Examples of Bernoulli Trial in the following topics:
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- This chapter explores Bernoulli experiments and the probability distributions of binomial random variables.
- Such a success/failure experiment is also called a Bernoulli experiment, or Bernoulli trial; when $n=1$, the Bernoulli distribution is a binomial distribution.
- In a sequence of Bernoulli trials, we are often interested in the total number of successes and not in the order of their occurrence.
- If we let the random variable $X$ equal the number of observed successes in $n$ Bernoulli trials, the possible values of $X$ are $0, 1, 2, \dots, n$.
- Since the trials are independent and since the probabilities of success and failure on each trial are, respectively, $p$ and $q=1-p$, the probability of each of these ways is $p^x(1-p)^{n-x}$.
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- The binomial distribution is the probability distribution of the number of successes for one of just two categories in $n$ independent Bernoulli trials, with the same probability of success on each trial.
- In a multinomial distribution, the analog of the Bernoulli distribution is the categorical distribution, where each trial results in exactly one of some fixed finite number $k$ of possible outcomes, with probabilities $p_1, \cdots , p_k$ (so that $p_i \geq 0$ for $i = 1, \cdots, k$ and the sum is $1$), and there are $n$ independent trials.
- Then if the random variables Xi indicate the number of times outcome number $i$ is observed over the $n$ trials, the vector $X = (X_1, \cdots , X_k)$ follows a multinomial distribution with parameters $n$ and $p$, where $p = (p_1, \cdots , p_k)$.
- There are $k$ possible outcomes for each trial.
- The probabilities of the $k$ outcomes, denoted by $p_1$, $p_2$, $\cdots$, $p_k$, remain the same from trial to trial, and they sum to one.
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- The binomial distribution is a special case of the Poisson binomial distribution, which is a sum of n independent non-identical Bernoulli trials Bern(pi).
- Using the definition of covariance, in the case n = 1 (thus being Bernoulli trials) we have .
- Defining pB as the probability of both happening at the same time, this gives and for n independent pairwise trials .
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- There are a fixed number of trials.
- Because the n trials are independent, the outcome of one trial does not help in predicting the outcome of another trial.
- Any experiment that has characteristics 2 and 3 and where n = 1 is called a Bernoulli Trial (named after Jacob Bernoulli who, in the late 1600s, studied them extensively).
- A binomial experiment takes place when the number of successes is counted in one or more Bernoulli Trials.
- The number of trial is n = 50.
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- A hypergeometric random variable is a discrete random variable characterized by a fixed number of trials with differing probabilities of success.
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- Determine if each trial can be considered an independent Bernouilli trial for the following situations.
- The Bernoulli distribution allows for only two events or categories.
- Note that rolling a die could be a Bernoulli trial if we simply to two events, e.g. rolling a 6 and not rolling a 6, though specifying such details would be necessary.
- (e) When p is smaller, the event is rarer, meaning the expected number of trials before a success and the standard deviation of the waiting time are higher.
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- Each person in Milgram's experiment can be thought of as a trial.
- When an indi- vidual trial only has two possible outcomes, it is called a Bernoulli random variable.
- A Bernoulli random variable has exactly two possible outcomes.
- Bernoulli random variables are often denoted as 1 for a success and 0 for a failure.
- Suppose we observe ten trials: 0 1 1 1 1 0 1 1 0 0
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- The Bernoulli distribution allows for only two events or categories.
- Note that rolling a die could be a Bernoulli trial if we simply to two events, e.g. rolling a 6 and not rolling a 6, though specifying such details would be neces- sary.
- The conditions are satisfied: independence, fixed number of trials, either success or failure for each trial, and probability of success being constant across trials.
- The negative binomial setting is appropriate since the last trial is fixed but the order of the first 3 trials is unknown.
- In the negative binomial model the last trial is fixed.
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- We first formalize each trial – such as a single coin flip or die toss – using the Bernoulli distribution, and then we combine these with our tools from probability (Chapter 2) to construct the geometric distribution.
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- The relationship between pressure and velocity in ideal fluids is described quantitatively by Bernoulli's equation, named after its discoverer, the Swiss scientist Daniel Bernoulli (1700–1782).
- This simply adds another term to the above version of the Bernoulli equation and results in
- Bernoulli's equation can be applied when syphoning fluid between two reservoirs .
- The Bernoulli equation can be adapted to flows that are both unsteady and compressible.
- Adapt Bernoulli's equation for flows that are either unsteady or compressible