Collinearities and concurrencies

Trilinear coordinates enable many algebraic methods in triangle geometry. For example, three points

${\displaystyle {\begin{aligned}P&=p:q:r\\U&=u:v:w\\X&=x:y:z\\\end{aligned}}}$

are collinear if and only if the determinant

${\displaystyle D={\begin{vmatrix}p&q&r\\u&v&w\\x&y&z\end{vmatrix}}}$

equals zero. Thus if x : y : z is a variable point, the equation of a line through the points P and U is D = 0.^{[1]: p. 23} From this, every straight line has a linear equation homogeneous in x, y, z. Every equation of the form ${\displaystyle lx+my+nz=0}$ in real coefficients is a real straight line of finite points unless l : m : n is proportional to a : b : c, the side lengths, in which case we have the locus of points at infinity.^{[1]: p. 40}

The dual of this proposition is that the lines

${\displaystyle {\begin{aligned}p\alpha +q\beta +r\gamma &=0\\u\alpha +v\beta +w\gamma &=0\\x\alpha +y\beta +z\gamma &=0\end{aligned}}}$

concur in a point (α, β, γ) if and only if D = 0.^{[1]: p. 28}

Also, if the actual directed distances are used when evaluating the determinant of D, then the area of triangle △PUX is KD, where ${\displaystyle K={\tfrac {-abc}{8\Delta ^{2}}}}$ (and where Δ is the area of triangle △ABC, as above) if triangle △PUX has the same orientation (clockwise or counterclockwise) as △ABC, and ${\displaystyle K={\tfrac {-abc}{8\Delta ^{2}}}}$ otherwise.

Parallel lines

Two lines with trilinear equations ${\displaystyle lx+my+nz=0}$ and ${\displaystyle l'x+m'y+n'z=0}$ are parallel if and only if^{[1]: p. 98, #xi}

${\displaystyle {\begin{vmatrix}l&m&n\\l'&m'&n'\\a&b&c\end{vmatrix}}=0,}$

where a, b, c are the side lengths.

Angle between two lines

The tangents of the angles between two lines with trilinear equations ${\displaystyle lx+my+nz=0}$ and ${\displaystyle l'x+m'y+n'z=0}$ are given by^[1]: p.50

${\displaystyle \pm {\frac {(mn'-m'n)\sin A+(nl'-n'l)\sin B+(lm'-l'm)\sin C}{ll'+mm'+nn'-(mn'+m'n)\cos A-(nl'+n'l)\cos B-(lm'+l'm)\cos C}}.}$

Altitude

The equation of the altitude from vertex A to side BC is^{[1]: p.98, #x}

${\displaystyle y\cos B-z\cos C=0.}$

Line in terms of distances from vertices

The equation of a line with variable distances p, q, r from the vertices A, B, C whose opposite sides are a, b, c is^{[1]: p. 97, #viii}

${\displaystyle apx+bqy+crz=0.}$

Actual-distance trilinear coordinates

The trilinears with the coordinate values a', b', c' being the actual perpendicular distances to the sides satisfy^{[1]: p. 11}

${\displaystyle aa'+bb'+cc'=2\Delta }$

for triangle sides a, b, c and area Δ. This can be seen in the figure at the top of this article, with interior point P partitioning triangle △ABC into three triangles △PBC, △PCA, △PAB with respective areas ${\displaystyle {\tfrac {1}{2}}aa',{\tfrac {1}{2}}bb',{\tfrac {1}{2}}cc'.}$

Distance between two points

The distance d between two points with actual-distance trilinears a_i : b_i : c_i is given by^{[1]: p. 46}

${\displaystyle d^{2}\sin ^{2}C=(a_{1}-a_{2})^{2}+(b_{1}-b_{2})^{2}+2(a_{1}-a_{2})(b_{1}-b_{2})\cos C}$

or in a more symmetric way

${\displaystyle d^{2}={\frac {abc}{4\Delta ^{2}}}\left(a(b_{1}-b_{2})(c_{2}-c_{1})+b(c_{1}-c_{2})(a_{2}-a_{1})+c(a_{1}-a_{2})(b_{2}-b_{1})\right).}$

Distance from a point to a line

The distance d from a point a' : b' : c' , in trilinear coordinates of actual distances, to a straight line ${\displaystyle lx+my+nz=0}$ is^{[1]: p. 48}

${\displaystyle d={\frac {la'+mb'+nc'}{\sqrt {l^{2}+m^{2}+n^{2}-2mn\cos A-2nl\cos B-2lm\cos C}}}.}$

Quadratic curves

The equation of a conic section in the variable trilinear point x : y : z is^[1]: p.118

${\displaystyle rx^{2}+sy^{2}+tz^{2}+2uyz+2vzx+2wxy=0.}$

It has no linear terms and no constant term.

The equation of a circle of radius r having center at actual-distance coordinates (a', b', c' ) is^[1]: p.287

${\displaystyle (x-a')^{2}\sin 2A+(y-b')^{2}\sin 2B+(z-c')^{2}\sin 2C=2r^{2}\sin A\sin B\sin C.}$

Cubic curves

Many cubic curves are easily represented using trilinear coordinates. For example, the pivotal self-isoconjugate cubic Z(U, P), as the locus of a point X such that the P-isoconjugate of X is on the line UX is given by the determinant equation

${\displaystyle {\begin{vmatrix}x&y&z\\qryz&rpzx&pqxy\\u&v&w\end{vmatrix}}=0.}$

Among named cubics Z(U, P) are the following:

Thomson cubic: Z(X(2),X(1)), where X(2) = centroid, X(1) = incenter

Feuerbach cubic: Z(X(5),X(1)), where X(5) = Feuerbach point

Darboux cubic: Z(X(20),X(1)), where X(20) = De Longchamps point

Neuberg cubic: Z(X(30),X(1)), where X(30) = Euler infinity point.

Between trilinear coordinates and distances from sidelines

For any choice of trilinear coordinates x : y : z to locate a point, the actual distances of the point from the sidelines are given by a' = kx, b' = ky, c' = kz where k can be determined by the formula ${\displaystyle k={\tfrac {2\Delta }{ax+by+cz}}}$ in which a, b, c are the respective sidelengths BC, CA, AB, and ∆ is the area of △ABC.

Between barycentric and trilinear coordinates

A point with trilinear coordinates x : y : z has barycentric coordinates ax : by : cz where a, b, c are the sidelengths of the triangle. Conversely, a point with barycentrics α : β : γ has trilinear coordinates ${\displaystyle {\tfrac {\alpha }{a}}:{\tfrac {\beta }{b}}:{\tfrac {\gamma }{c}}.}$

Between Cartesian and trilinear coordinates

Given a reference triangle △ABC, express the position of the vertex B in terms of an ordered pair of Cartesian coordinates and represent this algebraically as a vector ${\displaystyle {\vec {B}},}$ using vertex C as the origin. Similarly define the position vector of vertex A as ${\displaystyle {\vec {A}}.}$ Then any point P associated with the reference triangle △ABC can be defined in a Cartesian system as a vector ${\displaystyle {\vec {P}}=k_{1}{\vec {A}}+k_{2}{\vec {B}}.}$ If this point P has trilinear coordinates x : y : z then the conversion formula from the coefficients k₁ and k₂ in the Cartesian representation to the trilinear coordinates is, for side lengths a, b, c opposite vertices A, B, C,

${\displaystyle x:y:z={\frac {k_{1}}{a}}:{\frac {k_{2}}{b}}:{\frac {1-k_{1}-k_{2}}{c}},}$

and the conversion formula from the trilinear coordinates to the coefficients in the Cartesian representation is

${\displaystyle k_{1}={\frac {ax}{ax+by+cz}},\quad k_{2}={\frac {by}{ax+by+cz}}.}$

More generally, if an arbitrary origin is chosen where the Cartesian coordinates of the vertices are known and represented by the vectors ${\displaystyle {\vec {A}},{\vec {B}},{\vec {C}}}$ and if the point P has trilinear coordinates x : y : z, then the Cartesian coordinates of ${\displaystyle {\vec {P}}}$ are the weighted average of the Cartesian coordinates of these vertices using the barycentric coordinates ax, by, cz as the weights. Hence the conversion formula from the trilinear coordinates x, y, z to the vector of Cartesian coordinates ${\displaystyle {\vec {P}}}$ of the point is given by

${\displaystyle {\vec {P}}={\frac {ax}{ax+by+cz}}{\vec {A}}+{\frac {by}{ax+by+cz}}{\vec {B}}+{\frac {cz}{ax+by+cz}}{\vec {C}},}$

where the side lengths are

${\displaystyle {\begin{aligned}&|{\vec {C}}-{\vec {B}}|=a,\\&|{\vec {A}}-{\vec {C}}|=b,\\&|{\vec {B}}-{\vec {A}}|=c.\end{aligned}}}$