An objective, model-independent method for detection of non-uniform steps in noisy signals

Bennett Kalafut; Koen Visscher

doi:10.1016/j.cpc.2008.06.008

An objective, model-independent method for detection of non-uniform steps in noisy signals

Bennett Kalafut, Koen Visscher

Research output: Contribution to journal › Article › peer-review

57 Scopus citations

Abstract

Biophysical techniques, such as single molecule FRET, fluorescence microscopy, single ion-channel patch clamping, and optical tweezers often yield data that are noisy time series containing discrete steps. Here we present a method enabling objective identification of nonuniform steps present in such noisy data. Our method does not require the assumption of any underlying kinetic or state models and is thus particularly useful for analysis of novel and poorly understood systems. In contrast to other model-independent methods, no parameters or other information is taken from the user. We find that, at high noise levels, our method exceeds the performance of other model-independent methods in accurately locating steps in simulated noisy data.

Original language	English (US)
Pages (from-to)	716-723
Number of pages	8
Journal	Computer Physics Communications
Volume	179
Issue number	10
DOIs	https://doi.org/10.1016/j.cpc.2008.06.008
State	Published - Nov 15 2008

Keywords

Change point analysis
Single molecule biophysics
Step detection

ASJC Scopus subject areas

Hardware and Architecture
Physics and Astronomy(all)

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10.1016/j.cpc.2008.06.008

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abstract = "Biophysical techniques, such as single molecule FRET, fluorescence microscopy, single ion-channel patch clamping, and optical tweezers often yield data that are noisy time series containing discrete steps. Here we present a method enabling objective identification of nonuniform steps present in such noisy data. Our method does not require the assumption of any underlying kinetic or state models and is thus particularly useful for analysis of novel and poorly understood systems. In contrast to other model-independent methods, no parameters or other information is taken from the user. We find that, at high noise levels, our method exceeds the performance of other model-independent methods in accurately locating steps in simulated noisy data.",

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N2 - Biophysical techniques, such as single molecule FRET, fluorescence microscopy, single ion-channel patch clamping, and optical tweezers often yield data that are noisy time series containing discrete steps. Here we present a method enabling objective identification of nonuniform steps present in such noisy data. Our method does not require the assumption of any underlying kinetic or state models and is thus particularly useful for analysis of novel and poorly understood systems. In contrast to other model-independent methods, no parameters or other information is taken from the user. We find that, at high noise levels, our method exceeds the performance of other model-independent methods in accurately locating steps in simulated noisy data.

AB - Biophysical techniques, such as single molecule FRET, fluorescence microscopy, single ion-channel patch clamping, and optical tweezers often yield data that are noisy time series containing discrete steps. Here we present a method enabling objective identification of nonuniform steps present in such noisy data. Our method does not require the assumption of any underlying kinetic or state models and is thus particularly useful for analysis of novel and poorly understood systems. In contrast to other model-independent methods, no parameters or other information is taken from the user. We find that, at high noise levels, our method exceeds the performance of other model-independent methods in accurately locating steps in simulated noisy data.

KW - Change point analysis

KW - Single molecule biophysics

KW - Step detection

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An objective, model-independent method for detection of non-uniform steps in noisy signals

Abstract

Keywords

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