MODELING AND ARTIFICIAL INTELLIGENCE APPROACHES TO ENZYME SYSTEMS.

David Garfinkel; Casimir A. Kulikowski; Von Wun Soo; Julio Maclay; Murray J. Achs

MODELING AND ARTIFICIAL INTELLIGENCE APPROACHES TO ENZYME SYSTEMS.

David Garfinkel, Casimir A. Kulikowski, Von Wun Soo, Julio Maclay, Murray J. Achs

Research output: Contribution to journal › Conference article › peer-review

Abstract

These include performance of serious modeling on laboratory microcomputers, e. g. IBM PCs such as fitting models to kinetic data with linear or nonlinear regression and graphical assistance; use of PC to rapidly build multienzyme models of metabolic systems, which have previously taken much longer on large computers; use of PCs to build data bases used for modeling; extraction of information from models by sensitivity analysis; and use of the preceding to design experiments. Artificial intelligence techniques permit critiquing and evaluating the data, experiments, and hypotheses being modeled. Much of the modeling process can be stated within the framework of expert systems (now becoming available on microcomputers) using sets of rules for fitting and evaluating models and designing further experiments. Such expert systems can supervise calculations in addition to performing reasoning.

Original language	American English
Pages (from-to)	92
Number of pages	1
Journal	Annals of Biomedical Engineering
Volume	14
Issue number	1
State	Published - 1986
Externally published	Yes
Event	Biomed Eng Soc (BES) 1986 Symp - St Louis, MO, USA Duration: Apr 13 1986 → Apr 18 1986

ASJC Scopus subject areas

Biomedical Engineering

Cite this

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title = "MODELING AND ARTIFICIAL INTELLIGENCE APPROACHES TO ENZYME SYSTEMS.",

abstract = "These include performance of serious modeling on laboratory microcomputers, e. g. IBM PCs such as fitting models to kinetic data with linear or nonlinear regression and graphical assistance; use of PC to rapidly build multienzyme models of metabolic systems, which have previously taken much longer on large computers; use of PCs to build data bases used for modeling; extraction of information from models by sensitivity analysis; and use of the preceding to design experiments. Artificial intelligence techniques permit critiquing and evaluating the data, experiments, and hypotheses being modeled. Much of the modeling process can be stated within the framework of expert systems (now becoming available on microcomputers) using sets of rules for fitting and evaluating models and designing further experiments. Such expert systems can supervise calculations in addition to performing reasoning.",

author = "David Garfinkel and Kulikowski, {Casimir A.} and Soo, {Von Wun} and Julio Maclay and Achs, {Murray J.}",

year = "1986",

language = "American English",

volume = "14",

pages = "92",

journal = "Annals of Biomedical Engineering",

issn = "0090-6964",

publisher = "Springer Netherlands",

number = "1",

note = "Biomed Eng Soc (BES) 1986 Symp ; Conference date: 13-04-1986 Through 18-04-1986",

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TY - JOUR

T1 - MODELING AND ARTIFICIAL INTELLIGENCE APPROACHES TO ENZYME SYSTEMS.

AU - Garfinkel, David

AU - Kulikowski, Casimir A.

AU - Soo, Von Wun

AU - Maclay, Julio

AU - Achs, Murray J.

PY - 1986

Y1 - 1986

N2 - These include performance of serious modeling on laboratory microcomputers, e. g. IBM PCs such as fitting models to kinetic data with linear or nonlinear regression and graphical assistance; use of PC to rapidly build multienzyme models of metabolic systems, which have previously taken much longer on large computers; use of PCs to build data bases used for modeling; extraction of information from models by sensitivity analysis; and use of the preceding to design experiments. Artificial intelligence techniques permit critiquing and evaluating the data, experiments, and hypotheses being modeled. Much of the modeling process can be stated within the framework of expert systems (now becoming available on microcomputers) using sets of rules for fitting and evaluating models and designing further experiments. Such expert systems can supervise calculations in addition to performing reasoning.

AB - These include performance of serious modeling on laboratory microcomputers, e. g. IBM PCs such as fitting models to kinetic data with linear or nonlinear regression and graphical assistance; use of PC to rapidly build multienzyme models of metabolic systems, which have previously taken much longer on large computers; use of PCs to build data bases used for modeling; extraction of information from models by sensitivity analysis; and use of the preceding to design experiments. Artificial intelligence techniques permit critiquing and evaluating the data, experiments, and hypotheses being modeled. Much of the modeling process can be stated within the framework of expert systems (now becoming available on microcomputers) using sets of rules for fitting and evaluating models and designing further experiments. Such expert systems can supervise calculations in addition to performing reasoning.

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M3 - Conference article

SN - 0090-6964

VL - 14

SP - 92

JO - Annals of Biomedical Engineering

JF - Annals of Biomedical Engineering

IS - 1

T2 - Biomed Eng Soc (BES) 1986 Symp

Y2 - 13 April 1986 through 18 April 1986

ER -

MODELING AND ARTIFICIAL INTELLIGENCE APPROACHES TO ENZYME SYSTEMS.

Abstract

ASJC Scopus subject areas

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