Difference between revisions of "Vectors"
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− | <h2>Vectors in Problems: PG Code Snippet</h2> |
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+ | {{historical}} |
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+ | <p style="font-size: 120%;font-weight:bold">This problem has been replaced with [https://openwebwork.github.io/pg-docs/sample-problems/VectorCalc/Vectors.html a newer version of this problem]</p><h2>Vectors in Problems: PG Code Snippet</h2> |
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<p style="background-color:#eeeeee;border:black solid 1px;padding:3px;"> |
<p style="background-color:#eeeeee;border:black solid 1px;padding:3px;"> |
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<th> Explanation </th> |
<th> Explanation </th> |
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</tr> |
</tr> |
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+ | |||
+ | <tr valign="top"> |
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+ | <td style="background-color:#ddffdd;border:black 1px dashed;"> |
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+ | <pre> |
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+ | loadMacros( |
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+ | "PGstandard.pl", |
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+ | "PGcourse.pl", |
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+ | "MathObjects.pl", |
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+ | "parserVectorUtils.pl", |
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+ | ); |
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+ | </pre> |
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+ | </td> |
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+ | <td style="background-color:#ccffcc;padding:7px;"> |
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+ | <p> |
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+ | <b>Initialization:</b> |
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+ | Be sure to load <code>parserVectorUtils.pl</code> and <code>MathObjects.pl</code> (since <code>parserVectorUtils.pl</code> does not automatically load <code>MathObjects.pl</code>). |
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+ | </p> |
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+ | </td> |
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+ | </tr> |
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+ | |||
<tr valign="top"> |
<tr valign="top"> |
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<td style="background-color:#ffffdd;border:black 1px dashed;"> |
<td style="background-color:#ffffdd;border:black 1px dashed;"> |
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<pre> |
<pre> |
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− | + | Context('Vector'); |
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− | + | ## display vectors in ijk format |
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− | + | ## Context()->flags->set( ijk=>1 ); |
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+ | ## set the appearance of the ijk vectors |
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+ | ## this sets them to be overset with |
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+ | ## vector arrows, instead of boldface |
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+ | # Context()->constants->set( |
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+ | # i => {TeX => "\mathit{\vec i}"}, |
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+ | # j => {TeX => "\mathit{\vec j}"}, |
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+ | # k => {TeX => "\mathit{\vec k}"}, |
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+ | # ); |
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− | ## set the appearance of the ijk vectors |
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+ | $v1 = Vector("<1,3>"); |
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− | ## this sets them to be overset with |
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+ | $v2 = Compute("<-3,1>"); |
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− | ## vector arrows, instead of boldface |
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+ | $v3 = 3*i + 2*j - 4*k; |
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− | # Context()->constants->set( |
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+ | $v4 = Vector(1,1,0); |
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− | # i => {TeX => "\mathit{\vec i}"}, |
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− | # j => {TeX => "\mathit{\vec j}"}, |
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− | # k => {TeX => "\mathit{\vec k}"}, |
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− | # ); |
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− | $v1 = Vector("<1,3>"); |
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+ | # create an array of the components of $v3 |
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− | $v2 = Compute("<-3,1>"); |
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+ | @v3comp = $v3->value; |
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− | $v3 = 3*i + 2*j - 4*k; |
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− | + | $a = 3*i + j; |
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− | + | $b = $a + $v1; |
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+ | $c = norm($v3); # vector length |
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+ | $v5 = unit($v3); # unit vector in same direction |
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+ | $d = $v1 . $v2; # dot product |
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+ | $v6 = $v3 x $v4; # cross product |
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+ | $v3->isParallel($v4); # =1 if parallel, =0 if skew |
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</pre> |
</pre> |
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</td> |
</td> |
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<td style="background-color:#ffffcc;padding:7px;"> |
<td style="background-color:#ffffcc;padding:7px;"> |
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<p> |
<p> |
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+ | <b>Setup:</b> |
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We indicate that we are working in a vector context by setting the <code>Context</code> to be <code>Vector</code>. If we want to have vectors displayed, by default, as a sum of <i>i,j,k</i> components, we can set the <code>ijk</code> flag in the Context. This is commented out here; uncommenting it would result in the vector <b>v1</b> here being shown as <b>v1</b> = <b>i</b> + 3<b>j</b> instead of <b>v1</b> = <1,3>, etc. Similarly, if we wanted to change the default display of the <b>i</b>, <b>j</b> and <b>k</b> vectors, say to have them display with overset arrows, we can redefine the TeX formatting of those constants, as shown in the second comment. |
We indicate that we are working in a vector context by setting the <code>Context</code> to be <code>Vector</code>. If we want to have vectors displayed, by default, as a sum of <i>i,j,k</i> components, we can set the <code>ijk</code> flag in the Context. This is commented out here; uncommenting it would result in the vector <b>v1</b> here being shown as <b>v1</b> = <b>i</b> + 3<b>j</b> instead of <b>v1</b> = <1,3>, etc. Similarly, if we wanted to change the default display of the <b>i</b>, <b>j</b> and <b>k</b> vectors, say to have them display with overset arrows, we can redefine the TeX formatting of those constants, as shown in the second comment. |
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</p> |
</p> |
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<p> |
<p> |
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To explicitly require that the vectors be two-dimensional rather than three-dimensional, we would use <code>Context('Vector2D')</code> instead of <code>Context('Vector')</code>. |
To explicitly require that the vectors be two-dimensional rather than three-dimensional, we would use <code>Context('Vector2D')</code> instead of <code>Context('Vector')</code>. |
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+ | </p> |
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+ | <p> |
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+ | The components of MathObjects vectors are available as an array from <code>$v->value</code>; thus, we could save the three components of the vector <code>$v3</code> in the array <code>@v3comp</code>. Then, we can access the first component using $v3comp[0], the second component using $v3comp[1], etc. Better still, to get the first component of the vector <code>$v3</code> we could use <code>$v3->extract(1)</code> instead of <code>($v3->value)[0]</code>. <em>(This appears only to be the case for vectors that are initially defined using angle-bracket notation, not for vectors that are defined using i, j, and k—and this behavior may be different for vectors of numbers and vectors of formulas.)</em> |
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</p> |
</p> |
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</td> |
</td> |
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<td style="background-color:#ffdddd;border:black 1px dashed;"> |
<td style="background-color:#ffdddd;border:black 1px dashed;"> |
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<pre> |
<pre> |
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− | + | BEGIN_TEXT |
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− | + | Enter the vector pointing from |
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− | + | \($a\) to \($b\): |
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− | + | \{ ans_rule(25) \} |
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− | + | $PAR |
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− | + | Enter a vector perpendicular to this: |
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− | + | \{ ans_rule(25) \} |
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− | + | $PAR |
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− | + | Enter a vector parallel to \($v3\): |
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− | + | \{ ans_rule(25) \} |
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</pre> |
</pre> |
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<td style="background-color:#ffcccc;padding:7px;"> |
<td style="background-color:#ffcccc;padding:7px;"> |
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<p> |
<p> |
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+ | <b>Main text:</b> |
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We can then use the vectors that we created in the text section of the problem. |
We can then use the vectors that we created in the text section of the problem. |
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</p> |
</p> |
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<td style="background-color:#eeddff;border:black 1px dashed;"> |
<td style="background-color:#eeddff;border:black 1px dashed;"> |
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<pre> |
<pre> |
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− | + | ANS( $v1->cmp() ); |
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− | + | ANS( $v2->cmp( checker=>sub { |
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− | + | my ($correct, $student, $ansHash) = @_; |
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− | + | return $correct->isParallel($student); |
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− | + | }, showCoordinateHints => 0 ) ); |
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− | + | ## or: |
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− | + | # ANS( $v1->cmp( checker=>sub { |
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− | + | # my ($correct, $student, $ansHash) = @_; |
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− | + | # return $correct.$student == 0; } ) ); |
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− | + | # make a custom answer checker as a subroutine |
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− | + | sub parallel_vector_cmp { |
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− | + | my ($correct, $student, $ansHash) = @_; |
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− | + | return $correct->isParallel($student); |
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− | + | } |
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+ | ANS( $v3->cmp( checker=>~~¶llel_vector_cmp, |
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+ | showCoordinateHints => 0 ) ); |
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</pre> |
</pre> |
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<td style="background-color:#eeccff;padding:7px;"> |
<td style="background-color:#eeccff;padding:7px;"> |
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<p> |
<p> |
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− | We can then use the vectors to check the answers that are given. Note that we have used [[CustomAnswerCheckers|custom answer checkers]] for the latter answer evaluators here, taking advantage of the built in dot product and <code>isParallel</code> method of vector objects. |
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+ | <b>Answer evaluation:</b> |
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+ | We can then use the vectors to check the answers that are given. Note that we have used [[CustomAnswerCheckers|custom answer checkers]] for the latter answer evaluators here, taking advantage of the built in dot product and <code>isParallel</code> method of vector objects. When checking if a student's vector is parallel to the correct vector, hints about which coordinates are incorrect can be misleading, so we set <code>showCoordinateHints => 0</code>. |
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+ | </p> |
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+ | <p> |
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+ | Other properties of MathObjects vectors are given in the [[MathObjects_reference_table|MathObjects reference table]]. |
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</p> |
</p> |
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</td> |
</td> |
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[[IndexOfProblemTechniques|Problem Techniques Index]] |
[[IndexOfProblemTechniques|Problem Techniques Index]] |
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</p> |
</p> |
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+ | |||
+ | [[Category:Problem Techniques]] |
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+ | |||
+ | |||
+ | |||
+ | <ul> |
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+ | <li>POD documentation: [http://webwork.maa.org/pod/pg/macros/parserVectorUtils.html parserVectorUtils.pl]</li> |
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+ | <li>PG macro: [http://webwork.maa.org/viewvc/system/trunk/pg/macros/parserVectorUtils.pl?view=log parserVectorUtils.pl]</li> |
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+ | </ul> |
Latest revision as of 13:01, 28 June 2023
This problem has been replaced with a newer version of this problem
Vectors in Problems: PG Code Snippet
This code snippet shows the essential PG code to use vectors in WeBWorK problems. Note that these are insertions, not a complete PG file. This code will have to be incorporated into the problem file on which you are working.
PG problem file | Explanation |
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loadMacros( "PGstandard.pl", "PGcourse.pl", "MathObjects.pl", "parserVectorUtils.pl", ); |
Initialization:
Be sure to load |
Context('Vector'); ## display vectors in ijk format ## Context()->flags->set( ijk=>1 ); ## set the appearance of the ijk vectors ## this sets them to be overset with ## vector arrows, instead of boldface # Context()->constants->set( # i => {TeX => "\mathit{\vec i}"}, # j => {TeX => "\mathit{\vec j}"}, # k => {TeX => "\mathit{\vec k}"}, # ); $v1 = Vector("<1,3>"); $v2 = Compute("<-3,1>"); $v3 = 3*i + 2*j - 4*k; $v4 = Vector(1,1,0); # create an array of the components of $v3 @v3comp = $v3->value; $a = 3*i + j; $b = $a + $v1; $c = norm($v3); # vector length $v5 = unit($v3); # unit vector in same direction $d = $v1 . $v2; # dot product $v6 = $v3 x $v4; # cross product $v3->isParallel($v4); # =1 if parallel, =0 if skew |
Setup:
We indicate that we are working in a vector context by setting the
Then, we can define vectors as we might expect: either with the
Note that if we define the vector using the constants i, j and k, as in the definition of
To explicitly require that the vectors be two-dimensional rather than three-dimensional, we would use
The components of MathObjects vectors are available as an array from |
BEGIN_TEXT Enter the vector pointing from \($a\) to \($b\): \{ ans_rule(25) \} $PAR Enter a vector perpendicular to this: \{ ans_rule(25) \} $PAR Enter a vector parallel to \($v3\): \{ ans_rule(25) \} |
Main text: We can then use the vectors that we created in the text section of the problem. |
ANS( $v1->cmp() ); ANS( $v2->cmp( checker=>sub { my ($correct, $student, $ansHash) = @_; return $correct->isParallel($student); }, showCoordinateHints => 0 ) ); ## or: # ANS( $v1->cmp( checker=>sub { # my ($correct, $student, $ansHash) = @_; # return $correct.$student == 0; } ) ); # make a custom answer checker as a subroutine sub parallel_vector_cmp { my ($correct, $student, $ansHash) = @_; return $correct->isParallel($student); } ANS( $v3->cmp( checker=>~~¶llel_vector_cmp, showCoordinateHints => 0 ) ); |
Answer evaluation:
We can then use the vectors to check the answers that are given. Note that we have used custom answer checkers for the latter answer evaluators here, taking advantage of the built in dot product and Other properties of MathObjects vectors are given in the MathObjects reference table. |
- POD documentation: parserVectorUtils.pl
- PG macro: parserVectorUtils.pl