Solutions to the Test. Problem 1. 1) Who is the author of the first comprehensive text on geometry? When and where was it written?

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Solutions to the Test Problem 1. 1) Who is the author of the first comprehensive text on geometry? When and where was it written? Answer: The first comprehensive text on geometry is called The Elements and it was written by Euclid in Alexandria (Egypt) around 300 BC. 2) State three theorems from the Elements which you find important and which speak about both lines and circles. There are many possible choices. Perhaps the most interesting are the following: Book III, Proposition 32. Let A be a point of a circle Γ, let l be the line tangent to Γ at A and let m be a line through A cutting Γ at another point B. If P is a point on l different from A and if C is a point on Γ such that C and P are on the opposite sides of m then PAB ACB. Book III, Proposition 35. Let P be a point inside a circle Γ. Let a line through P cut Γ at A and B and let another line through P cut Γ at C and D. Then AP PB = CP PD (i.e. the rectangle with sides AP, PB has content equal to the content of the rectangle with sides CP, PD). Book III, Proposition 36. Let P be a point outside a circle Γ. Let a line through P cut Γ at A and B and let another line through P be tangent to Γ at C. Then PA PB = PC 2. Remark. By the above propositions, if P is a point not on a circle Γ and if a line through P cuts Γ in two points A,B (A = B when the line is tangent to Γ) then the quantity PA PB is the same for all lines through P. This quantity is called the power of P with respect to Γ. When P is inside the circle, the power is taken with negative sign (i.e. it is PA PB). 3) Define the following concepts a) altitudes, b) medians, c) centroid, d) orthocenter, e) incenter, f) circumcenter An altitude of a triangle is a line passing through a vertex of the triangle and perpendicular to the edge subtended by the vertex. A median of a triangle is a line passing through a vertex of the triangle and the midpoint of the edge subtended by the vertex. The centroid of a triangle is the point where all three medians intersect. 1

The orthocenter of a triangle is the point where all three altitudes intersect. The incenter of a triangle is the point where the angle bisectors of the angles of the triangle intersect. Equivalently, it is the center of the circle inscribed in the triangle. The circumcenter of a triangle is the point where the perpendicular bisectors of the three sides of the triangle intersect. Equivalently, it is the center of the circle circumscribed on the triangle. 4) Define Euler line. What can you say about the position of the points defining this line? The Euler line of a triangle is the line passing through the orthocenter H, the centroid G and the circumcenter O of the triangle. The point G is always between the points H and O and HG is twice OG. Note that Euler line is not defined for equilateral triangles since then the three points coincide. 5) Define the nine point circle. Explain what are the nine points. What can you say about the nine-point center? Let ABC be a triangle, let H be the orthocenter and let H A,H B,H C be the feet of the altitudes through A,B,C respectively (i.e. H A is on BC and AH A is an altitude, etc.). Then the following nine points are on one circle, called the nine-point circle of ABC: the midpoints of sides of ABC, the feet of the altitudes H A,H B,H C and the midpoints of the segments AH, BH, CH. The center of the nine-point circle is called the nine-point center of ABC. The nine point center is on the Euler line and it coincides with the midpoint of the segment joining the orthocenter and the circumcenter. 6) State Pasch axiom. Let l be a line which does not contain any of the vertices of a given triangle and which intersects one of the sides of the triangle. Then l intersects one (and only one) of the remaining two sides. 7) State the circle-circle intersection axiom and the circle-line intersection property(clip). (E) (circle-circle intersection). Let Γ and be two circles. If Γ contains a point inside and a point outside then Γ and have a common point. Circle-line intersection property (CLIP). If a line l contains a point inside a circle Γ then l and Γ have a common point (i.e. they intersect). 8) State the plane separation theorem and explain how the sides of a line are defined. Plane separation. Let l be a line in a geometry which satisfies the incidence axioms and the betweenness axioms. The set of all points not on l can be divided into two disjoint 2

subsets, called the sides of l such that: two points A, B are in the same side of l if and only if l does not intersect the segment AB (i.e. no point on l is between A and B). two points A, B are in different side of l if and only if l intersects the segment AB (i.e. there is a point on l which is between A and B). 9) Define a ray, an angle, and the interior of an angle. A ray AB consists of all points C of the line AB such that A is not between B and C. An angle BAC is the union of the rays AB and AC under the assumption that A,B,C are not collinear. A point P is in the interior of an angle BAC if and only if P and B are on the same side of the line AC and P and C are on the same side of the line AB. 10) What is Hilbert s plane? What is Euclid s plane? Hilbert s plane is a set Π, whose elements are called points such that: Some subsets of Π, called lines, are selected and the incidence axioms are satisfied. A notion of betweenness is defined for some triples of points in Π and the axioms of betweenness are satisfied. A notion of congruence is defined for segments in Π and the congruence axioms C1-C3 are satisfied. A notion of congruence is defined for angles and congruence axioms C4-C6 are satisfied. Euclid s plane is a Hilbert s plane which satisfies the Playfair s Axiom (P) and the circle-circle intersection axiom (E). Problem 2. a) In a triangle the orthocenter coincides with the circumcenter. Prove that the triangle is equilateral. b) In a triangle the nine-point center and the circumcenter coincide. Prove that the triangle is equilateral. Solution. a) Let ABC be a triangle in which the orthocenter H and the circumcenter coincide. The line AH is an altitude, so it is perpendicular to BC. Since H coincides with the circumcenter, the perpendicular bisector of BC passes through H. Since there 3

is unique line through H which is perpendicular to BC, we conclude that AH is the perpendicular bisector of BC. Thus the midpoint M A of BC belongs to AH. Since AM A B is right we have AM A B AM A C. By SAS, the triangles AM A B and AM A C are congruent. In particular, AC AB. In the same way we show that BA BC. This proves that ABC is equilateral. b) Suppose that the circumcenter and the nine-point center of a triangle coincide. Recall that the nine-point center is the midpoint between the orthocenter and the circumcenter. Thus the orthocenter coincides with the circumcenter and the triangle is equilateral by part a). Problem 3. Two circles Γ and Γ in a Euclid s plane are internally tangent at a point A (say Γ is inside Γ ). A ray emanating from A intersects Γ and Γ at points B, B respectively. Another ray emanating from A intersects Γ and Γ at points C, C respectively. Prove that BC and B C are parallel. Carefully explain your reasoning. Hint: consider the line tangent to the circles at A. Solution. Let l be the line tangent to Γ at A. Then all points of l except A are outside of Γ. But all points of Γ except A are inside of Γ. Thus A is the only point of intersection of l and Γ, i.e. l is tangent to Γ too (there are other ways to justify this). Note that the points C,C are on the same side of the line AB (since A C C ). Let P be a point on l which is on the opposite side of the line AB than the side where C,C are. ByProposition32fromBookIIIoftheElements(seethesolutiontoquestion2ofProblem 1), we get that PAB ACB and PAB AC B. Since PAB = PAB, we see that ACB AC B. It follows that the lines BC and B C are parallel (Proposition 27 in Book I). Problem 4. In this problem you can only use the incidence axioms, the betweenness axioms, and the line separation theorem. Suppose that A B C on one line and A D E on a different line. Prove that the segments BE and CD have a common point. Solution. Since A D E, points A and D are on the same side of the line BE. Since A B C, points A and C are on opposite sides of the line BE. Thus C and D are on opposite sides of the line BE and therefore the segment CD intersects line BE at some point P. In the same manner, we show that B and E are on opposite sides of the line CD, hence segment BE intersects the line CD. Thus the point P (the intersection of lines CD and BE) belongs to both segments BE and CD. Problem 5. Let P be a point in the interior of an angle BAC in a Hilbert plane. Let X on line AB be such that line PX is perpendicular to AB. Similarly, let Y on line AC 4

be such that the line PY is perpendicular to the line AC. Prove that if PX PY then X is on the ray AB, Y is on the ray AC, and AP is the angle bisector of BAC. Solution. Note that X Y, otherwise we would have a line PX perpendicular to both arms of an angle, which is not possible. Consider the circle Γ with center P and radius PX PY. Thus the lines AB and AC are tangent to Γ at points X, Y respectively. We have proved that all points of a circle tangent to a line l are on the same side of l as the center of the circle. Thus P and Y are on the same side of AB, which means that A is not between P and Y, i.e Y AC. Same argument shows that X AB. Looking at triangles PXAandPXB, weseethattheyarecongruentbyrass. Thus PAX PAY. Since X AB, we have PAX = PAB. Similarly, PAY = PAC. Thus AP is indeed the angle bisector of BAC. Remark. To show that all points of a circle tangent to a line l are on the same side of l as the center P of the circle (except of course the point T of tangency, which is on l), consider a point Q on the circle. If it was on opposite side of l than P, there would be a point S on l such that P S Q. We would have then PQ > PS > PT (as PS is a hypotenuse in the right triangle PTS), which is a contradiction because PQ PT. Problem 6. In a Hilbert s plane triangles ABC and A B C satisfy the following conditions: the angles at A and A are right angles, AB A B and BC B C. Prove that the triangles are congruent. Solution. It suffices to show that AC A C since then we can use SSS to conclude that the triangles ABC and A B C are congruent. Consider the point D on the line AC such that D and C are on opposite sides of A and AD A C. It exists by the axiom C1. By SAS we conclude that the triangles BAD and B A C are congruent. Thus BD B C. By assumption, B C BC, so BD BC. In other words, the triangle CBD is isosceles. Thus BDC BCD. By AAS, the triangles BAC and BAD are congruent. Consequently, AD AC. Recall that AD A C, so we get that AC A C. 5

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