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M.González
M.González
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A (non-trivial) ultrafilter $\mathcal{U}$ on $\mathbb{N}$ is a p-point if and only if every bounded sequence $(a_n)$ of real numbers contains a convergent subsequence $(a_{n_k})$ such that $\{n_k\}\in \mathcal{U}$.

See [Israel Journalthe Introduction of Mathematics[Israel J. Math. 122 (2001), 189-206 DOI: 10.1007/BF02809899] for an application of a subclass of these ultrafilters to obtain an ultrapower version of the subsequence splitting property for the Banach space $L_1(\mu)$, some discussions related with the question, and proper references.

A (non-trivial) ultrafilter $\mathcal{U}$ on $\mathbb{N}$ is a p-point if and only if every bounded sequence $(a_n)$ of real numbers contains a convergent subsequence $(a_{n_k})$ such that $\{n_k\}\in \mathcal{U}$.

See [Israel Journal of Mathematics 122 (2001), 189-206 DOI: 10.1007/BF02809899] for an application of these ultrafilters to obtain an ultrapower version of the subsequence splitting property for the Banach space $L_1(\mu)$, some discussions related with the question, and proper references.

A (non-trivial) ultrafilter $\mathcal{U}$ on $\mathbb{N}$ is a p-point if and only if every bounded sequence $(a_n)$ of real numbers contains a convergent subsequence $(a_{n_k})$ such that $\{n_k\}\in \mathcal{U}$.

See the Introduction of [Israel J. Math. 122 (2001), 189-206 DOI: 10.1007/BF02809899] for an application of a subclass of these ultrafilters to obtain an ultrapower version of the subsequence splitting property for the Banach space $L_1(\mu)$, some discussions related with the question, and proper references.

deleted 86 characters in body
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M.González
M.González
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A (non-trivial) ultrafilter $\mathcal{U}$ on $\mathbb{N}$ is a p-point if and only if every bounded sequence $(a_n)$ of real numbers contains a convergent subsequence $(a_{n_k})$ such that $\{n_k\}\in \mathcal{U}$.

See [M. Gonzáles, A. Martinéz-Abejón: Ultrapowers of $L_1(\mu)$ and the subsequence splitting principle, Israel[Israel Journal of Mathematics 122 (2001), 189-206, DOI: 10.1007/BF02809899] for an application of these ultrafilters to obtain an ultrapower version of the subsequence splitting property for the Banach space $L_1(\mu)$, some discussions related with the question, and proper references.

A (non-trivial) ultrafilter $\mathcal{U}$ on $\mathbb{N}$ is a p-point if and only if every bounded sequence $(a_n)$ of real numbers contains a convergent subsequence $(a_{n_k})$ such that $\{n_k\}\in \mathcal{U}$.

See [M. Gonzáles, A. Martinéz-Abejón: Ultrapowers of $L_1(\mu)$ and the subsequence splitting principle, Israel Journal of Mathematics 122 (2001), 189-206, DOI: 10.1007/BF02809899] for an application of these ultrafilters to obtain an ultrapower version of the subsequence splitting property for $L_1(\mu)$, some discussions related with the question, and proper references.

A (non-trivial) ultrafilter $\mathcal{U}$ on $\mathbb{N}$ is a p-point if and only if every bounded sequence $(a_n)$ of real numbers contains a convergent subsequence $(a_{n_k})$ such that $\{n_k\}\in \mathcal{U}$.

See [Israel Journal of Mathematics 122 (2001), 189-206 DOI: 10.1007/BF02809899] for an application of these ultrafilters to obtain an ultrapower version of the subsequence splitting property for the Banach space $L_1(\mu)$, some discussions related with the question, and proper references.

added complete citation and doi
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edit approved Jul 8, 2016 at 9:12
Martin Sleziak
edit approved Jul 8, 2016 at 9:12
Martin Sleziak
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A (non-trivial) ultrafilter $\mathcal{U}$ on $\mathbb{N}$ is a p-point if and only if every bounded sequence $(a_n)$ of real numbers contains a convergent subsequence $(a_{n_k})$ such that $\{n_k\}\in \mathcal{U}$.

See [ISRAEL JOURNAL OF MATHEMATICS[M. Gonzáles, A. Martinéz-Abejón: Ultrapowers of $L_1(\mu)$ and the subsequence splitting principle, Israel Journal of Mathematics 122 (2001), 189-206]206, DOI: 10.1007/BF02809899] for an application of these ultrafilters to obtain an ultrapower version of the subsequence splitting property for $L_1(\mu)$, some discussions related with the question, and proper references.

A (non-trivial) ultrafilter $\mathcal{U}$ on $\mathbb{N}$ is a p-point if and only if every bounded sequence $(a_n)$ of real numbers contains a convergent subsequence $(a_{n_k})$ such that $\{n_k\}\in \mathcal{U}$.

See [ISRAEL JOURNAL OF MATHEMATICS 122 (2001), 189-206] for an application of these ultrafilters to obtain an ultrapower version of the subsequence splitting property for $L_1(\mu)$, some discussions related with the question, and proper references.

A (non-trivial) ultrafilter $\mathcal{U}$ on $\mathbb{N}$ is a p-point if and only if every bounded sequence $(a_n)$ of real numbers contains a convergent subsequence $(a_{n_k})$ such that $\{n_k\}\in \mathcal{U}$.

See [M. Gonzáles, A. Martinéz-Abejón: Ultrapowers of $L_1(\mu)$ and the subsequence splitting principle, Israel Journal of Mathematics 122 (2001), 189-206, DOI: 10.1007/BF02809899] for an application of these ultrafilters to obtain an ultrapower version of the subsequence splitting property for $L_1(\mu)$, some discussions related with the question, and proper references.

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M.González
M.González
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