Power of a point

Last updated January 24, 2024

Geometric meaning Potenz-geom-e.svg — Geometric meaning

In elementary plane geometry, the power of a point is a real number that reflects the relative distance of a given point from a given circle. It was introduced by Jakob Steiner in 1826.^[1]

Geometric properties
Orthogonal circle
Intersecting secants theorem, intersecting chords theorem
Radical axis
Secants theorem, chords theorem: common proof
Similarity points, common power of two circles
Similarity points
Common power of two circles
Determination of a circle that is tangent to two circles
Power with respect to a sphere
Darboux product
Laguerre's theorem
References
Further reading
External links

Specifically, the power $\Pi (P)$ of a point $P$ with respect to a circle $c$ with center $O$ and radius $r$ is defined by

\Pi (P)=|PO|^{2}-r^{2}.

If $P$ is outside the circle, then $\Pi (P)>0$ ,
if $P$ is on the circle, then $\Pi (P)=0$ and
if $P$ is inside the circle, then $\Pi (P)<0$ .

Due to the Pythagorean theorem the number $\Pi (P)$ has the simple geometric meanings shown in the diagram: For a point $P$ outside the circle $\Pi (P)$ is the squared tangential distance $|PT|$ of point $P$ to the circle $c$ .

Points with equal power, isolines of $\Pi (P)$ , are circles concentric to circle $c$ .

Steiner used the power of a point for proofs of several statements on circles, for example:

Determination of a circle, that intersects four circles by the same angle.^[2]
Solving the Problem of Apollonius
Construction of the Malfatti circles:^[3] For a given triangle determine three circles, which touch each other and two sides of the triangle each.
Spherical version of Malfatti's problem:^[4] The triangle is a spherical one.

Essential tools for investigations on circles are the radical axis of two circles and the radical center of three circles.

The power diagram of a set of circles divides the plane into regions within which the circle minimizing the power is constant.

More generally, French mathematician Edmond Laguerre defined the power of a point with respect to any algebraic curve in a similar way.

Geometric properties

Besides the properties mentioned in the lead there are further properties:

Orthogonal circle

For any point $P$ outside of the circle $c$ there are two tangent points $T_{1},T_{2}$ on circle $c$ , which have equal distance to $P$ . Hence the circle $o$ with center $P$ through $T_{1}$ passes $T_{2}$ , too, and intersects $c$ orthogonal:

The circle with center $P$ and radius ${\sqrt {\Pi (P)}}$ intersects circle $c$ orthogonal.

Angle between two circles Potenz-schnittw-kreis-e.svg — Angle between two circles

If the radius $\rho$ of the circle centered at $P$ is different from ${\sqrt {\Pi (P)}}$ one gets the angle of intersection $\varphi$ between the two circles applying the Law of cosines (see the diagram):

\rho ^{2}+r^{2}-2\rho r\cos \varphi =|PO|^{2}

\rightarrow \ \cos \varphi ={\frac {\rho ^{2}+r^{2}-|PO|^{2}}{2\rho r}}={\frac {\rho ^{2}-\Pi (P)}{2\rho r}}

( $PS_{1}$ and $OS_{1}$ are normals to the circle tangents.)

If $P$ lies inside the blue circle, then $\Pi (P)<0$ and $\varphi$ is always different from $90^{\circ }$ .

If the angle $\varphi$ is given, then one gets the radius $\rho$ by solving the quadratic equation

\rho ^{2}-2\rho r\cos \varphi -\Pi (P)=0

.

Intersecting secants theorem, intersecting chords theorem

Secant-, chord-theorem Potenz-sek-sehne-e.svg — Secant-, chord-theorem

For the intersecting secants theorem and chord theorem the power of a point plays the role of an invariant:

Intersecting secants theorem: For a point $P$ outside a circle $c$ and the intersection points $S_{1},S_{2}$ of a secant line $g$ with $c$ the following statement is true: $|PS_{1}|\cdot |PS_{2}|=\Pi (P)$ , hence the product is independent of line $g$ . If $g$ is tangent then $S_{1}=S_{2}$ and the statement is the tangent-secant theorem .
Intersecting chords theorem : For a point $P$ inside a circle $c$ and the intersection points $S_{1},S_{2}$ of a secant line $g$ with $c$ the following statement is true: $|PS_{1}|\cdot |PS_{2}|=-\Pi (P)$ , hence the product is independent of line $g$ .

Radical axis

Let $P$ be a point and $c_{1},c_{2}$ two non concentric circles with centers $O_{1},O_{2}$ and radii $r_{1},r_{2}$ . Point $P$ has the power $\Pi _{i}(P)$ with respect to circle $c_{i}$ . The set of all points $P$ with $\Pi _{1}(P)=\Pi _{2}(P)$ is a line called radical axis . It contains possible common points of the circles and is perpendicular to line ${\overline {O_{1}O_{2}}}$ .

Secants theorem, chords theorem: common proof

Secant-/chord-theorem: proof Potenz-sek-sehne-beweis-e.svg — Secant-/chord-theorem: proof

Both theorems, including the tangent-secant theorem, can be proven uniformly:

Let $P:{\vec {p}}$ be a point, $c:{\vec {x}}^{2}-r^{2}=0$ a circle with the origin as its center and ${\vec {v}}$ an arbitrary unit vector. The parameters $t_{1},t_{2}$ of possible common points of line $g:{\vec {x}}={\vec {p}}+t{\vec {v}}$ (through $P$ ) and circle $c$ can be determined by inserting the parametric equation into the circle's equation:

({\vec {p}}+t{\vec {v}})^{2}-r^{2}=0\quad \rightarrow \quad t^{2}+2t\;{\vec {p}}\cdot {\vec {v}}+{\vec {p}}^{2}-r^{2}=0\ .

From Vieta's theorem one finds:

t_{1}\cdot t_{2}={\vec {p}}^{2}-r^{2}=\Pi (P)

. (independent of

{\vec {v}}

!)

$\Pi (P)$ is the power of $P$ with respect to circle $c$ .

Because of $|{\vec {v}}|=1$ one gets the following statement for the points $S_{1},S_{2}$ :

|PS_{1}|\cdot |PS_{2}|=t_{1}t_{2}=\Pi (P)\

, if

P

is outside the circle,

|PS_{1}|\cdot |PS_{2}|=-t_{1}t_{2}=-\Pi (P)\

, if

P

is inside the circle (

t_{1},t_{2}

have different signs !).

In case of $t_{1}=t_{2}$ line $g$ is a tangent and $\Pi (P)$ the square of the tangential distance of point $P$ to circle $c$ .

Similarity points, common power of two circles

Similarity points

Similarity points are an essential tool for Steiner's investigations on circles.^[5]

Given two circles

\ c_{1}:({\vec {x}}-{\vec {m}}_{1})-r_{1}^{2}=0,\quad c_{2}:({\vec {x}}-{\vec {m}}_{2})-r_{2}^{2}=0\ .

A homothety (similarity) $\sigma$ , that maps $c_{1}$ onto $c_{2}$ stretches (jolts) radius $r_{1}$ to $r_{2}$ and has its center $Z:{\vec {z}}$ on the line ${\overline {M_{1}M_{2}}}$ , because $\sigma (M_{1})=M_{2}$ . If center $Z$ is between $M_{1},M_{2}$ the scale factor is $s=-{\tfrac {r_{2}}{r_{1}}}$ . In the other case $s={\tfrac {r_{2}}{r_{1}}}$ . In any case:

\sigma ({\vec {m}}_{1})={\vec {z}}+s({\vec {m}}_{1}-{\vec {z}})={\vec {m}}_{2}

.

Inserting $s=\pm {\tfrac {r_{2}}{r_{1}}}$ and solving for ${\vec {z}}$ yields:

{\vec {z}}={\frac {r_{1}{\vec {m}}_{2}\mp r_{2}{\vec {m}}_{1}}{r_{1}\mp r_{2}}}

.

Point

E:{\vec {e}}={\frac {r_{1}{\vec {m}}_{2}-r_{2}{\vec {m}}_{1}}{r_{1}-r_{2}}}

is called the exterior similarity point and

I:{\vec {i}}={\frac {r_{1}{\vec {m}}_{2}+r_{2}{\vec {m}}_{1}}{r_{1}+r_{2}}}

is called the inner similarity point.

In case of $M_{1}=M_{2}$ one gets $E=I=M_{i}$ .
In case of $r_{1}=r_{2}$ : $E$ is the point at infinity of line ${\overline {M_{1}M_{2}}}$ and $I$ is the center of $M_{1},M_{2}$ .
In case of $r_{1}=|EM_{1}|$ the circles touch each other at point $E$ inside (both circles on the same side of the common tangent line).
In case of $r_{1}=|IM_{1}|$ the circles touch each other at point $I$ outside (both circles on different sides of the common tangent line).

Further more:

If the circles lie disjoint (the discs have no points in common), the outside common tangents meet at $E$ and the inner ones at $I$ .
If one circle is contained within the other, the points $E,I$ lie within both circles.
The pairs $M_{1},M_{2};E,I$ are projective harmonic conjugate: Their cross ratio is $(M_{1},M_{2};E,I)=-1$ .

Monge's theorem states: The outer similarity points of three disjoint circles lie on a line.

Common power of two circles

Similarity points of two circles and their common power Kreis-2-aehnlpunkte.svg — Similarity points of two circles and their common power

Let $c_{1},c_{2}$ be two circles, $E$ their outer similarity point and $g$ a line through $E$ , which meets the two circles at four points $G_{1},H_{1},G_{2},H_{2}$ . From the defining property of point $E$ one gets

{\frac {|EG_{1}|}{|EG_{2}|}}={\frac {r_{1}}{r_{2}}}={\frac {|EH_{1}|}{|EH_{2}|}}\

\rightarrow \ |EG_{1}|\cdot |EH_{2}|=|EH_{1}|\cdot |EG_{2}|\

and from the secant theorem (see above) the two equations

|EG_{1}|\cdot |EH_{1}|=\Pi _{1}(E),\quad |EG_{2}|\cdot |EH_{2}|=\Pi _{2}(E).

Combining these three equations yields:

{\begin{aligned}\Pi _{1}(E)\cdot \Pi _{2}(E)&=|EG_{1}|\cdot |EH_{1}|\cdot |EG_{2}|\cdot |EH_{2}|\\&=|EG_{1}|^{2}\cdot |EH_{2}|^{2}=|EG_{2}|^{2}\cdot |EH_{1}|^{2}\ .\end{aligned}}

Hence:

|EG_{1}|\cdot |EH_{2}|=|EG_{2}|\cdot |EH_{1}|={\sqrt {\Pi _{1}(E)\cdot \Pi _{2}(E)}}

(independent of line $g$ !).

The analog statement for the inner similarity point $I$ is true, too.

The invariants ${\textstyle {\sqrt {\Pi _{1}(E)\cdot \Pi _{2}(E)}},\ {\sqrt {\Pi _{1}(I)\cdot \Pi _{2}(I)}}}$ are called by Steiner common power of the two circles (gemeinschaftliche Potenz der beiden Kreise bezüglich ihrer Ähnlichkeitspunkte).^[6]

The pairs $G_{1},H_{2}$ and $H_{1},G_{2}$ of points are antihomologous points. The pairs $G_{1},G_{2}$ and $H_{1},H_{2}$ are homologous.^[7]^[8]

Determination of a circle that is tangent to two circles

Common power of two circles: application Kreise2-ap-2sek.svg — Common power of two circles: application

Circles tangent to two circles Kreise2-ap-beruehrk.svg — Circles tangent to two circles

For a second secant through $E$ :

|EH_{1}|\cdot |EG_{2}|=|EH'_{1}|\cdot |EG'_{2}|

From the secant theorem one gets:

The four points

H_{1},G_{2},H'_{1},G'_{2}

lie on a circle.

And analogously:

The four points

G_{1},H_{2},G'_{1},H'_{2}

lie on a circle, too.

Because the radical lines of three circles meet at the radical (see: article radical line), one gets:

The secants

{\overline {H_{1}H'_{1}}},\;{\overline {G_{2}G'_{2}}}

meet on the radical axis of the given two circles.

Moving the lower secant (see diagram) towards the upper one, the red circle becomes a circle, that is tangent to both given circles. The center of the tangent circle is the intercept of the lines ${\overline {M_{1}H_{1}}},{\overline {M_{2}G_{2}}}$ . The secants ${\overline {H_{1}H'_{1}}},{\overline {G_{2}G'_{2}}}$ become tangents at the points $H_{1},G_{2}$ . The tangents intercept at the radical line $p$ (in the diagram yellow).

Similar considerations generate the second tangent circle, that meets the given circles at the points $G_{1},H_{2}$ (see diagram).

All tangent circles to the given circles can be found by varying line $g$ .

Positions of the centers

Circles tangent to two circles Kreise2-ap-beruehrkreise-n.svg — Circles tangent to two circles

If $X$ is the center and $\rho$ the radius of the circle, that is tangent to the given circles at the points $H_{1},G_{2}$ , then:

\rho =|XM_{1}|-r_{1}=|XM_{2}|-r_{2}

\rightarrow \ |XM_{2}|-|XM_{1}|=r_{2}-r_{1}.

Hence: the centers lie on a hyperbola with

foci

M_{1},M_{2}

,

distance of the vertices^{[ clarification needed ]}

2a=r_{2}-r_{1}

,

center

M

is the center of

M_{1},M_{2}

,

linear eccentricity

c={\tfrac {|M_{1}M_{2}|}{2}}

and

\ b^{2}=e^{2}-a^{2}={\tfrac {|M_{1}M_{2}|^{2}-(r_{2}-r_{1})^{2}}{4}}

^{[ clarification needed ]}.

Considerations on the outside tangent circles lead to the analog result:

If $X$ is the center and $\rho$ the radius of the circle, that is tangent to the given circles at the points $G_{1},H_{2}$ , then:

\rho =|XM_{1}|+r_{1}=|XM_{2}|+r_{2}

\rightarrow \ |XM_{2}|-|XM_{1}|=-(r_{2}-r_{1}).

The centers lie on the same hyperbola, but on the right branch.

Power with respect to a sphere

The idea of the power of a point with respect to a circle can be extended to a sphere .^[9] The secants and chords theorems are true for a sphere, too, and can be proven literally as in the circle case.

Darboux product

The power of a point is a special case of the Darboux product between two circles, which is given by^[10]

\left|A_{1}A_{2}\right|^{2}-r_{1}^{2}-r_{2}^{2}\,

where A₁ and A₂ are the centers of the two circles and r₁ and r₂ are their radii. The power of a point arises in the special case that one of the radii is zero.

If the two circles are orthogonal, the Darboux product vanishes.

If the two circles intersect, then their Darboux product is

2r_{1}r_{2}\cos \varphi \,

where φ is the angle of intersection (see section orthogonal circle).

Laguerre's theorem

Laguerre defined the power of a point P with respect to an algebraic curve of degree n to be the product of the distances from the point to the intersections of a circle through the point with the curve, divided by the nth power of the diameter d. Laguerre showed that this number is independent of the diameter ( Laguerre 1905 ). In the case when the algebraic curve is a circle this is not quite the same as the power of a point with respect to a circle defined in the rest of this article, but differs from it by a factor of d².

Related Research Articles

<span class="mw-page-title-main">Ellipse</span> Plane curve: conic section

In mathematics, an ellipse is a plane curve surrounding two focal points, such that for all points on the curve, the sum of the two distances to the focal points is a constant. It generalizes a circle, which is the special type of ellipse in which the two focal points are the same. The elongation of an ellipse is measured by its eccentricity $, a number ranging from to .$

In mathematics, a parabola is a plane curve which is mirror-symmetrical and is approximately U-shaped. It fits several superficially different mathematical descriptions, which can all be proved to define exactly the same curves.

The Method of Mechanical Theorems, also referred to as The Method, is one of the major surviving works of the ancient Greek polymath Archimedes. The Method takes the form of a letter from Archimedes to Eratosthenes, the chief librarian at the Library of Alexandria, and contains the first attested explicit use of indivisibles. The work was originally thought to be lost, but in 1906 was rediscovered in the celebrated Archimedes Palimpsest. The palimpsest includes Archimedes' account of the "mechanical method", so called because it relies on the center of weights of figures (centroid) and the law of the lever, which were demonstrated by Archimedes in On the Equilibrium of Planes.

In mathematics, the Peter–Weyl theorem is a basic result in the theory of harmonic analysis, applying to topological groups that are compact, but are not necessarily abelian. It was initially proved by Hermann Weyl, with his student Fritz Peter, in the setting of a compact topological group G. The theorem is a collection of results generalizing the significant facts about the decomposition of the regular representation of any finite group, as discovered by Ferdinand Georg Frobenius and Issai Schur.

In mathematics, a Lie algebroid is a vector bundle $together with a Lie bracket on its space of sections and a vector bundle morphism, satisfying a Leibniz rule. A Lie algebroid can thus be thought of as a "many-object generalisation" of a Lie algebra.$

Electrostatics is a branch of physics that studies slow-moving or stationary electric charges.

<span class="mw-page-title-main">Cardioid</span> Type of plane curve

In geometry, a cardioid is a plane curve traced by a point on the perimeter of a circle that is rolling around a fixed circle of the same radius. It can also be defined as an epicycloid having a single cusp. It is also a type of sinusoidal spiral, and an inverse curve of the parabola with the focus as the center of inversion. A cardioid can also be defined as the set of points of reflections of a fixed point on a circle through all tangents to the circle.

In quantum mechanics and computing, the Bloch sphere is a geometrical representation of the pure state space of a two-level quantum mechanical system (qubit), named after the physicist Felix Bloch.

<span class="mw-page-title-main">Evolute</span> Centers of curvature of a curve

In the differential geometry of curves, the evolute of a curve is the locus of all its centers of curvature. That is to say that when the center of curvature of each point on a curve is drawn, the resultant shape will be the evolute of that curve. The evolute of a circle is therefore a single point at its center. Equivalently, an evolute is the envelope of the normals to a curve.

<span class="mw-page-title-main">Nephroid</span> Plane curve; an epicycloid with radii differing by 1/2

In geometry, a nephroid is a specific plane curve. It is a type of epicycloid in which the smaller circle's radius differs from the larger one by a factor of one-half.

The representation theory of groups is a part of mathematics which examines how groups act on given structures.

A first class constraint is a dynamical quantity in a constrained Hamiltonian system whose Poisson bracket with all the other constraints vanishes on the constraint surface in phase space. To calculate the first class constraint, one assumes that there are no second class constraints, or that they have been calculated previously, and their Dirac brackets generated.

In geometry, the area enclosed by a circle of radius $r$ is $π r 2$ . Here the Greek letter $π$ represents the constant ratio of the circumference of any circle to its diameter, approximately equal to 3.14159.

<span class="mw-page-title-main">Radical axis</span> All points whose relative distances to two circles are same

In Euclidean geometry, the radical axis of two non-concentric circles is the set of points whose power with respect to the circles are equal. For this reason the radical axis is also called the power line or power bisector of the two circles. In detail:

<span class="mw-page-title-main">Multiple integral</span> Generalization of definite integrals to functions of multiple variables

In mathematics (specifically multivariable calculus), a multiple integral is a definite integral of a function of several real variables, for instance, $f (x, y)$ or $f (x, y, z)$ . Physical (natural philosophy) interpretation: S any surface, V any volume, etc.. Incl. variable to time, position, etc.

The lattice Boltzmann methods (LBM), originated from the lattice gas automata (LGA) method (Hardy-Pomeau-Pazzis and Frisch-Hasslacher-Pomeau models), is a class of computational fluid dynamics (CFD) methods for fluid simulation. Instead of solving the Navier–Stokes equations directly, a fluid density on a lattice is simulated with streaming and collision (relaxation) processes. The method is versatile as the model fluid can straightforwardly be made to mimic common fluid behaviour like vapour/liquid coexistence, and so fluid systems such as liquid droplets can be simulated. Also, fluids in complex environments such as porous media can be straightforwardly simulated, whereas with complex boundaries other CFD methods can be hard to work with.

In physics, Gauss's law for gravity, also known as Gauss's flux theorem for gravity, is a law of physics that is equivalent to Newton's law of universal gravitation. It is named after Carl Friedrich Gauss. It states that the flux of the gravitational field over any closed surface is proportional to the mass enclosed. Gauss's law for gravity is often more convenient to work from than Newton's law.

In geometry, the Steiner inellipse, midpoint inellipse, or midpoint ellipse of a triangle is the unique ellipse inscribed in the triangle and tangent to the sides at their midpoints. It is an example of an inellipse. By comparison the inscribed circle and Mandart inellipse of a triangle are other inconics that are tangent to the sides, but not at the midpoints unless the triangle is equilateral. The Steiner inellipse is attributed by Dörrie to Jakob Steiner, and a proof of its uniqueness is given by Dan Kalman.

In mathematics, a Coulomb wave function is a solution of the Coulomb wave equation, named after Charles-Augustin de Coulomb. They are used to describe the behavior of charged particles in a Coulomb potential and can be written in terms of confluent hypergeometric functions or Whittaker functions of imaginary argument.

Lagrangian field theory is a formalism in classical field theory. It is the field-theoretic analogue of Lagrangian mechanics. Lagrangian mechanics is used to analyze the motion of a system of discrete particles each with a finite number of degrees of freedom. Lagrangian field theory applies to continua and fields, which have an infinite number of degrees of freedom.

References

↑ Jakob Steiner: Einige geometrische Betrachtungen, 1826, S. 164
↑ Steiner, p. 163
↑ Steiner, p. 178
↑ Steiner, p. 182
↑ Steiner: p. 170,171
↑ Steiner: p. 175
↑ Michel Chasles, C. H. Schnuse: Die Grundlehren der neuern Geometrie, erster Theil, Verlag Leibrock, Braunschweig, 1856, p. 312
↑ William J. M'Clelland: A Treatise on the Geometry of the Circle and Some Extensions to Conic Sections by the Method of Reciprocation,1891, Verlag: Creative Media Partners, LLC, ISBN 978-0-344-90374-8, p. 121,220
↑ K.P. Grothemeyer: Analytische Geometrie, Sammlung Göschen 65/65A, Berlin 1962, S. 54
↑ Pierre Larochelle, J. Michael McCarthy:Proceedings of the 2020 USCToMM Symposium on Mechanical Systems and Robotics, 2020, Springer-Verlag, ISBN 978-3-030-43929-3, p. 97

Coxeter, H. S. M. (1969), Introduction to Geometry (2nd ed.), New York: Wiley.
Darboux, Gaston (1872), "Sur les relations entre les groupes de points, de cercles et de sphéres dans le plan et dans l'espace", Annales Scientifiques de l'École Normale Supérieure, 1: 323–392, doi: 10.24033/asens.87 .
Laguerre, Edmond (1905), Oeuvres de Laguerre: Géométrie (in French), Gauthier-Villars et fils, p. 20
Steiner, Jakob (1826). "Einige geometrischen Betrachtungen" [Some geometric considerations]. Crelle's Journal (in German). 1: 161–184. doi:10.1515/crll.1826.1.161. S2CID 122065577. Figures 8–26.
Berger, Marcel (1987), Geometry I, Springer, ISBN 978-3-540-11658-5

External links

Jacob Steiner and the Power of a Point at Convergence
Weisstein, Eric W. "Circle Power". MathWorld .
Intersecting Chords Theorem at cut-the-knot
Intersecting Chords Theorem With interactive animation
Intersecting Secants Theorem With interactive animation

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[1] Jakob Steiner: Einige geometrische Betrachtungen, 1826, S. 164

[2] Steiner, p. 163

[3] Steiner, p. 178

[4] Steiner, p. 182

[5] Steiner: p. 170,171

[6] Steiner: p. 175

[7] Michel Chasles, C. H. Schnuse: Die Grundlehren der neuern Geometrie, erster Theil, Verlag Leibrock, Braunschweig, 1856, p. 312

[8] William J. M'Clelland: A Treatise on the Geometry of the Circle and Some Extensions to Conic Sections by the Method of Reciprocation,1891, Verlag: Creative Media Partners, LLC, ISBN 978-0-344-90374-8, p. 121,220

[9] K.P. Grothemeyer: Analytische Geometrie, Sammlung Göschen 65/65A, Berlin 1962, S. 54

[10] Pierre Larochelle, J. Michael McCarthy:Proceedings of the 2020 USCToMM Symposium on Mechanical Systems and Robotics, 2020, Springer-Verlag, ISBN 978-3-030-43929-3, p. 97

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]