The Four Pillars of Geometry Flashcards

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1
Q

Thales Theorem

A line drawn parallel to one side of a triangle cuts the other two sides ___________.

A

Thales Theorem

A line drawn parallel to one side of a triangle cuts the other two sides proportionally.

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2
Q

Invariance of angles in a circle

If A and B are two points on a circle, then for all points C on one of the arcs connecting them, the angle ACB is _______.

A

Invariance of angles in a circle

​If A and B are two points on a circle, then for all points C on one of the arcs connecting them, the angle ACB is constant.

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3
Q

Angle in a semicircle theorem

If A and B are the ends of a diameter of a circle, and C is any other point on the circle, then angle ACB is a ______ angle.

A

Angle in a semicircle theorem

If A and B are the ends of a diameter of a circle, and C is any other point on the circle, then angle ACB is a right angle.

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4
Q

For linear equations, some / all intersection points involved in a straightedge and compass construction can be found with the operations +, -, x, /, sqrt()

A

For linear equations, all intersection points involved in a straightedge and compass construction can be found with the operations +, -, x, /, sqrt()

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5
Q

A transformation f is called an ______ if it sends any two points P1 and P2 to points f(P1) and f(P2) the same distance apart.

Thus, an ______ is a function f with the property:

f(P1) f(P2) | = | P1 P2 |

A

A transformation f is called an isometry if it sends any two points P1 and P2 to points f(P1) and f(P2) the same distance apart.

Thus, an isometry is a function f with the property:

f(P1) f(P2) | = | P1 P2 |

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6
Q

A _______ moves each point of the plane the same distance in the same direction.

It sends each point (x,y) to the point ______, where a and b are the change of distance.

A

A translation moves each point of the plane the same distance in the same direction.

It sends each point (x,y) to the point (x+a, y+b), where a and b are the change of distance.

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7
Q

A ______ takes two numbers c and s such that c2+s2=1 where c and s are the numbers that result from cos() and sin() respectively.

It sends the point (x,y) to the point _______.

A

A rotation takes two numbers c and s such that c2+s2=1 where c and s are the numbers that result from cos() and sin() respectively.

It sends the point (x,y) to the point (cx-sy, sx+cy).

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8
Q

Three Reflections Theorem

Any isometry of R2is a combination of one, two, or three ________.

A

Three Reflections Theorem

Any isometry of R2is a combination of one, two, or three reflections.

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9
Q

The role of transformations was first characterized by Felix Kelin in an address he delivered at the University of Erlangen in 1872. His address is known as the ______ ______, which characterizes geometry as the study of _______ _____ and their _______.

A

The role of transformations was first characterized by Felix Kelin in an address he delivered at the University of Erlangen in 1872. His address is known as the Erlangen Program, which characterizes geometry as the study of transformation groups and their invariants.

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10
Q

The concept of distance is introduced in linear algebra through the concept of the inner product u•v of vectors u and v.

If u = (u1, u2) and v = (v1, v2),

Then u•v = ________

A

The concept of distance is introduced in linear algebra through the concept of the inner product u•v of vectors u and v.

If u = (u1, u2) and v = (v1, v2),

Then u•v = u1v1 + u2v<span>2</span>

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11
Q

The inner product gives us distance because u•u=|u|2

where |u| is the distance of u from the origin 0. It also gives us angles because

u•v = _______

A

The inner product gives us distance because u•u=|u|2

where |u| is the distance of u from the origin 0. It also gives us angles because

u•v = |u| |v| cos(theta)

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12
Q

Complete the 8 properties for something to be considered a vector space:

u+v =

u + (v+w) =

u + 0 =

u + (-u) =

1u =

a(u+v) =

(a+b)u =

a(bu) =

A

Complete the 8 properties for something to be considered a vector space:

u+v = v + u

u + (v+w) = (u+v) + w

u + 0 = u

u + (-u) = 0

1u = u

a(u+v) = au + av

(a+b)u = au + bu

a(bu) = (ab)u

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13
Q

The ____-_____ is preserved as an invariant in a projection. It is a quantity that is associated with four points on a line. If the four points have coordinates p, q, r, s, then their _____-______ is the function of the ordered 4-tuple (p,q,r,s) written as:

_________

A

The cross-ratio is preserved as an invariant in a projection. It is a quantity that is associated with four points on a line. If the four points have coordinates p, q, r, s, then their cross-ratio is the function of the ordered 4-tuple (p,q,r,s) written as:

(r-p) (s-q) / (r-q) (s-p)

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14
Q

It follows immediately from the definition of an isometry that when f and g are isometries, so is their ____ or _____ f•g.

A

It follows immediately from the definition of an isometry that when f and g are isometries, so is their composite or product f•g.

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15
Q

It is less obvious that any isometry f has an ______, __, which is also an isometry. To prove this fact we can use the result that any isometry in R2 is the product of one, two, or three reflections, and thus:

fr3r2r1 = r1r2r3r3r2r1

= r1r2r2r1

= r1r1

= identity function

A

It is less obvious that any isometry f has an inverse, f-1, which is also an isometry. To prove this fact we can use the result that any isometry in R2 is the product of one, two, or three reflections, and thus:

fr3r2r1 = r1r2r3r3r2r1

= r1r2r2r1

= r1r1

= identity function

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16
Q

The following two properties are characteristic of a group of transformations. A transformation of a set S is a function from S to S, and a collection G of transformations forms a group if it has two properties:

1)

2)

A

The following two properties are characteristic of a group of transformations. A transformation of a set S is a function from S to S, and a collection G of transformations forms a group if it has two properties:

1) If f and g are in G, then so if fg
2) If f is in G, then so is its inverse f-1

17
Q

The meaningful concepts of a geometry correspond to properties that are left _____ by a transformation of a group. It is called an ____ of the isometry group. 3 examples of these are:

A

The meaningful concepts of a geometry correspond to properties that are left unchanged by a transformation of a group. It is called an invariant of the isometry group. 3 examples of these are:

distance

straightness of lines

circularity of circles

18
Q

Unlike in R2, in R3 one now has the concept of _______, which distinguishes the ___-___ from the ___-___. We can preserve these transformations of orientation by using products of an even number of reflections of planes.

A

Unlike in R2, in R3 one now has the concept of handedness, which distinguishes the right-hand from the left-hand. We can preserve these transformations of orientation by using products of an even number of reflections of planes.

19
Q

A transformation is called linear if it preserves the following two operations:

_____ = _____

_____ = _____

A

A transformation is called linear if it preserves the following two operations:

f(u + v) = f(u) + f(v)

f(au) = af(u)

20
Q

A linear transformation (x,y) –> (ax+by, cx+dy) is usually represented by the matrix:

A

A linear transformation (x,y) –> (ax+by, cx+dy) is usually represented by the matrix:

(a b,

c d)

21
Q

To find where (x,y) in R2 is sent by f, one writes it as a column vector (x, y) and multiplies this column on the left by M according the matrix product rule:

A

To find where (x,y) in R2 is sent by f, one writes it as a column vector (x, y) and multiplies this column on the left by M according the matrix product rule:

(a b, c d) (x, y) = (ax+by, cx + dy)

22
Q

The main advantage of the matrix notation is that it gives the product of two linear transformations, first (x, y) –> (a2x + b2y, c2x + d2y) and then (x, y) –> (a1x + b1y, c1x + d1y) by the matrix product rule:

A

The main advantage of the matrix notation is that it gives the product of two linear transformations, first (x, y) –> (a2x + b2y, c2x + d2y) and then (x, y) –> (a1x + b1y, c1x + d1y) by the matrix product rule:

(a1 b1, c1 d1) (a2 b2, c2 d2) = (a1a2 + b1c2 a1b2 + b1d2,

c1a2 + d1c2, c1b2 + c1b2 + d1d2)

23
Q

Matrix notation also exposes the role of the determinant, det(M) which must be __-____ for the linear transformation to have an inverse.

If M = ( a b, c d ),

then det(M) = ____

A

Matrix notation also exposes the role of the determinant, det(M) which must be non-zero for the linear transformation to have an inverse.

If M = ( a b, c d ),

then det(M) = ad - bc

24
Q

If the det(M) != 0,

then M-1 = _________

A

If the det(M) != 0,

then M-1​ = ( 1 / det(M) ) * ( d -b, -c a )

25
Q

Linear transformations preserve geometrically natural properties such as straightness and parallelism, but they also preserve origin, which is really not geometrically different from any other point. To abolish the special position of the origin, we allow linear transformations to be composed with translations, thus obtaining what are called _____ transformations. They preserve everything about linear transformations except for _____.

A

Linear transformations preserve geometrically natural properties such as straightness and parallelism, but they also preserve origin, which is really not geometrically different from any other point. To abolish the special position of the origin, we allow linear transformations to be composed with translations, thus obtaining what are called affine transformations. They preserve everything about linear transformations except for position.

26
Q

The unit sphere in R3 consists of all points at unit distance from O, that is all points (x, y, z) satisfying the equation _______ = __

This surface is also called a _-____ or __ because its points can be described by two coordinates, ______ and ______. It is essentially two-dimensional.

A

The unit sphere in R3 consists of all points at unit distance from O, that is all points (x, y, z) satisfying the equation x2 + y2 + z2 = 1

This surface is also called a 2-sphere or S2 because its points can be described by two coordinates, latitude and longitude. It is essentially two-dimensional.

27
Q

There are products of reflections in three planes that are different from products of reflections in one or two planes. One such isometry is called the _____ ___ which sends each point (x, y, z) to its _____ _____ (-x, -y, -z).

A

There are products of reflections in three planes that are different from products of reflections in one or two planes. One such isometry is called the antipodal map which sends each point (x, y, z) to its antipodal point (-x, -y, -z).

28
Q

The most elegant and practical way to represent rotations of R3 or S2 is with the help of _______. These are a 2x2 matrix of the form

q = _______ where a, b, c, d in R2 and i2 = -1

A

The most elegant and practical way to represent rotations of R3 or S2 is with the help of quaternions. These are a 2x2 matrix of the form

q = (a+bi c+di, -c+di a-bi)

where a, b, c, d in R2 and i2 = -1

29
Q

The determinant of the quaternion q is given by

__________

A

The determinant of the quaternion q is given by

det q = a2 + b2 + c2 + d2 = |q|2

30
Q

A group of rotations is itself a _____ _____.

A

A group of rotations is itself a geometric object.

31
Q

We define an abstract group to be a set G, which contains a special element 1 and for each g an element g-1, with a product operation satisfying the following three axioms:

A

We define an abstract group to be a set G, which contains a special element 1 and for each g an element g-1, with a product operation satisfying the following three axioms:

g1(g2g3) = (g1g2)g3 associativity

g1 = g identity

gg-1 = 1 inverse

32
Q

When we say that the elements of a certain group G correspond to or behave like or can be viewed as elements of another group G|, we have in mind a precise relationship called an ______ of G onto G|. This also means that there is a ___-__-___ _______ between G and G|, and that this preserves _____.

A

When we say that the elements of a certain group G correspond to or behave like or can be viewed as elements of another group G|, we have in mind a precise relationship called an isomorphism of G onto G|. This also means that there is a one-to-one correspondence between G and G|​, and that this preserves products.

33
Q

Hamilton thought that R3 could be viewed as a number system by some clever choice of multiplication rule. He took a “number system” to be what we now call a ____ together with an absolute value

|u| = sqrt( u12 + u22​ + u32​ )

A

Hamilton thought that R3 could be viewed as a number system by some clever choice of multiplication rule. He took a “number system” to be what we now call a field together with an absolute value

|u| = sqrt( u12 + u22​ + u32​ )

34
Q

The simplest surface of constant negative curvature is called the ________ or the ______.

A

The simplest surface of constant negative curvature is called the pseudosphere or the tractoid.

35
Q

Beltrami’s first discovery in 1865, established the special role of constant curvature in geometry: The surfaces of constant curvature are precisely those surfaces that can be mapped to the plane in such a way that geodesics map to _____ _____.

A

Beltrami’s first discovery in 1865, established the special role of constant curvature in geometry: The surfaces of constant curvature are precisely those surfaces that can be mapped to the plane in such a way that geodesics map to straight lines.

36
Q
A