Mass point geometry explained

Mass point geometry, colloquially known as mass points, is a problem-solving technique in geometry which applies the physical principle of the center of mass to geometry problems involving triangles and intersecting cevians.[1] All problems that can be solved using mass point geometry can also be solved using either similar triangles, vectors, or area ratios,[2] but many students prefer to use mass points. Though modern mass point geometry was developed in the 1960s by New York high school students,[3] the concept has been found to have been used as early as 1827 by August Ferdinand Möbius in his theory of homogeneous coordinates.[4]

Definitions

The theory of mass points is defined according to the following definitions:[5]

(m,P)

, also written as

mP

, including a mass,

m

, and an ordinary point,

P

on a plane.

mP

and

nQ

coincide if and only if

m=n

and

P=Q

.

mP

and

nQ

has mass

m+n

and point

R

where

R

is the point on

PQ

such that

PR:RQ=n:m

. In other words,

R

is the fulcrum point that perfectly balances the points

P

and

Q

. An example of mass point addition is shown at right. Mass point addition is closed, commutative, and associative.

mP

and a positive real scalar

k

, we define multiplication to be

k(m,P)=(km,P)

. Mass point scalar multiplication is distributive over mass point addition.

Methods

Concurrent cevians

First, a point is assigned with a mass (often a whole number, but it depends on the problem) in the way that other masses are also whole numbers.The principle of calculation is that the foot of a cevian is the addition (defined above) of the two vertices (they are the endpoints of the side where the foot lie).For each cevian, the point of concurrency is the sum of the vertex and the foot.Each length ratio may then be calculated from the masses at the points. See Problem One for an example.

Splitting masses

Splitting masses is the slightly more complicated method necessary when a problem contains transversals in addition to cevians. Any vertex that is on both sides the transversal crosses will have a split mass. A point with a split mass may be treated as a normal mass point, except that it has three masses: one used for each of the two sides it is on, and one that is the sum of the other two split masses and is used for any cevians it may have. See Problem Two for an example.

Other methods

Examples

Problem One

Problem. In triangle

ABC

,

E

is on

AC

so that

CE=3AE

and

F

is on

AB

so that

BF=3AF

. If

BE

and

CF

intersect at

O

and line

AO

intersects

BC

at

D

, compute

\tfrac{OB}{OE}

and

\tfrac{OD}{OA}

.

Solution. We may arbitrarily assign the mass of point

A

to be

3

. By ratios of lengths, the masses at

B

and

C

must both be

1

. By summing masses, the masses at

E

and

F

are both

4

. Furthermore, the mass at

O

is

4+1=5

, making the mass at

D

have to be

5-3=2

Therefore

\tfrac{OB}{OE}

=4

and

\tfrac{OD}{OA}=\tfrac{3}{2}

. See diagram at right.

Problem Two

Problem. In triangle

ABC

,

D

,

E

, and

F

are on

BC

,

CA

, and

AB

, respectively, so that

AE=AF=CD=2

,

BD=CE=3

, and

BF=5

. If

DE

and

CF

intersect at

O

, compute

\tfrac{OD}{OE}

and

\tfrac{OC}{OF}

.

Solution. As this problem involves a transversal, we must use split masses on point

C

. We may arbitrarily assign the mass of point

A

to be

15

. By ratios of lengths, the mass at

B

must be

6

and the mass at

C

is split

10

towards

A

and

9

towards

B

. By summing masses, we get the masses at

D

,

E

, and

F

to be

15

,

25

, and

21

, respectively. Therefore

\tfrac{OD}{OE}=\tfrac{25}{15}=\tfrac{5}{3}

and

\tfrac{OC}{OF}=\tfrac{21}{10+9}=\tfrac{21}{19}

.

Problem Three

Problem. In triangle

ABC

, points

D

and

E

are on sides

BC

and

CA

, respectively, and points

F

and

G

are on side

AB

with

G

between

F

and

B

.

BE

intersects

CF

at point

O1

and

BE

intersects

DG

at point

O2

. If

FG=1

,

AE=AF=DB=DC=2

, and

BG=CE=3

, compute

\tfrac{O1O2}{BE}

.

Solution. This problem involves two central intersection points,

O1

and

O2

, so we must use multiple systems.

O1

as our central point, and we may therefore ignore segment

DG

and points

D

,

G

, and

O2

. We may arbitrarily assign the mass at

A

to be

6

, and by ratios of lengths the masses at

B

and

C

are

3

and

4

, respectively. By summing masses, we get the masses at

E

,

F

, and

O1

to be 10, 9, and 13, respectively. Therefore,

\tfrac{EO1}{BO1}=\tfrac{3}{10}

and

\tfrac{EO1}{BE}=\tfrac{3}{13}

.

O2

as our central point, and we may therefore ignore segment

CF

and points

F

and

O1

. As this system involves a transversal, we must use split masses on point

B

. We may arbitrarily assign the mass at

A

to be

3

, and by ratios of lengths, the mass at

C

is

2

and the mass at

B

is split

3

towards

A

and 2 towards

C

. By summing masses, we get the masses at

D

,

G

, and

O2

to be 4, 6, and 10, respectively. Therefore,

\tfrac{BO2}{EO2}=\tfrac{5}{3+2}=1

and

\tfrac{BO2}{BE}=\tfrac{1}{2}

.

See also

Notes

  1. Rhoad, R., Milauskas, G., and Whipple, R. Geometry for Enjoyment and Challenge. McDougal, Littell & Company, 1991.
  2. Web site: Archived copy . 2009-06-13 . https://web.archive.org/web/20100720083314/http://mathcircle.berkeley.edu/archivedocs/2007_2008/lectures/0708lecturesps/MassPointsBMC07.ps . 2010-07-20 . dead .
  3. Rhoad, R., Milauskas, G., and Whipple, R. Geometry for Enjoyment and Challenge. McDougal, Littell & Company, 1991
  4. D. Pedoe Notes on the History of Geometrical Ideas I: Homogeneous Coordinates. Math Magazine (1975), 215-217.
  5. H. S. M. Coxeter, Introduction to Geometry, pp. 216-221, John Wiley & Sons, Inc. 1969