3-001-SpringMassDataAnalysis-ModelingScenario

Brian Winkel; Brian Winkel; Brian Winkel

doi:10.25334/W79E-P417

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3-001-SpringMassDataAnalysis-ModelingScenario

Author(s): Brian Winkel

SIMIODE - Systemic Initiative for Modeling Investigations and Opportunities with Differential Equations

Keywords: data damping spring-mass system Newton's Second Law of Motion spring constant Hooke's Law

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Abstract

We offer data on position of a mass at end of spring over time where the spring mass configuration has damping due to taped flat index cards at the bottom of the mass. Modeling of a spring mass configuration and estimation of parameters are the core.

Citation

Researchers should cite this work as follows:

Winkel, B. (2022). 3-001-SpringMassDataAnalysis-ModelingScenario. SIMIODE, QUBES Educational Resources. doi:10.25334/W79E-P417
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Article Context

Resource Type

Modeling Scenario

Differential Equation Type

Technique

Qualitative Analysis

Application Area

Course

Course Level

Lesson Length

Portion of one class period

Technology

Approach

Guided

Skills

Key Scientific Process Skills

Assessment Type

Pedagogical Approaches

Guided inquiry/investigation

Vision and Change Core Competencies - Ability

Principles of How People Learn

Bloom's Cognitive Level

Application & Analysis

Description

We study a spring mass system with a spring attached to a horizontal rod on a ring stand and a Vernier Motion Detector under the mass to capture its displacement from a static equilibrium value at time intervals of 0.02 seconds over a time interval of about 30 seconds.

The motion detector is turned on and the spring is stretched downward and released. We collect the data and ignore (edit out) data from hand placement until a reasonable point in the motion when the oscillation is clear and clean. That cleaned up data is moved to an Excel spreadsheet and a Mathematica notebook. The apparatus with the mass has an additional resistance material in the form of taped index cars on the mass. Thus the 200 g mass with index cards taped to its base to offer more resistance makes for a total mass of 200.20626 g.

Article Files

3-001-S-SpringMassDataAnalysis-StudentVersion.pdf(PDF | 2 MB)
3-001-S-SpringMassDataAnalysis-StudentVersion.tex(TEX | 13 KB)
3-001-T-Mma-SpringMassDampingAnalysis-TeacherVersion.nb (Instructors only)(NB | 2 MB)
3-001-T-Mma-SpringMassDampingAnalysis-TeacherVersion.pdf (Instructors only)(PDF | 2 MB)
3-001-T-Mma-SpringMassDataAnalysis-KnownMass-TeacherVersion.nb (Instructors only)(NB | 10 MB)
3-001-T-Mma-SpringMassDataAnalysis-KnownMass-TeacherVersion.pdf (Instructors only)(PDF | 5 MB)
3-001-T-SpringMassDataAnalysis-TeacherVersion.pdf (Instructors only)(PDF | 2 MB)
3-001-T-SpringMassDataAnalysis-TeacherVersion.tex (Instructors only)(TEX | 13 KB)
3-1-FBD.eps(EPS | 20 KB)
3-1-MainSetUp.eps(EPS | 1 MB)
3-1-MainSetUp.JPG(JPG | 2 MB)
3-1-MassTape.eps(EPS | 912 KB)
3-1-MassTape.JPG(JPG | 2 MB)
3-1-S-SpringMassDampingAnalysis-StudentVersion-FINAL DATA.xlsx(XLSX | 27 KB)
3-1-S-SpringMassDataAnalysis-StudentVersion.xlsx(XLSX | 109 KB)
MassPic.JPG(JPG | 2 MB)
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Authors

Author(s): Brian Winkel

SIMIODE - Systemic Initiative for Modeling Investigations and Opportunities with Differential Equations

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