MER331 Lab 2 - PowerPoint PPT Presentation

1 / 20
About This Presentation
Title:

MER331 Lab 2

Description:

Consider procedural and test control errors that affect the measurement. Uncertainty Analysis ... General Practice in engineering is 95% confidence of 20 to 1 odds. ... – PowerPoint PPT presentation

Number of Views:81
Avg rating:3.0/5.0
Slides: 21
Provided by: thomasjam4
Category:
Tags: lab | math | mer331 | practice | test

less

Transcript and Presenter's Notes

Title: MER331 Lab 2


1
MER331 Lab 2
  • Uncertainty Analysis

2
Error Sources
  • The measurement process consists of three
    dis-tinct steps calibration, data acquisition,
    and data reduction
  • calibration error
  • data acquisition error
  • data reduction error

3
Uncertainty Analysis
  • Error - difference between true value and
    measured value.
  • Two general categories of error (exclude gross
    blunders)
  • Fixed error remove by calibration
  • Random error quantify by uncertainty analysis
  • The term uncertainty is used to refer to a
    possible value that an error may have

4
Stages of Uncertainty Analysis
  • Design Stage Uncertainty Analysis
  • Uncertainty analysis can be used to assist in the
    selection of equipment and procedures based on
    their relative performance and cost.
  • Advanced-Stage and Single Measurement Uncertainty
    Analysis
  • Consider procedural and test control errors that
    affect the measurement

5
Uncertainty Analysis
  • m Kt(rball-rfluid)
  • How do I find uncertainty in m if I have
    uncertainty in K, t, rball,and rfluid.?
  • Three steps
  • Estimate uncertainty interval for each measured
    quantity
  • State the confidence limit on each measurement
  • Analyze the propagation of uncertainty into
    results calculated from experimental data.

6
Estimating Uncertainty Interval
  • If you have a statistically significant sample
    use 2s for a 95 confidence interval. (1st
    order analysis)
  • General Practice in engineering is 95
    confidence of 20 to 1 odds.
  • Otherwise use ½ smallest scale division as an
    estimate. (0th order analysis)
  • Technique due to Kline, S.J., and McClintock,
    F.A., Describing Uncertainties in Single Sample
    Experiments, Mechanical Engineering, 75, 1953.

7
Propagation of Uncertainty -The Basic Mathematics
  • The value of dxi represents 2s for a single
    sample analysis. The result, R of an experiment
    is assumed to be calculated from a set of
    measurements
  • R R(X1, X2, X3,, XN)
  • The effect of the uncertainty in a single
    measurement (i.e. one of the Xs) on the
    calculated result, R, if only that one X were in
    error is

8
The Basic Mathematics
  • When several independent variables (Xs) are used
    in calculating the Result, R, the individual
    terms are combined by a root-sum-square method
    (Method due to Kline and McClintock (1953))
  • In most situations the overall uncertainty in a
    given result is dominated by only a few of its
    terms. Ignore terms that are smaller than the
    largest term by a factor of 3 or more.

9
Example 1
  • For a displacement transducer having a
    calibration curve y KE2, estimate the
    uncertainty in displacement y for
  • E 5.00 V, dE 0.01 V
  • K 10.10 mm/V2, dk 0.10 mm/V2
  • (95 confidence).

10
Example 1

11
Uncertainty as a Percentage
  • In most situations the overall uncertainty in a
    given result is dominated by only a few of its
    terms. Ignore terms that are smaller than the
    largest term by a factor of 3 or more.
  • It is difficult (impossible) to compare errors
    with different units associated with them (e.g.
    how big is a 2 gram error compared to a 2 second
    error?)
  • To solve this we nondimensionalize the errors

12
So, as a percentage
13
Uncertainty Analysis (Product form Equations)
  • .
  • If
  • Then
  • The exponent on Xi becomes its sensitivity
    coefficient

14
Example 2
  • For a displacement transducer having a
    calibration curve y KE2, estimate the PERCENT
    uncertainty in displacement y for
  • E 5.00 V, dE 0.01 V
  • K 10.10 mm/V2, dk 0.10 mm/V2
  • (95 confidence).

15
Example 2
  • If
  • Then

16
Zero-Order Uncertainty
  • At zero-order uncertainty, all variables and
    parameters that affect the outcome of the
    measurement, including time, are assumed to be
    fixed except for the physical act of observation
    itself.
  • Any data scatter is the results of instrument
    resolution alone uo.

17
Higher-Order Uncertainty
  • Higher order uncertainty estimates consider the
    controllability of the test operating conditions.
  • For a first order estimate we might make a
    series of measurements over time and calculate
    the variation in that measurement. The first
    order uncertainty of that measurand is then
  • u1 2s at (95)
  • Note Assuming we make enough measurements

18
Nth-Order Uncertainty
  • As the final estimate, instrument calibration
    characteristics are entered into the scheme
    through the instrument uncertainty, uc. A
    practical estimate of the Nth order uncertainty
    uN is
  • Uncertainty analyses at the Nth order allow for
    the direct comparison between results of similar
    tests obtained using different instruments or at
    different test facilities.

19
Uncertainty Analysis
  • rfluid m/V
  • How do I find uncertainty in r?
  • Three steps
  • Estimate uncertainty interval for each measured
    quantity, (m and V)
  • State the confidence limit on each measurement
  • Analyze the propagation of uncertainty into
    results calculated from experimental data.

20
Report Results at uN level
Nth order Uncertainty
First-order Uncertainty u1 gt u0
Zero- order Uncertainty u0 1/2 resolution
Write a Comment
User Comments (0)
About PowerShow.com