What can quantum theory bring to information retrieval

Ingo Frommholz; Benjamin Piwowarski; Mounia Lalmas; Keith Van Rijsbergen

doi:10.1145/1871437.1871450

What can quantum theory bring to information retrieval

Ingo Frommholz
, Benjamin Piwowarski
, Mounia Lalmas
, Keith Van Rijsbergen

Institute for Research in Applicable Computing (IRAC)

University of Glasgow

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

59 Citations (Scopus)

Abstract

The probabilistic formalism of quantum physics is said to provide a sound basis for building a principled information retrieval framework. Such a framework can be based on the notion of information need vector spaces where events, such as document relevance or observed user interactions, correspond to subspaces. As in quantum theory, a probability distribution over these subspaces is defined through weighted sets of state vectors (density operators), and used to represent the current view of the retrieval system on the user information need. Tensor spaces can be used to capture different aspects of information needs. Our evaluation shows that the framework can lead to acceptable performance in an ad-hoc retrieval task. Going beyond this, we discuss the potential of the framework for three active challenges in information retrieval, namely, interaction, novelty and diversity.

Original language	English
Title of host publication	nan
Publisher	Association for Computing Machinery
ISBN (Electronic)	9781450300995
ISBN (Print)	9781450300995
DOIs	https://doi.org/10.1145/1871437.1871450
Publication status	Published - 1 Jan 2010
Event	19th ACM international conference on Information and knowledge management - Duration: 1 Jan 2010 → …

Conference

Conference	19th ACM international conference on Information and knowledge management
Period	1/01/10 → …
Other	19th ACM international conference on Information and knowledge management

Keywords

Information retrieval

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10.1145/1871437.1871450

http://portal.acm.org/citation.cfm%3Fdoid%3D1871437.1871450

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title = "What can quantum theory bring to information retrieval",

abstract = "The probabilistic formalism of quantum physics is said to provide a sound basis for building a principled information retrieval framework. Such a framework can be based on the notion of information need vector spaces where events, such as document relevance or observed user interactions, correspond to subspaces. As in quantum theory, a probability distribution over these subspaces is defined through weighted sets of state vectors (density operators), and used to represent the current view of the retrieval system on the user information need. Tensor spaces can be used to capture different aspects of information needs. Our evaluation shows that the framework can lead to acceptable performance in an ad-hoc retrieval task. Going beyond this, we discuss the potential of the framework for three active challenges in information retrieval, namely, interaction, novelty and diversity.",

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author = "Ingo Frommholz and Benjamin Piwowarski and Mounia Lalmas and \{Van Rijsbergen\}, Keith",

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AU - Frommholz, Ingo

AU - Piwowarski, Benjamin

AU - Lalmas, Mounia

AU - Van Rijsbergen, Keith

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N2 - The probabilistic formalism of quantum physics is said to provide a sound basis for building a principled information retrieval framework. Such a framework can be based on the notion of information need vector spaces where events, such as document relevance or observed user interactions, correspond to subspaces. As in quantum theory, a probability distribution over these subspaces is defined through weighted sets of state vectors (density operators), and used to represent the current view of the retrieval system on the user information need. Tensor spaces can be used to capture different aspects of information needs. Our evaluation shows that the framework can lead to acceptable performance in an ad-hoc retrieval task. Going beyond this, we discuss the potential of the framework for three active challenges in information retrieval, namely, interaction, novelty and diversity.

AB - The probabilistic formalism of quantum physics is said to provide a sound basis for building a principled information retrieval framework. Such a framework can be based on the notion of information need vector spaces where events, such as document relevance or observed user interactions, correspond to subspaces. As in quantum theory, a probability distribution over these subspaces is defined through weighted sets of state vectors (density operators), and used to represent the current view of the retrieval system on the user information need. Tensor spaces can be used to capture different aspects of information needs. Our evaluation shows that the framework can lead to acceptable performance in an ad-hoc retrieval task. Going beyond this, we discuss the potential of the framework for three active challenges in information retrieval, namely, interaction, novelty and diversity.

KW - Information retrieval

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U2 - 10.1145/1871437.1871450

DO - 10.1145/1871437.1871450

M3 - Conference contribution

SN - 9781450300995

BT - nan

PB - Association for Computing Machinery

T2 - 19th ACM international conference on Information and knowledge management

Y2 - 1 January 2010

ER -

What can quantum theory bring to information retrieval

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