Difference between revisions of "LocusEquation Command"
From GeoGebra Manual
(;LocusEquation[ <Boolean Expression>, <Free Point> ]) |
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;LocusEquation[ <Locus> ] | ;LocusEquation[ <Locus> ] | ||
:Calculates the equation of a Locus and plots this as an Implicit Curve. | :Calculates the equation of a Locus and plots this as an Implicit Curve. | ||
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;LocusEquation[ <Point Creating Locus Line Q>, <Point P> ] | ;LocusEquation[ <Point Creating Locus Line Q>, <Point P> ] | ||
:Calculates the equation of a Locus by using inputs tracer point ''Q'' and mover point ''P'', and plots this as an Implicit Curve. | :Calculates the equation of a Locus by using inputs tracer point ''Q'' and mover point ''P'', and plots this as an Implicit Curve. | ||
:{{example| 1=<div>Let us construct a parabola as a locus: Create free Points ''A'' and ''B'', and Line ''d'' lying through them (this will be the directrix of the parabola). Create free point ''F'' for the focus. Now create ''P'' on Line ''d'' (the mover point), then create line ''p'' as a perpendicular line to ''d'' through ''P''. Also create line ''b'' as perpendicular bisector of Line Segment ''FP''. Finally, point ''Q'' (the point creating locus line) is to be created as intersection of Lines ''p'' and ''b''. Now <code><nowiki>LocusEquation[Q,P]</nowiki></code> will find and plot the exact equation of the locus.</div>}} | :{{example| 1=<div>Let us construct a parabola as a locus: Create free Points ''A'' and ''B'', and Line ''d'' lying through them (this will be the directrix of the parabola). Create free point ''F'' for the focus. Now create ''P'' on Line ''d'' (the mover point), then create line ''p'' as a perpendicular line to ''d'' through ''P''. Also create line ''b'' as perpendicular bisector of Line Segment ''FP''. Finally, point ''Q'' (the point creating locus line) is to be created as intersection of Lines ''p'' and ''b''. Now <code><nowiki>LocusEquation[Q,P]</nowiki></code> will find and plot the exact equation of the locus.</div>}} | ||
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;LocusEquation[ <Boolean Expression>, <Free Point> ] | ;LocusEquation[ <Boolean Expression>, <Free Point> ] | ||
| − | :Calculates the locus of the free point such that the boolean condition is satisified | + | :Calculates the locus of the free point such that the boolean condition is satisified. |
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:{{example| 1= <code>LocusEquation[AreCollinear[A, B, C],A]</code> for free points A, B, C calculates the set of positions of A that make A, B and C collinear - ie a Line through B and C}} | :{{example| 1= <code>LocusEquation[AreCollinear[A, B, C],A]</code> for free points A, B, C calculates the set of positions of A that make A, B and C collinear - ie a Line through B and C}} | ||
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{{Notes|1=<div> | {{Notes|1=<div> | ||
| − | *Further informations and examples on [http://www.geogebra.org/student/b121563# GeoGebra] | + | *The Locus must be made from a Point (not from a Slider) |
| + | *Works only for a restricted set of geometric loci, i.e. using points, lines, circles, conics. (Rays and line segments will be treated as (infinite) lines.) | ||
| + | *If the locus is too complicated then it will return 'undefined'. | ||
| + | *The calculation is done using [[w:Gröbner_basis|Gröbner bases]], so sometimes extra branches of the curve will appear that were not in the original locus. | ||
| + | *Further informations and examples on [http://www.geogebra.org/student/b121563# GeoGebra]. | ||
*See also [[Locus Command|Locus]] command.</div>}} | *See also [[Locus Command|Locus]] command.</div>}} | ||
Revision as of 12:34, 14 March 2016
- LocusEquation[ <Locus> ]
- Calculates the equation of a Locus and plots this as an Implicit Curve.
- LocusEquation[ <Point Creating Locus Line Q>, <Point P> ]
- Calculates the equation of a Locus by using inputs tracer point Q and mover point P, and plots this as an Implicit Curve.
- Example:Let us construct a parabola as a locus: Create free Points A and B, and Line d lying through them (this will be the directrix of the parabola). Create free point F for the focus. Now create P on Line d (the mover point), then create line p as a perpendicular line to d through P. Also create line b as perpendicular bisector of Line Segment FP. Finally, point Q (the point creating locus line) is to be created as intersection of Lines p and b. Now
LocusEquation[Q,P]will find and plot the exact equation of the locus.
- LocusEquation[ <Boolean Expression>, <Free Point> ]
- Calculates the locus of the free point such that the boolean condition is satisified.
- Example:
LocusEquation[AreCollinear[A, B, C],A]for free points A, B, C calculates the set of positions of A that make A, B and C collinear - ie a Line through B and C
Notes:
- The Locus must be made from a Point (not from a Slider)
- Works only for a restricted set of geometric loci, i.e. using points, lines, circles, conics. (Rays and line segments will be treated as (infinite) lines.)
- If the locus is too complicated then it will return 'undefined'.
- The calculation is done using Gröbner bases, so sometimes extra branches of the curve will appear that were not in the original locus.
- Further informations and examples on GeoGebra.
- See also Locus command.
