Spherical law of cosines

In spherical trigonometry, the law of cosines (also called the cosine rule for sides^[1]) is a theorem relating the sides and angles of spherical triangles, analogous to the ordinary law of cosines from plane trigonometry.

Given a unit sphere, a "spherical triangle" on the surface of the sphere is defined by the great circles connecting three points u, v, and w on the sphere (shown at right). If the lengths of these three sides are a (from u to v), b (from u to w), and c (from v to w), and the angle of the corner opposite c is C, then the (first) spherical law of cosines states:^[2][1]

$${\displaystyle \cos c=\cos a\cos b+\sin a\sin b\cos C\,}$$

Since this is a unit sphere, the lengths a, b, and c are simply equal to the angles (in radians) subtended by those sides from the center of the sphere. (For a non-unit sphere, the lengths are the subtended angles times the radius, and the formula still holds if a, b and c are reinterpreted as the subtended angles). As a special case, for C = ⁠π/2⁠, then cos C = 0, and one obtains the spherical analogue of the Pythagorean theorem:

$${\displaystyle \cos c=\cos a\cos b\,}$$

If the law of cosines is used to solve for c, the necessity of inverting the cosine magnifies rounding errors when c is small. In this case, the alternative formulation of the law of haversines is preferable.^[3]

A variation on the law of cosines, the second spherical law of cosines,^[4] (also called the cosine rule for angles^[1]) states:

$${\displaystyle \cos C=-\cos A\cos B+\sin A\sin B\cos c\,}$$

where A and B are the angles of the corners opposite to sides a and b, respectively. It can be obtained from consideration of a spherical triangle dual to the given one.

Let u, v, and w denote the unit vectors from the center of the sphere to those corners of the triangle. The angles and distances do not change if the coordinate system is rotated, so we can rotate the coordinate system so that ${\displaystyle \mathbf {u} }$ is at the north pole and ${\displaystyle \mathbf {v} }$ is somewhere on the prime meridian (longitude of 0). With this rotation, the spherical coordinates for ${\displaystyle \mathbf {v} }$ are ${\displaystyle (r,\theta ,\phi )=(1,a,0),}$ where θ is the angle measured from the north pole not from the equator, and the spherical coordinates for ${\displaystyle \mathbf {w} }$ are ${\displaystyle (r,\theta ,\phi )=(1,b,C).}$ The Cartesian coordinates for ${\displaystyle \mathbf {v} }$ are ${\displaystyle (x,y,z)=(\sin a,0,\cos a)}$ and the Cartesian coordinates for ${\displaystyle \mathbf {w} }$ are ${\displaystyle (x,y,z)=(\sin b\cos C,\sin b\sin C,\cos b).}$ The value of ${\displaystyle \cos c}$ is the dot product of the two Cartesian vectors, which is ${\displaystyle \sin a\sin b\cos C+\cos a\cos b.}$

Let u, v, and w denote the unit vectors from the center of the sphere to those corners of the triangle. We have u · u = 1, v · w = cos c, u · v = cos a, and u · w = cos b. The vectors u × v and u × w have lengths sin a and sin b respectively and the angle between them is C, so $${\displaystyle {\begin{aligned}\sin a\sin b\cos C&=({\mathbf {u}}\times {\mathbf {v}})\cdot ({\mathbf {u}}\times {\mathbf {w}})\\&=({\mathbf {u}}\cdot {\mathbf {u}})({\mathbf {v}}\cdot {\mathbf {w}})-({\mathbf {u}}\cdot {\mathbf {w}})({\mathbf {v}}\cdot {\mathbf {u}})\\&=\cos c-\cos a\cos b\end{aligned}}}$$

using cross products, dot products, and the Binet–Cauchy identity $${\displaystyle ({\mathbf {p}}\times {\mathbf {q}})\cdot ({\mathbf {r}}\times {\mathbf {s}})=({\mathbf {p}}\cdot {\mathbf {r}})({\mathbf {q}}\cdot {\mathbf {s}})-({\mathbf {p}}\cdot {\mathbf {s}})({\mathbf {q}}\cdot {\mathbf {r}}).}$$

The following proof relies on the concept of quaternions and is based on a proof given in Brand:^[5] Let u, v, and w denote the unit vectors from the center of the unit sphere to those corners of the triangle. We define the quaternion u = (0, u) = 0 + u_xi + u_yj + u_zk. The quaternion u is used to represent a rotation by 180° around the axis indicated by the vector u. We note that using −u as the axis of rotation gives the same result, and that the rotation is its own inverse. We also define v = (0, v) and w = (0, w).

We compute the product of quaternions, which also gives the composition of the corresponding rotations:

q = vu⁻¹ = (v)(−u) = (−(v · −u), v × −u) = (u · v, u × v) = (cos a, w′ sin a)

where (f, g) represents the real and imaginary parts of a quaternion, a is the angle between u and v, and w′ = (u × v) / |u × v| is the axis of the rotation that moves u to v along a great circle. Similarly we define:

r = wv⁻¹ = (v · w, v × w) = (cos b, u′ sin b).

s = uw⁻¹ = (w · u, w × u) = (cos c, v′ sin c)

The quaternions q, r, and s are used to represent rotations with axes of rotation w′, u′, and v′, respectively, and angles of rotation 2a, 2b, and 2c, respectively. Because these are double angles, each of q, r, and s represents two applications of the rotation implied by an edge of the spherical triangle.

From the definitions, it follows that

srq = uw⁻¹wv⁻¹vu⁻¹ = 1,

which tells us that the composition of these rotations is the identity transformation. In particular, rq = s⁻¹ gives us

(cos b, u′ sin b) (cos a, w′ sin a) = (cos c, −v′ sin c).

Expanding the left-hand side, we obtain

${\displaystyle (\cos a\cos b-{\mathbf {u}}'\cdot {\mathbf {w}}'\sin a\sin b,{\mathbf {u}}'\cos a\sin b+{\mathbf {w}}'\sin a\cos b+{\mathbf {u}}'\times {\mathbf {w}}'\sin a\sin b).}$

Equating the scalar parts on both sides of the identity, we obtain

${\displaystyle \cos a\cos b-{\mathbf {u}}'\cdot {\mathbf {w}}'\sin a\sin b=\cos c.}$

Because u′ is parallel to v × w, w′ is parallel to u × v = −v × u, and C is the angle between v × w and v × u, it follows that ${\displaystyle {\mathbf {u}}'\cdot {\mathbf {w}}'=-\cos C}$. Thus,

${\displaystyle \cos a\cos b+\cos C\sin a\sin b=\cos c.}$

The first and second spherical laws of cosines can be rearranged to put the sides (a, b, c) and angles (A, B, C) on opposite sides of the equations: $${\displaystyle {\begin{aligned}\cos C&={\frac {\cos c-\cos a\cos b}{\sin a\sin b}}\\\cos c&={\frac {\cos C+\cos A\cos B}{\sin A\sin B}}\\\end{aligned}}}$$

For small spherical triangles, i.e. for small a, b, and c, the spherical law of cosines is approximately the same as the ordinary planar law of cosines, $${\displaystyle c^{2}\approx a^{2}+b^{2}-2ab\cos C\,.}$$

To prove this, we will use the small-angle approximation obtained from the Maclaurin series for the cosine and sine functions: $${\displaystyle {\begin{aligned}\cos a&=1-{\frac {a^{2}}{2}}+O\left(a^{4}\right)\\\sin a&=a+O\left(a^{3}\right)\end{aligned}}}$$

Substituting these expressions into the spherical law of cosines nets:

$${\displaystyle 1-{\frac {c^{2}}{2}}+O\left(c^{4}\right)=1-{\frac {a^{2}}{2}}-{\frac {b^{2}}{2}}+{\frac {a^{2}b^{2}}{4}}+O\left(a^{4}\right)+O\left(b^{4}\right)+\cos(C)\left(ab+O\left(a^{3}b\right)+O\left(ab^{3}\right)+O\left(a^{3}b^{3}\right)\right)}$$

or after simplifying:

$${\displaystyle c^{2}=a^{2}+b^{2}-2ab\cos C+O\left(c^{4}\right)+O\left(a^{4}\right)+O\left(b^{4}\right)+O\left(a^{2}b^{2}\right)+O\left(a^{3}b\right)+O\left(ab^{3}\right)+O\left(a^{3}b^{3}\right).}$$

The big O terms for a and b are dominated by O(a⁴) + O(b⁴) as a and b get small, so we can write this last expression as:

$${\displaystyle c^{2}=a^{2}+b^{2}-2ab\cos C+O\left(a^{4}\right)+O\left(b^{4}\right)+O\left(c^{4}\right).}$$

Something equivalent to the spherical law of cosines was used (but not stated in general) by al-Khwārizmī (9th century), al-Battānī (9th century), and Nīlakaṇṭha (15th century).^[6]

• Half-side formula
• Hyperbolic law of cosines
• Solution of triangles
• Spherical law of sines