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Commit ea53bf01 authored by Daniel Hutzschenreuter's avatar Daniel Hutzschenreuter
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Delete Examples_02_complex.xml

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<?xml version="1.0" encoding="UTF-8"?>
<examples id="EXAMPLES_02_complex">
<!--###########################
# Examples of atomic complex types A, B C and D
#-->
<!-- Option A basic complex quantity - Cartesian form -->
<si:complex>
<si:valueReal>-10.3</si:valueReal>
<si:valueImag>0.0</si:valueImag>
<si:unit>\metre</si:unit>
</si:complex>
<!-- Option A basic complex quantity - polar form -->
<si:complex>
<si:valueAmplitude>-10.3</si:valueAmplitude>
<si:valueAmplitude>0.1</si:valueAmplitude>
<si:unit>\metre</si:unit>
<si:unitPhase>\rad</si:unitPhase>
</si:complex>
<!-- Option B basic complex quantity - Cartesian form -->
<si:complex>
<si:value1>-10.3</si:value1>
<si:value2>0.0</si:value2>
<si:unit>\metre</si:unit>
</si:complex>
<!-- Option B basic complex quantity - polar form -->
<si:complex>
<si:value1>-10.3</si:value1>
<si:value2>0.0</si:value2>
<si:unit>\metre</si:unit>
<si:unitPhase>\rad</si:unitPhase>
</si:complex>
<!-- Option C basic complex quantity - Cartesian form -->
<si:list>
<!-- real part of value -->
<si:real>
<si:value>1</si:value>
<si:unit>\hertz</si:unit>
</si:real>
<!-- imaginary part of value -->
<si:imag>
<si:value>0.1</si:value>
</si:imag>
</si:list>
<!-- Option C basic complex quantity - polar form -->
<si:list>
<!-- real part of value -->
<si:real>
<si:value>1</si:value>
<si:unit>\hertz</si:unit>
</si:real>
<!-- imaginary part of value -->
<si:phase>
<si:value>0.1</si:value>
<si:unit>\rad</si:unit>
</si:phase>
</si:list>
<!-- Option D basic complex quantity - Cartesian form -->
<si:list>
<!-- real part of value -->
<si:real>
<si:value>1</si:value>
<si:unit>\hertz</si:unit>
</si:real>
<!-- imaginary part of value -->
<si:complex>
<si:value>0.1</si:value>
</si:complex>
</si:list>
<!-- Option D basic complex quantity - polar form -->
<si:list>
<!-- real part of value -->
<si:real>
<si:value>1</si:value>
<si:unit>\hertz</si:unit>
</si:real>
<!-- imaginary part of value -->
<si:complex>
<si:value>0.1</si:value>
<si:unit>\rad</si:unit>
</si:complex>
</si:list>
<!--###########################
# Examples of the extension of complex types A, B C and D
# with a bivariate or a multivariate definition of coverage
# regions. Two region types are considered:
# These are the hyper-rectangle region and the hyper-
# ellipsoid region.
#
# Only examples for Cartesian coordinates are considered.
#-->
<!-- Examples with elliptic region option 1 (bivariate case)-->
<!-- Option A.1 Cartesian form with hyper-ellipsoid region -->
<si:complex>
<si:valueReal>-10.30</si:valueReal>
<si:valueImag>0.05</si:valueImag>
<si:unit>\metre</si:unit>
<!-- uncertainty -->
<si:uncertaintyReal>0.25</si:uncertaintyReal>
<si:uncertaintyImag>0.20</si:uncertaintyImag>
<si:covariance>-0.01</si:covariance>
<si:coverageFactor>2.45</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:complex>
<!-- Option B.1 Cartesian form with hyper-ellipsoid region -->
<si:complex>
<si:value1>-10.3</si:value1>
<si:value2>0.05</si:value2>
<si:unit>\metre</si:unit>
<!-- uncertainty -->
<si:uncertainty1>0.25</si:uncertainty1>
<si:covariance>-0.01</si:covariance>
<si:uncertainty2>0.20</si:uncertainty2>
<si:coverageFactor>2.45</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:complex>
<!-- Option C.1 Cartesian form with hyper-ellipsoid region -->
<si:list>
<!-- real part of value -->
<si:real>
<si:value>1</si:value>
<si:unit>\hertz</si:unit>
<si:uncertainty>0.25</si:uncertainty>
<si:coverageFactor>2.45</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:real>
<!-- imaginary part of value -->
<si:imag>
<si:value>0.05</si:value>
<si:uncertainty>0.20</si:uncertainty>
<si:covariance>-0.01</si:covariance>
</si:imag>
</si:list>
<!-- Option D.1 Cartesian form with hyper-ellipsoid region -->
<si:list>
<!-- real part of value -->
<si:real>
<si:value>1</si:value>
<si:unit>\hertz</si:unit>
<si:uncertainty>0.25</si:uncertainty>
<si:coverageFactor>2.45</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:real>
<!-- imaginary part of value -->
<si:complex>
<si:value>0.05</si:value>
<si:uncertainty>0.20</si:uncertainty>
<si:covariance>-0.01</si:covariance>
</si:complex>
</si:list>
<!-- Examples with elliptic region option 2 (multivariate case)-->
<!-- Full examples for the hyper-ellipsoid region are provided
in Examples_04_coverageRegions.xml-->
<!-- Option A.2 Cartesian form with hyper-ellipsoid region -->
<si:complex>
<si:valueReal>-10.30</si:valueReal>
<si:valueImag>0.00</si:valueImag>
<si:unit>\metre</si:unit>
<si:ellipsoidRegion>
<!-- upper triangular covariance matrix row by row -->
<si:covarianceMat>0.10, -0.05, 0.15</si:covarianceMat>
<!-- additional information -->
<si:coverageFactor>2.45</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:ellipsoidRegion>
</si:complex>
<!-- Option B.2 Cartesian form with hyper-ellipsoid region -->
<si:complex>
<si:value1>-10.30</si:value1>
<si:value2>0.05</si:value2>
<si:unit>\metre</si:unit>
<si:ellipsoidRegion>
<!-- upper triangular covariance matrix row by row -->
<si:covarianceMat>0.10, -0.05, 0.15</si:covarianceMat>
<!-- additional information -->
<si:coverageFactor>2.45</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:ellipsoidRegion>
</si:complex>
<!-- Option C.2 Cartesian form with hyper-ellipsoid region -->
<si:list>
<!-- real part of value -->
<si:real>
<si:value>1.00</si:value>
<si:unit>\hertz</si:unit>
</si:real>
<!-- imaginary part of value -->
<si:imag>
<si:value>0.10</si:value>
</si:imag>
<si:ellipsoidRegion>
<!-- upper triangular covariance matrix row by row -->
<si:covarianceMat>0.10, -0.05, 0.15</si:covarianceMat>
<!-- additional information -->
<si:coverageFactor>2.45</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:ellipsoidRegion>
</si:list>
<!-- Option D.2 Cartesian form with hyper-ellipsoid region -->
<si:list>
<!-- real part of value -->
<si:real>
<si:value>1.00</si:value>
<si:unit>\hertz</si:unit>
</si:real>
<!-- imaginary part of value -->
<si:complex>
<si:value>0.10</si:value>
</si:complex>
<si:ellipsoidRegion>
<!-- upper triangular covariance matrix row by row -->
<si:covarianceMat>0.10, -0.05, 0.15</si:covarianceMat>
<!-- additional information -->
<si:coverageFactor>2.45</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:ellipsoidRegion>
</si:list>
<!-- Examples with rectangle region option 1 (bivariate case)-->
<!-- Option A.1 Cartesian form with hyper-rectangle region -->
<si:complex>
<si:valueReal>-10.30</si:valueReal>
<si:valueImag>0.05</si:valueImag>
<si:unit>\metre</si:unit>
<!-- uncertainty -->
<si:uncertaintyReal>0.25</si:uncertaintyReal>
<si:uncertaintyImag>0.20</si:uncertaintyImag>
<si:coverageFactor>2.39</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:complex>
<!-- Option B.1 Cartesian form with hyper-rectangle region -->
<si:complex>
<si:value1>-10.3</si:value1>
<si:value2>0.05</si:value2>
<si:unit>\metre</si:unit>
<!-- uncertainty -->
<si:uncertainty1>0.25</si:uncertainty1>
<si:uncertainty2>0.20</si:uncertainty2>
<si:coverageFactor>2.39</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:complex>
<!-- Option C.1 Cartesian form with hyper-rectangle region -->
<si:list>
<!-- real part of value -->
<si:real>
<si:value>1</si:value>
<si:unit>\hertz</si:unit>
<si:uncertainty>0.25</si:uncertainty>
<si:coverageFactor>2.39</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:real>
<!-- imaginary part of value -->
<si:imag>
<si:value>0.05</si:value>
<si:uncertainty>0.20</si:uncertainty>
</si:imag>
</si:list>
<!-- Option D.1 Cartesian form with hyper-rectangle region -->
<si:list>
<!-- real part of value -->
<si:real>
<si:value>1</si:value>
<si:unit>\hertz</si:unit>
<si:uncertainty>0.25</si:uncertainty>
<si:coverageFactor>2.39</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:real>
<!-- imaginary part of value -->
<si:complex>
<si:value>0.05</si:value>
<si:uncertainty>0.20</si:uncertainty>
</si:complex>
</si:list>
<!-- Examples with hyper-rectangular region option 2 (multivariate case)-->
<!-- Full examples for the hyper-rectangle region are provided
in Examples_04_coverageRegions.xml-->
<!-- Option A.2 Cartesian form with hyper-rectangle region -->
<si:complex>
<si:valueReal>-10.30</si:valueReal>
<si:valueImag>0.00</si:valueImag>
<si:unit>\metre</si:unit>
<si:rectangleRegion>
<!-- list of uncertainty values -->
<si:uncertainty>0.15</si:uncertainty>
<si:uncertainty>0.15</si:uncertainty>
<!-- additional information -->
<si:coverageFactor>2.39</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:rectangleRegion>
</si:complex>
<!-- Option B.2 Cartesian form with hyper-rectangle region -->
<si:complex>
<si:value1>-10.30</si:value1>
<si:value2>0.05</si:value2>
<si:unit>\metre</si:unit>
<si:rectangleRegion>
<!-- list of uncertainty values -->
<si:uncertainty>0.15</si:uncertainty>
<si:uncertainty>0.15</si:uncertainty>
<!-- additional information -->
<si:coverageFactor>2.39</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:rectangleRegion>
</si:complex>
<!-- Option C.2 Cartesian form with hyper-rectangle region -->
<si:list>
<!-- real part of value -->
<si:real>
<si:value>1.00</si:value>
<si:unit>\hertz</si:unit>
</si:real>
<!-- imaginary part of value -->
<si:imag>
<si:value>0.10</si:value>
</si:imag>
<si:rectangleRegion>
<!-- list of uncertainty values -->
<si:uncertainty>0.15</si:uncertainty>
<si:uncertainty>0.15</si:uncertainty>
<!-- additional information -->
<si:coverageFactor>2.39</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:rectangleRegion>
</si:list>
<!-- Option D.2 Cartesian form with hyper-rectangle region -->
<si:list>
<!-- real part of value -->
<si:real>
<si:value>1.00</si:value>
<si:unit>\hertz</si:unit>
</si:real>
<!-- imaginary part of value -->
<si:complex>
<si:value>0.10</si:value>
</si:complex>
<si:rectangleRegion>
<!-- list of uncertainty values -->
<si:uncertainty>0.15</si:uncertainty>
<si:uncertainty>0.15</si:uncertainty>
<!-- additional information -->
<si:coverageFactor>2.39</si:coverageFactor>
<si:coverageProbability>0.95</si:coverageProbability>
<si:distribution>normal-bivariate</si:distribution>
</si:rectangleRegion>
</si:list>
</examples>
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