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Mohr–Mascheroni theorem

January 08, 2023

In mathematics, the Mohr–Mascheroni theorem states that any geometric construction that can be performed by a compass and straightedge can be performed by a compass alone.

It must be understood that by "any geometric construction", we are referring to figures that contain no straight lines, as it is clearly impossible to draw a straight line without a straightedge. It is understood that a line is determined provided that two distinct points on that line are given or constructed, even though no visual representation of the line will be present. The theorem can be stated more precisely as:[1]

Any Euclidean construction, insofar as the given and required elements are points (or circles), may be completed with the compass alone if it can be completed with both the compass and the straightedge together.

Though the use of a straightedge can make a construction significantly easier, the theorem shows that any set of points that fully defines a constructed figure can be determined with compass alone, and the only reason to use a straightedge is for the aesthetics of seeing straight lines, which for the purposes of construction is functionally unnecessary.

History

The result was originally published by Georg Mohr in 1672,[2] but his proof languished in obscurity until 1928.[3][4][5] The theorem was independently discovered by Lorenzo Mascheroni in 1797 and it was known as Mascheroni's Theorem until Mohr's work was rediscovered.[6]

Several proofs of the result are known. Mascheroni's proof of 1797 was generally based on the idea of using reflection in a line as the major tool. Mohr's solution was different.[3] In 1890, August Adler published a proof using the inversion transformation.[7]

An algebraic approach uses the isomorphism between the Euclidean plane and the real coordinate space  . In this way, a stronger version of the theorem was proven in 1990.[8] It also shows the dependence of the theorem on Archimedes' axiom (which cannot be formulated in a first-order language).

Constructive proof

Outline

To prove the theorem, each of the basic constructions of compass and straightedge need to be proven to be possible by using a compass alone, as these are the foundations of, or elementary steps for, all other constructions. These are:

  1. Creating the line through two existing points
  2. Creating the circle through one point with centre another point
  3. Creating the point which is the intersection of two existing, non-parallel lines
  4. Creating the one or two points in the intersection of a line and a circle (if they intersect)
  5. Creating the one or two points in the intersection of two circles (if they intersect).

#1 - A line through two points

It is understood that a straight line cannot be drawn without a straightedge. A line is considered to be given by any two points, as any such pair define a unique line. In keeping with the intent of the theorem which we aim to prove, the actual line need not be drawn but for aesthetic reasons.

#2 - A circle through one point with defined center

This can be done with a compass alone. A straightedge is not required for this.

#5 - Intersection of two circles

This construction can also be done directly with a compass.

#3, #4 - The other constructions

Thus, to prove the theorem, only compass-only constructions for #3 and #4 need to be given.

Notation and remarks

The following notation will be used throughout this article. A circle whose center is located at point U and that passes through point V will be denoted by U(V). A circle with center U and radius specified by a number, r, or a line segment AB will be denoted by U(r) or U(AB), respectively.[9]

In general constructions there are often several variations that will produce the same result. The choices made in such a variant can be made without loss of generality. However, when a construction is being used to prove that something can be done, it is not necessary to describe all these various choices and, for the sake of clarity of exposition, only one variant will be given below. However, many constructions come in different forms depending on whether or not they use circle inversion and these alternatives will be given if possible.

It is also important to note that some of the constructions proving the Mohr-Mascheroni theorem require the arbitrary placement of points in space, such as finding the center of a circle when not already provided (see construction below). In some construction paradigms - such as in the geometric definition of the constructible number - this may be prohibited. In such a paradigm, however, for example, circles without their centers will not be provided by hypothesis, thus there is no issue.

Some preliminary constructions

To prove the above constructions #3 and #4, which are included below, a few necessary intermediary constructions are also explained below since they are used and referenced frequently. These are also compass-only constructions. All constructions below rely on #1,#2,#5, and any other construction that is listed prior to it.

Compass equivalence theorem (circle translation)

Main article: Compass equivalence theorem

The ability to translate, or copy, a circle to a new center is vital in these proofs and fundamental to establishing the veracity of the theorem. The creation of a new circle with the same radius as the first, but centered at a different point, is the key feature distinguishing the collapsing compass from the modern, rigid compass. With the rigid compass this is a triviality, but with the collapsing compass it is a question of construction possibility. The equivalence of a collapsing compass and a rigid compass was proved by Euclid (Book I Proposition 2 of The Elements) using straightedge and collapsing compass when he, essentially, constructs a copy of a circle with a different center. This equivalence can also be established with compass alone, a proof of which can be found in the main article.

Reflecting a point across a line

 
Point symmetry
  • Given a line segment AB and a point C not on the line determined by that segment, construct the image of C upon reflection across this line.
  1. Construct two circles: one centered at A and one centered at B, both passing through C.
  2. D, the other point of intersection of the two circles, is the reflection of C across the line AB.
    • If C = D (that is, there is a unique point of intersection of the two circles), then C is its own reflection and lies on the line AB (contrary to the assumption), and the two circles are internally tangential.

Extending the length of a line segment

 
A compass-only construction of doubling the length of segment AB
  • Given a line segment AB find a point C on the line AB such that B is the midpoint of line segment AC.[10]
  1. Construct point D as the intersection of circles A(B) and B(A). (∆ABD is an equilateral triangle.)
  2. Construct point EA as the intersection of circles D(B) and B(D). (∆DBE is an equilateral triangle.)
  3. Finally, construct point CD as the intersection of circles B(E) and E(B). (∆EBC is an equilateral triangle, and the three angles at B show that A, B and C are collinear.)

This construction can be repeated as often as necessary to find a point Q so that the length of line segment AQ = n⋅ length of line segment AB for any positive integer n.

Inversion in a circle

 
Point inversion in a circle
  • Given a circle B(r), for some radius r (in black) and a point D (≠ B) construct the point I that is the inverse of D in the circle.[11] Naturally there is no inversion for a point  .
  1. Draw a circle D(B) (in red).
  2. Assume that the red circle intersects the black circle at E and E'
    • if the circles do not intersect in two points see below for an alternative construction.
    • if the circles intersect in only one point,  , it is possible to invert   simply by doubling the length of   (quadrupling the length of  ).
  3. Reflect the circle center   across the line  :
    1. Construct two new circles E(B) and E' (B) (in light blue).
    2. The light blue circles intersect at B and at another point IB.
  4. Point I is the desired inverse of D in the black circle.

Point I is such that the radius r of B(r) is to IB as DB is to the radius; or IB / r = r / DB.

In the event that the above construction fails (that is, the red circle and the black circle do not intersect in two points),[12] find a point Q on the line BD so that the length of line segment BQ is a positive integral multiple, say n, of the length of BD and is greater than r / 2 (this is possible by Archimede's axiom). Find Q' the inverse of Q in circle B(r) as above (the red and black circles must now intersect in two points). The point I is now obtained by extending BQ' so that BI = nBQ' .

Determining the center of a circle through three points

 
Compass-only construction of the center of a circle through three points (A,B,C)
  • Given three non-collinear points A, B and C, find the center O of the circle they determine.[13]
  1. Construct point D, the inverse of C in the circle A(B).
  2. Reflect A in the line BD to the point X.
  3. O is the inverse of X in the circle A(B).

Intersection of two non-parallel lines (construction #3)

 
Compass-only construction of the intersection of two lines (not all construction steps shown)
  • Given non-parallel lines AB and CD, find their point of intersection, X.[13]
  1. Select circle O(r) of arbitrary radius whose center O does not lie on either line.
  2. Invert points A and B in circle O(r) to points A' and B' respectively.
  3. The line AB is inverted to the circle passing through O, A' and B'. Find the center E of this circle.
  4. Invert points C and D in circle O(r) to points C' and D' respectively.
  5. The line CD is inverted to the circle passing through O, C' and D'. Find the center F of this circle.
  6. Let YO be the intersection of circles E(O) and F(O).
  7. X is the inverse of Y in the circle O(r).

Intersection of a line and a circle (construction #4)

The compass-only construction of the intersection points of a line and a circle breaks into two cases depending upon whether the center of the circle is or is not collinear with the line.

Circle center is not collinear with the line

Assume that center of the circle does not lie on the line.

 
Line-circle intersection (non-collinear case)
  • Given a circle C(r) (in black) and a line AB. We wish to construct the points of intersection, P and Q, between them (if they exist).[14][15]
  1. Construct the point D, which is the reflection of point C across line AB. (See above.)
    • Under the assumption of this case, CD.
  2. Construct a circle D(r) (in red). (See above, compass equivalence.)
  3. The intersections of circle C(r) and the new red circle D(r) are points P and Q.
    • If the two circles are (externally) tangential then  .
  4. Points P and Q are the intersection points of circle C(r) and the line AB.
    • If   then the line is tangential to the circle  .

An alternate construction, using circle inversion can also be given.[13]

  • Given a circle C(r) and a line AB. We wish to construct the points of intersection, P and Q, between them (if they exist).
  1. Invert points A and B in circle C(r) to points A' and B' respectively.
    • Under the assumption of this case, points A', B', and C are not collinear.
  2. Find the center E of the circle passing through points C, A', and B'.
  3. Construct circle E(C), which represents the inversion of the line AB into circle C(r).
  4. P and Q are the intersection points of circles C(r) and E(C).[16]
    • If the two circles are (internally) tangential then  , and the line is also tangential.

Circle center is collinear with the line

 
Compass only construction of intersection of a circle and a line (circle center on line)
  • Given the circle C(D) whose center C lies on the line AB, find the points P and Q, the intersection points of the circle and the line.[17]
  1. Construct point D' D as the other intersection of circles A(D) and C(D).
  2. Construct point F as the intersection of circles C(DD' ) and D(C). (F is the fourth vertex of parallelogram CD'DF.)
  3. Construct point F' as the intersection of circles C(DD' ) and D' (C). (F' is the fourth vertex of parallelogram CDD'F'.)
  4. Construct point M as an intersection of circles F(D' ) and F' (D). (M lies on AB.)
  5. Points P and Q are the intersections of circles F(CM) and C(D).

Thus it has been shown that all of the basic construction one can perform with a straightedge and compass can be done with a compass alone, provided that it is understood that a line cannot be literally drawn but merely defined by two points.

Other types of restricted construction

Renaissance mathematicians Lodovico Ferrari, Gerolamo Cardano and Niccolò Fontana Tartaglia and others were able to show in the 16th century that any ruler-and-compass construction could be accomplished with a straightedge and a fixed-width compass (i.e. a rusty compass).[18]

Motivated by Mascheroni's result, in 1822 Jean Victor Poncelet conjectured a variation on the same theme. He proposed that any construction possible by straightedge and compass could be done with straightedge alone. The one stipulation though is that a single circle with its center identified must be provided. This statement, now known as the Poncelet-Steiner theorem, was proved by Jakob Steiner eleven years later.

A proof later provided in 1904 by Francesco Severi relaxes the requirement that one full circle be provided, and shows that any small arc of the circle, so long as the center is still provided, is still sufficient.[19]

Additionally, the center itself may be omitted instead of portions of the arc, if it is substituted for something else sufficient, such as a second concentric or intersecting circle, or a third circle, or a non-intersecting second circle provided a point on either the centerline or the radial axis between them is given.

The compass equivalency theorem shows that in all the constructions mentioned above, the familiar modern compass with its fixable aperture, which can be used to transfer distances, may be replaced with a "collapsible compass", a compass that collapses whenever it is lifted from a page, so that it may not be directly used to transfer distances. Indeed, Euclid's original constructions use a collapsible compass.

See also

Notes

  1. ^ Eves 1963, p. 201
  2. ^ Georg Mohr, Euclides Danicus (Amsterdam: Jacob van Velsen, 1672).
  3. ^ a b Eves 1963, p. 199
  4. ^ Hjelmslev, J. (1928) "Om et af den danske matematiker Georg Mohr udgivet skrift Euclides Danicus, udkommet i Amsterdam i 1672" [Of a memoir Euclides Danicus published by the Danish mathematician Georg Mohr in 1672 in Amsterdam], Matematisk Tidsskrift B , pages 1–7.
  5. ^ Schogt, J. H. (1938) "Om Georg Mohr's Euclides Danicus," Matematisk Tidsskrift A , pages 34–36.
  6. ^ Lorenzo Mascheroni, La Geometria del Compasso (Pavia: Pietro Galeazzi, 1797). 1901 edition.
  7. ^ Eves 1963, p. 198
  8. ^ Arnon Avron, "On strict strong constructibility with a compass alone", Journal of Geometry (1990) 38: 12.
  9. ^ Eves 1963, p. 184
  10. ^ Pedoe 1988, p. 78
  11. ^ Pedoe 1988, p. 77
  12. ^ Pedoe 1988, p. 78
  13. ^ a b c Pedoe 1988, p. 123
  14. ^ Hungerbühler 1994, p. 784
  15. ^ Eves 1963, p. 199
  16. ^ Pedoe carries out one more inversion at this point, but the points P and Q are on the circle of inversion and so are invariant under this last unneeded inversion.
  17. ^ Eves 1963, p. 200
  18. ^ Retz, Merlyn; Keihn, Meta Darlene (1989), "Compass and Straightedge Constructions", Historical Topics for the Mathematics Classroom, National Council of Teachers of Mathematics (NCTM), p. 195, ISBN 9780873532815
  19. ^ Retz & Keihn 1989, p. 196

References

  • Eves, Howard (1963), A Survey of Geometry (Volume One), Allyn and Bacon
  • Hungerbühler, Norbert (1994), "A Short Elementary Proof of the Mohr–Mascheroni Theorem", The American Mathematical Monthly, 101 (8): 784–787, doi:10.1080/00029890.1994.11997027
  • Pedoe, Dan (1988) [1970], Geometry / A Comprehensive Course, Dover, ISBN 978-0-486-65812-4

Further reading

  • Pedoe, Dan (1995) [1957], "1 Section 11: Compass geometry", Circles / A Mathematical View, Mathematical Association of America, pp. 23–25, ISBN 978-0-88385-518-8
  • Posamentier, Alfred S.; Geretschläger, Robert (2016), "8. Mascheroni constructions using only the compass", The Circle, Prometheus Books, pp. 197–216, ISBN 978-1-63388-167-9

External links

  • Construction with the Compass Only

January 08, 2023
mohr, mascheroni, theorem, mathematics, states, that, geometric, construction, that, performed, compass, straightedge, performed, compass, alone, must, understood, that, geometric, construction, referring, figures, that, contain, straight, lines, clearly, impo. In mathematics the Mohr Mascheroni theorem states that any geometric construction that can be performed by a compass and straightedge can be performed by a compass alone It must be understood that by any geometric construction we are referring to figures that contain no straight lines as it is clearly impossible to draw a straight line without a straightedge It is understood that a line is determined provided that two distinct points on that line are given or constructed even though no visual representation of the line will be present The theorem can be stated more precisely as 1 Any Euclidean construction insofar as the given and required elements are points or circles may be completed with the compass alone if it can be completed with both the compass and the straightedge together Though the use of a straightedge can make a construction significantly easier the theorem shows that any set of points that fully defines a constructed figure can be determined with compass alone and the only reason to use a straightedge is for the aesthetics of seeing straight lines which for the purposes of construction is functionally unnecessary Contents 1 History 2 Constructive proof 2 1 Outline 2 2 Notation and remarks 2 3 Some preliminary constructions 2 3 1 Compass equivalence theorem circle translation 2 3 2 Reflecting a point across a line 2 3 3 Extending the length of a line segment 2 3 4 Inversion in a circle 2 3 5 Determining the center of a circle through three points 2 4 Intersection of two non parallel lines construction 3 2 5 Intersection of a line and a circle construction 4 2 5 1 Circle center is not collinear with the line 2 5 2 Circle center is collinear with the line 3 Other types of restricted construction 4 See also 5 Notes 6 References 7 Further reading 8 External linksHistory EditThe result was originally published by Georg Mohr in 1672 2 but his proof languished in obscurity until 1928 3 4 5 The theorem was independently discovered by Lorenzo Mascheroni in 1797 and it was known as Mascheroni s Theorem until Mohr s work was rediscovered 6 Several proofs of the result are known Mascheroni s proof of 1797 was generally based on the idea of using reflection in a line as the major tool Mohr s solution was different 3 In 1890 August Adler published a proof using the inversion transformation 7 An algebraic approach uses the isomorphism between the Euclidean plane and the real coordinate space R 2 displaystyle mathbb R 2 In this way a stronger version of the theorem was proven in 1990 8 It also shows the dependence of the theorem on Archimedes axiom which cannot be formulated in a first order language Constructive proof EditOutline Edit To prove the theorem each of the basic constructions of compass and straightedge need to be proven to be possible by using a compass alone as these are the foundations of or elementary steps for all other constructions These are Creating the line through two existing points Creating the circle through one point with centre another point Creating the point which is the intersection of two existing non parallel lines Creating the one or two points in the intersection of a line and a circle if they intersect Creating the one or two points in the intersection of two circles if they intersect 1 A line through two pointsIt is understood that a straight line cannot be drawn without a straightedge A line is considered to be given by any two points as any such pair define a unique line In keeping with the intent of the theorem which we aim to prove the actual line need not be drawn but for aesthetic reasons 2 A circle through one point with defined centerThis can be done with a compass alone A straightedge is not required for this 5 Intersection of two circlesThis construction can also be done directly with a compass 3 4 The other constructionsThus to prove the theorem only compass only constructions for 3 and 4 need to be given Notation and remarks Edit The following notation will be used throughout this article A circle whose center is located at point U and that passes through point V will be denoted by U V A circle with center U and radius specified by a number r or a line segment AB will be denoted by U r or U AB respectively 9 In general constructions there are often several variations that will produce the same result The choices made in such a variant can be made without loss of generality However when a construction is being used to prove that something can be done it is not necessary to describe all these various choices and for the sake of clarity of exposition only one variant will be given below However many constructions come in different forms depending on whether or not they use circle inversion and these alternatives will be given if possible It is also important to note that some of the constructions proving the Mohr Mascheroni theorem require the arbitrary placement of points in space such as finding the center of a circle when not already provided see construction below In some construction paradigms such as in the geometric definition of the constructible number this may be prohibited In such a paradigm however for example circles without their centers will not be provided by hypothesis thus there is no issue Some preliminary constructions Edit To prove the above constructions 3 and 4 which are included below a few necessary intermediary constructions are also explained below since they are used and referenced frequently These are also compass only constructions All constructions below rely on 1 2 5 and any other construction that is listed prior to it Compass equivalence theorem circle translation Edit Main article Compass equivalence theorem The ability to translate or copy a circle to a new center is vital in these proofs and fundamental to establishing the veracity of the theorem The creation of a new circle with the same radius as the first but centered at a different point is the key feature distinguishing the collapsing compass from the modern rigid compass With the rigid compass this is a triviality but with the collapsing compass it is a question of construction possibility The equivalence of a collapsing compass and a rigid compass was proved by Euclid Book I Proposition 2 of The Elements using straightedge and collapsing compass when he essentially constructs a copy of a circle with a different center This equivalence can also be established with compass alone a proof of which can be found in the main article Reflecting a point across a line Edit Point symmetry Given a line segment AB and a point C not on the line determined by that segment construct the image of C upon reflection across this line Construct two circles one centered at A and one centered at B both passing through C D the other point of intersection of the two circles is the reflection of C across the line AB If C D that is there is a unique point of intersection of the two circles then C is its own reflection and lies on the line AB contrary to the assumption and the two circles are internally tangential Extending the length of a line segment Edit A compass only construction of doubling the length of segment AB Given a line segment AB find a point C on the line AB such that B is the midpoint of line segment AC 10 Construct point D as the intersection of circles A B and B A ABD is an equilateral triangle Construct point E A as the intersection of circles D B and B D DBE is an equilateral triangle Finally construct point C D as the intersection of circles B E and E B EBC is an equilateral triangle and the three angles at B show that A B and C are collinear This construction can be repeated as often as necessary to find a point Q so that the length of line segment AQ n length of line segment AB for any positive integer n Inversion in a circle Edit Point inversion in a circle Given a circle B r for some radius r in black and a point D B construct the point I that is the inverse of D in the circle 11 Naturally there is no inversion for a point D B textstyle D B Draw a circle D B in red Assume that the red circle intersects the black circle at E and E if the circles do not intersect in two points see below for an alternative construction if the circles intersect in only one point E E displaystyle E E it is possible to invert D displaystyle D simply by doubling the length of E B displaystyle EB quadrupling the length of D B displaystyle DB Reflect the circle center B displaystyle B across the line E E displaystyle EE Construct two new circles E B and E B in light blue The light blue circles intersect at B and at another point I B Point I is the desired inverse of D in the black circle Point I is such that the radius r of B r is to IB as DB is to the radius or IB r r DB In the event that the above construction fails that is the red circle and the black circle do not intersect in two points 12 find a point Q on the line BD so that the length of line segment BQ is a positive integral multiple say n of the length of BD and is greater than r 2 this is possible by Archimede s axiom Find Q the inverse of Q in circle B r as above the red and black circles must now intersect in two points The point I is now obtained by extending BQ so that BI n BQ Determining the center of a circle through three points Edit Compass only construction of the center of a circle through three points A B C Given three non collinear points A B and C find the center O of the circle they determine 13 Construct point D the inverse of C in the circle A B Reflect A in the line BD to the point X O is the inverse of X in the circle A B Intersection of two non parallel lines construction 3 Edit Compass only construction of the intersection of two lines not all construction steps shown Given non parallel lines AB and CD find their point of intersection X 13 Select circle O r of arbitrary radius whose center O does not lie on either line Invert points A and B in circle O r to points A and B respectively The line AB is inverted to the circle passing through O A and B Find the center E of this circle Invert points C and D in circle O r to points C and D respectively The line CD is inverted to the circle passing through O C and D Find the center F of this circle Let Y O be the intersection of circles E O and F O X is the inverse of Y in the circle O r Intersection of a line and a circle construction 4 Edit The compass only construction of the intersection points of a line and a circle breaks into two cases depending upon whether the center of the circle is or is not collinear with the line Circle center is not collinear with the line Edit Assume that center of the circle does not lie on the line Line circle intersection non collinear case Given a circle C r in black and a line AB We wish to construct the points of intersection P and Q between them if they exist 14 15 Construct the point D which is the reflection of point C across line AB See above Under the assumption of this case C D Construct a circle D r in red See above compass equivalence The intersections of circle C r and the new red circle D r are points P and Q If the two circles are externally tangential then P Q displaystyle P Q Points P and Q are the intersection points of circle C r and the line AB If P Q displaystyle P Q then the line is tangential to the circle C r displaystyle C r An alternate construction using circle inversion can also be given 13 Given a circle C r and a line AB We wish to construct the points of intersection P and Q between them if they exist Invert points A and B in circle C r to points A and B respectively Under the assumption of this case points A B and C are not collinear Find the center E of the circle passing through points C A and B Construct circle E C which represents the inversion of the line AB into circle C r P and Q are the intersection points of circles C r and E C 16 If the two circles are internally tangential then P Q displaystyle P Q and the line is also tangential Circle center is collinear with the line Edit Compass only construction of intersection of a circle and a line circle center on line Given the circle C D whose center C lies on the line AB find the points P and Q the intersection points of the circle and the line 17 Construct point D D as the other intersection of circles A D and C D Construct point F as the intersection of circles C DD and D C F is the fourth vertex of parallelogram CD DF Construct point F as the intersection of circles C DD and D C F is the fourth vertex of parallelogram CDD F Construct point M as an intersection of circles F D and F D M lies on AB Points P and Q are the intersections of circles F CM and C D Thus it has been shown that all of the basic construction one can perform with a straightedge and compass can be done with a compass alone provided that it is understood that a line cannot be literally drawn but merely defined by two points Other types of restricted construction EditRenaissance mathematicians Lodovico Ferrari Gerolamo Cardano and Niccolo Fontana Tartaglia and others were able to show in the 16th century that any ruler and compass construction could be accomplished with a straightedge and a fixed width compass i e a rusty compass 18 Motivated by Mascheroni s result in 1822 Jean Victor Poncelet conjectured a variation on the same theme He proposed that any construction possible by straightedge and compass could be done with straightedge alone The one stipulation though is that a single circle with its center identified must be provided This statement now known as the Poncelet Steiner theorem was proved by Jakob Steiner eleven years later A proof later provided in 1904 by Francesco Severi relaxes the requirement that one full circle be provided and shows that any small arc of the circle so long as the center is still provided is still sufficient 19 Additionally the center itself may be omitted instead of portions of the arc if it is substituted for something else sufficient such as a second concentric or intersecting circle or a third circle or a non intersecting second circle provided a point on either the centerline or the radial axis between them is given The compass equivalency theorem shows that in all the constructions mentioned above the familiar modern compass with its fixable aperture which can be used to transfer distances may be replaced with a collapsible compass a compass that collapses whenever it is lifted from a page so that it may not be directly used to transfer distances Indeed Euclid s original constructions use a collapsible compass See also EditNapoleon s problem Geometrography Inversive geometryNotes Edit Eves 1963 p 201 Georg Mohr Euclides Danicus Amsterdam Jacob van Velsen 1672 a b Eves 1963 p 199 Hjelmslev J 1928 Om et af den danske matematiker Georg Mohr udgivet skrift Euclides Danicus udkommet i Amsterdam i 1672 Of a memoir Euclides Danicus published by the Danish mathematician Georg Mohr in 1672 in Amsterdam Matematisk Tidsskrift B pages 1 7 Schogt J H 1938 Om Georg Mohr s Euclides Danicus Matematisk Tidsskrift A pages 34 36 Lorenzo Mascheroni La Geometria del Compasso Pavia Pietro Galeazzi 1797 1901 edition Eves 1963 p 198 Arnon Avron On strict strong constructibility with a compass alone Journal of Geometry 1990 38 12 Eves 1963 p 184 Pedoe 1988 p 78 Pedoe 1988 p 77 Pedoe 1988 p 78 a b c Pedoe 1988 p 123 Hungerbuhler 1994 p 784 Eves 1963 p 199 Pedoe carries out one more inversion at this point but the points P and Q are on the circle of inversion and so are invariant under this last unneeded inversion Eves 1963 p 200 Retz Merlyn Keihn Meta Darlene 1989 Compass and Straightedge Constructions Historical Topics for the Mathematics Classroom National Council of Teachers of Mathematics NCTM p 195 ISBN 9780873532815 Retz amp Keihn 1989 p 196References EditEves Howard 1963 A Survey of Geometry Volume One Allyn and Bacon Hungerbuhler Norbert 1994 A Short Elementary Proof of the Mohr Mascheroni Theorem The American Mathematical Monthly 101 8 784 787 doi 10 1080 00029890 1994 11997027 Pedoe Dan 1988 1970 Geometry A Comprehensive Course Dover ISBN 978 0 486 65812 4Further reading EditPedoe Dan 1995 1957 1 Section 11 Compass geometry Circles A Mathematical View Mathematical Association of America pp 23 25 ISBN 978 0 88385 518 8 Posamentier Alfred S Geretschlager Robert 2016 8 Mascheroni constructions using only the compass The Circle Prometheus Books pp 197 216 ISBN 978 1 63388 167 9External links EditConstruction with the Compass Only Retrieved from https en wikipedia org w index php title Mohr Mascheroni theorem amp oldid 1103141981, wikipedia, wiki, book, books, library,

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