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Probability Theory [electronic resource] : Independence Interchangeability Martingales /
Probability theory is a branch of mathematics dealing with chance phenomena and has clearly discernible links with the real world. The origins of the sub ject, generally attributed to investigations by the renowned french mathe matician Fermat of problems posed by a gambling contemporary to Pascal, have been pushed back a century earlier to the italian mathematicians Cardano and Tartaglia about 1570 (Ore, 1953). Results as significant as the Bernoulli weak law of large numbers appeared as early as 1713, although its counterpart, the Borel strong law oflarge numbers, did not emerge until 1909. Central limit theorems and conditional probabilities were already being investigated in the eighteenth century, but the first serious attempts to grapple with the logical foundations of probability seem to be Keynes (1921), von Mises (1928; 1931), and Kolmogorov (1933). An axiomatic mold and measure-theoretic framework for probability theory was furnished by Kolmogorov. In this so-called objective or measure theoretic approach, definitions and axioms are so chosen that the empirical realization of an event is the outcome of a not completely determined physical experiment -an experiment which is at least conceptually capable of indefi nite repetition (this notion is due to von Mises). The concrete or intuitive counterpart of the probability of an event is a long run or limiting frequency of the corresponding outcome.
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| Format: | Texto biblioteca |
| Language: | eng |
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New York, NY : Springer US,
1978
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| Subjects: | Mathematics., Probabilities., Probability Theory and Stochastic Processes., |
| Online Access: | http://dx.doi.org/10.1007/978-1-4684-0062-5 |
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Mathematics. Probabilities. Mathematics. Probability Theory and Stochastic Processes. Mathematics. Probabilities. Mathematics. Probability Theory and Stochastic Processes. |
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Mathematics. Probabilities. Mathematics. Probability Theory and Stochastic Processes. Mathematics. Probabilities. Mathematics. Probability Theory and Stochastic Processes. Chow, Yuan Shih. author. Teicher, Henry. author. SpringerLink (Online service) Probability Theory [electronic resource] : Independence Interchangeability Martingales / |
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Probability theory is a branch of mathematics dealing with chance phenomena and has clearly discernible links with the real world. The origins of the sub ject, generally attributed to investigations by the renowned french mathe matician Fermat of problems posed by a gambling contemporary to Pascal, have been pushed back a century earlier to the italian mathematicians Cardano and Tartaglia about 1570 (Ore, 1953). Results as significant as the Bernoulli weak law of large numbers appeared as early as 1713, although its counterpart, the Borel strong law oflarge numbers, did not emerge until 1909. Central limit theorems and conditional probabilities were already being investigated in the eighteenth century, but the first serious attempts to grapple with the logical foundations of probability seem to be Keynes (1921), von Mises (1928; 1931), and Kolmogorov (1933). An axiomatic mold and measure-theoretic framework for probability theory was furnished by Kolmogorov. In this so-called objective or measure theoretic approach, definitions and axioms are so chosen that the empirical realization of an event is the outcome of a not completely determined physical experiment -an experiment which is at least conceptually capable of indefi nite repetition (this notion is due to von Mises). The concrete or intuitive counterpart of the probability of an event is a long run or limiting frequency of the corresponding outcome. |
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Texto |
| topic_facet |
Mathematics. Probabilities. Mathematics. Probability Theory and Stochastic Processes. |
| author |
Chow, Yuan Shih. author. Teicher, Henry. author. SpringerLink (Online service) |
| author_facet |
Chow, Yuan Shih. author. Teicher, Henry. author. SpringerLink (Online service) |
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Chow, Yuan Shih. author. |
| title |
Probability Theory [electronic resource] : Independence Interchangeability Martingales / |
| title_short |
Probability Theory [electronic resource] : Independence Interchangeability Martingales / |
| title_full |
Probability Theory [electronic resource] : Independence Interchangeability Martingales / |
| title_fullStr |
Probability Theory [electronic resource] : Independence Interchangeability Martingales / |
| title_full_unstemmed |
Probability Theory [electronic resource] : Independence Interchangeability Martingales / |
| title_sort |
probability theory [electronic resource] : independence interchangeability martingales / |
| publisher |
New York, NY : Springer US, |
| publishDate |
1978 |
| url |
http://dx.doi.org/10.1007/978-1-4684-0062-5 |
| work_keys_str_mv |
AT chowyuanshihauthor probabilitytheoryelectronicresourceindependenceinterchangeabilitymartingales AT teicherhenryauthor probabilitytheoryelectronicresourceindependenceinterchangeabilitymartingales AT springerlinkonlineservice probabilitytheoryelectronicresourceindependenceinterchangeabilitymartingales |
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1756271744129171456 |
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KOHA-OAI-TEST:2320082018-07-31T00:15:05ZProbability Theory [electronic resource] : Independence Interchangeability Martingales / Chow, Yuan Shih. author. Teicher, Henry. author. SpringerLink (Online service) textNew York, NY : Springer US,1978.engProbability theory is a branch of mathematics dealing with chance phenomena and has clearly discernible links with the real world. The origins of the sub ject, generally attributed to investigations by the renowned french mathe matician Fermat of problems posed by a gambling contemporary to Pascal, have been pushed back a century earlier to the italian mathematicians Cardano and Tartaglia about 1570 (Ore, 1953). Results as significant as the Bernoulli weak law of large numbers appeared as early as 1713, although its counterpart, the Borel strong law oflarge numbers, did not emerge until 1909. Central limit theorems and conditional probabilities were already being investigated in the eighteenth century, but the first serious attempts to grapple with the logical foundations of probability seem to be Keynes (1921), von Mises (1928; 1931), and Kolmogorov (1933). An axiomatic mold and measure-theoretic framework for probability theory was furnished by Kolmogorov. In this so-called objective or measure theoretic approach, definitions and axioms are so chosen that the empirical realization of an event is the outcome of a not completely determined physical experiment -an experiment which is at least conceptually capable of indefi nite repetition (this notion is due to von Mises). The concrete or intuitive counterpart of the probability of an event is a long run or limiting frequency of the corresponding outcome.1 Classes of Sets, Measures, and Probability Spaces -- 1.1 Sets and set operations -- 1.2 Spaces and indicators -- 1.3 Sigma-algebras, measurable spaces, and product spaces -- 1.4 Measurable transformations -- 1.5 Additive set functions, measures and probability spaces -- 1.6 Induced measures and distribution functions -- 2 Binomial Random Variables -- 2.1 Poisson theorem, interchangeable events, and their limiting probabilities -- 2.2 Bernoulli, Borel theorems -- 2.3 Central limit theorem for binomial random variables, large deviations -- 3 Independence -- 3.1 Independence, random allocation of balls into cells -- 3.2 Borel-Cantelli theorem, characterization of independence, Kolmogorov zero-one law -- 3.3 Convergence in probability, almost certain convergence, and their equivalence for sums of independent random variables -- 3.4 Bernoulli trials -- 4 Integration in a Probability Space -- 4.1 Definition, properties of the integral, monotone convergence theorem -- 4.2 Indefinite integrals, uniform integrability, mean convergence -- 4.3 Jensen, Hölder, Schwarz inequalities -- 5 Sums of Independent Random Variables -- 5.1 Three series theorem -- 5.2 Laws of large numbers -- 5.3 Stopping times, copies of stopping times, Wald’s equation -- 5.4 Chung-Fuchs theorem, elementary renewal theorem, optimal stopping -- 6 Measure Extensions, Lebesgue-Stieltjes Measure, Kolmogorov Consistency Theorem -- 6.1 Measure extensions, Lebesgue-Stieltjes measure -- 6.2 Integration in a measure space -- 6.3 Product measure, Fubini’s theorem, n-dimensional Lebesgue-Stieltjes measure -- 6.4 Infinite-dimensional product measure space, Kolmogorov consistency theorem -- 6.5 Absolute continuity of measures, distribution functions; Radon-Nikodym theorem -- 7 Conditional Expectation, Conditional Independence, Introduction to Martingales -- 7.1 Conditional expectation -- 7.2 Conditional probabilities, conditional probability measures -- 7.3 Conditional independence, interchangeable random variables -- 7.4 Introduction to martingales -- 8 Distribution Functions and Characteristic Functions -- 8.1 Convergence of distribution functions, uniform integrability, Helly-Bray theorem -- 8.2 Weak compactness, Frêchet-Shohat, Glivenko-Cantelli theorems -- 8.3 Characteristic functions, inversion formula, Lévy continuity theorem -- 8.4 The nature of characteristic functions, analytic characteristic functions, Cramér-Lévy theorem -- 8.5 Remarks on k-dimensional distribution functions and characteristic functions -- 9 Central Limit Theorems -- 9.1 Independent components -- 9.2 Interchangeable components -- 9.3 The martingale case -- 9.4 Miscellaneous central limit theorems -- 10 Limit Theorems for Independent Random Variables -- 10.1 Laws of large numbers -- 10.2 Law of the iterated logarithm -- 10.3 Marcinkiewicz-Zygmund inequality, dominated ergodic theorems -- 10.4 Maxima of random walks -- 11 Martingales -- 11.1 Upcrossing inequality and convergence -- 11.2 Martingale extension of Marcinkiewicz-Zygmund inequalities -- 11.3 Convex function inequalities for martingales -- 11.4 Stochastic inequalities -- 12 Infinitely Divisible Laws -- 12.1 Infinitely divisible characteristic functions -- 12.2 Infinitely divisible laws as limits -- 12.3 Stable laws.Probability theory is a branch of mathematics dealing with chance phenomena and has clearly discernible links with the real world. The origins of the sub ject, generally attributed to investigations by the renowned french mathe matician Fermat of problems posed by a gambling contemporary to Pascal, have been pushed back a century earlier to the italian mathematicians Cardano and Tartaglia about 1570 (Ore, 1953). Results as significant as the Bernoulli weak law of large numbers appeared as early as 1713, although its counterpart, the Borel strong law oflarge numbers, did not emerge until 1909. Central limit theorems and conditional probabilities were already being investigated in the eighteenth century, but the first serious attempts to grapple with the logical foundations of probability seem to be Keynes (1921), von Mises (1928; 1931), and Kolmogorov (1933). An axiomatic mold and measure-theoretic framework for probability theory was furnished by Kolmogorov. In this so-called objective or measure theoretic approach, definitions and axioms are so chosen that the empirical realization of an event is the outcome of a not completely determined physical experiment -an experiment which is at least conceptually capable of indefi nite repetition (this notion is due to von Mises). The concrete or intuitive counterpart of the probability of an event is a long run or limiting frequency of the corresponding outcome.Mathematics.Probabilities.Mathematics.Probability Theory and Stochastic Processes.Springer eBookshttp://dx.doi.org/10.1007/978-1-4684-0062-5URN:ISBN:9781468400625 |