math] \frac{\beta}{1 + \beta}[/math] | [math] \frac{\beta(r-1)}{1 + \beta}\, [/math] | [math] [1−\beta(z−1)]^{−r}[/math] | [math] r\beta [/math] | [math] r\beta (1 + \beta)[/math] |
Notes
- Frank A. Haight (1967). Handbook of the Poisson Distribution. New York: John Wiley & Sons.CS1 maint: ref=harv (link)
- https://www.soa.org/globalassets/assets/Files/Edu/2019/2019-02-exam-stam-tables.pdf
References
- Wikipedia contributors. "Probability distribution". Wikipedia. Wikipedia. Retrieved 5 June 2019.
- Wikipedia contributors. "Binomial distribution". Wikipedia. Wikipedia. Retrieved 5 June 2019.
- Wikipedia contributors. "Negative binomial distribution". Wikipedia. Wikipedia. Retrieved 5 June 2019.
- Wikipedia contributors. "Geometric distribution". Wikipedia. Wikipedia. Retrieved 5 June 2019.
- Wikipedia contributors. "Poisson distribution". Wikipedia. Wikipedia. Retrieved 5 June 2019.
- Wikipedia contributors. "(a,b,0) class of distributions". Wikipedia. Wikipedia. Retrieved 5 June 2019.