If the closed plane curve is an inscribable N side polygon, it can be divided into N isosceles triangles, the solid angle of the straight pyramid having this polygon as its base is a sum of the N results of Equation (1), one for each triangle. The particular case of this situation is the regular N side polygon, creating a regular pyramid. As j is 2π divided by N, we get the pyramid solid angle by multiplying Equation (1) by N. The resulting formula, Equation (3), is conveniently written with a similar shape of the well-known cone case, unlike other publications [3].

Ω = 2 π { 1 − ( N / π ) arctan [ cos θ tan ( π / N ) ] } (3)

Equation (3) is useful to solve many geometric problems, as we see in item 5.

Some of these problems are classical ones that can be solved in a much simpler and quicker manner using Equation (3) and some are newly proposed ones.

is at a height z from the triangle plane. The lengths a, b, c and z are given and a is the side not containing the point P’. With b being the biggest between the two other sides, we build two isosceles triangles P’QR and P’ST. The segment e completes both central right triangles. This processes for determining solid angles of geometric figures are not exclusive of triangles,

The solid angle relative to the original triangle P’SQ is obviously given by:

Ω = ( Ω 1 − Ω 2 ) / 2

where Ω 1 and Ω 2 are the solid angles relative to the triangles P’ST and P’QR respectively.

With:

K = 4 ( a 2 b 2 + a 2 c 2 + b 2 c 2 ) − ( a 2 + b 2 + c 2 ) 2

We have:

tan 2 ( φ 1 / 2 ) = ( b 2 − c 2 + a 2 ) 2 / K

tan 2 ( φ 2 / 2 ) = ( b 2 − c 2 − a 2 ) 2 / K

With some manipulation and using Equation (1), we get for the solid angle:

Ω = arctan { ( b 2 − c 2 + a 2 ) / [ 4 ( a 2 b 2 + a 2 c 2 + b 2 c 2 ) − ( a 2 + b 2 + c 2 ) 2 ] } − arctan { z ( b 2 − c 2 + a 2 ) / { [ 4 ( a 2 b 2 + a 2 c 2 + b 2 c 2 ) − ( a 2 + b 2 + c 2 ) 2 ] ( b 2 + z 2 ) } } − arctan { ( b 2 − c 2 − a 2 ) / [ 4 ( a 2 b 2 + a 2 c 2 + b 2 c 2 ) − ( a 2 + b 2 + c 2 ) 2 ] } + arctan { z ( b 2 − c 2 − a 2 ) / { [ 4 ( a 2 b 2 + a 2 c 2 + b 2 c 2 ) − ( a 2 + b 2 + c 2 ) 2 ] ( c 2 + z 2 ) } } (4)

The expression above is rather complicated but is a real and exact solution of the proposed problem.

As a test of Equation (4), we make c = b , that means, the triangle is isosceles. We get Ω = φ − 2 arctan [ cos θ tan ( φ / 2 ) ] , that is the Equation (1), as expected.

If P’ is not on the vertex of the triangle, we can create three new triangles αβP’, βχP’ and αχP’ as in Figure 7 and solve the problem for these three general triangles as shown before in the present section. The sought solid angle Ω(αβχ) is given by:

Ω ( α β χ ) = Ω ( α β Ρ ′ ) + Ω ( β χ Ρ ′ ) − Ω ( α χ Ρ ′ )

This solution, although shown for the triangle case, it is perfectly valid for any polygon, as one can create a number of suitable triangles to calculate the solid angle.

Normally it is possible to create N triangles for the case of a general polygon with N sides. This leads to the solid angle for a general pyramid with a general polygonal base [4]. The process may be laborious due the number of involved triangles but leads to precise results. The next section just deals with the special case of rectangles, that are simpler to calculate as it involves only isosceles triangles that are well treated in Section 2.

Reference [5] shows another approach to the solid angle for a general triangle.

It is possible to solve this problem using Section 4.2 choosing the rectangle as the general polygon, but the following solution is simpler and immediate.

A rectangle is dividable into 4 isosceles triangles equal two by two with sides 2A and 2B. Then, if P’ is on the center of a rectangle, the problem of the solid angle for such a pyramid is solved by using Equation (1) two times, one for each type of triangle, summing their results and multiple by two. The result is shown by Equation (5) below:

Ω = 2 π − 4 arctan { z A / [ B ( A 2 + B 2 + z 2 ) 1 / 2 ] }     − 4 arctan { z B / [ A ( A 2 + B 2 + z 2 ) 1 / 2 ] } (5)

When P’ is not on the center, for example, the situation is that of Figure 8, where the rectangle is αβχε of sides 2.a and 2.b. To solve this case, we trace two central lines containing P’ and parallel to the rectangle sides and create three more rectangles, γδλη, ρσζψ and μνξκ, the central lines three mirror images of the first one. As we see in Figure 8, the problem now is reduced to calculate the solid angles of four rectangle with P’ common to all. These rectangles are: αδζκ, βγψξ, μεησ and χλρν, with the respective solid angles Ω(αδζκ), Ω(βγψξ), Ω(μεησ) and Ω(χλρν). The solid angle Ω of the original rectangle is given by Ω = [ Ω ( α δ ζ κ ) − Ω ( β γ ψ ξ ) − Ω ( μ ε η σ ) + Ω ( χ λ ρ ν ) ] / 4 (The last term is the compensation for the central rectangle χλρν that was accounted two times with the rectangles βγψξ and μεησ).

Ω = arctan { [ ( x + a ) 2 + ( y − b ) 2 + z 2 ] 1 / 2 z / [ ( x + a ) ( y − b ) ] }     + arctan { [ ( x − a ) 2 + ( y + b ) 2 + z 2 ] 1 / 2 z / [ ( x − a ) ( y + b ) ] }     − arctan { [ ( x + a ) 2 + ( y + b ) 2 + z 2 ] 1 / 2 z / [ ( x + a ) ( y + b ) ] }     − arctan { [ ( x − a ) 2 + ( y − b ) 2 + z 2 ] 1 / 2 z / [ ( x − a ) ( y − b ) ] } (6)

As before, the expression is complicated but exact. It is possible to condensate yet more Equation (6), but the result does not seem to be more convenient to use.

One test may be performed on Equation (6) by making x = a , y = b , that is, putting P’ on the vertex χ. Choosing a = b and z = 2 a , the point P will be seeing one quarter of the face of a cube and situated at its center, that is, Ω = π / 6 . Multiplying this by four, we get Ω = 2 π / 3 , the solid angle of the face of a cube (as multiplying this by six we get 4π).

Suppose we have an infinite long band with width p as in Figure 9(a). To get the solid angle the point P sees the infinite band, we draw an isosceles triangle as in Figure 9(b), keeping the distance p and getting the limit when L tends to infinity. Using Equation (1) and getting the limit for L, we have:

Ω = π − 2 arctan ( z / p ) (7)

Making z = 0 in Equation (5), we get Ω = π , in agreement with Equation (2), as expected.

If P is on the middle of a band of width p, we simply double the result of Equation (7), replacing p by p/2:

Ω = 2 π − 4 tg − 1 ( 2 z / p ) (8)

So, using Figure 10 and the Equation (7), we can obtain the solid angle for any point P outside an infinite band with width p. Now, we have two bands, one with width y − p / 2 and another with width y + p / 2 . The subtraction of the solid angles Ω₁ and Ω₂ given by Equation (7) corresponding to both bands gives us the solid angle that P sees the original band with width p:

Ω 1 = π − 2 arctan [ z / ( y + p / 2 ) ] and Ω 2 = π − 2 arctan [ z / ( y − p / 2 ) ]

Ω = Ω 1 − Ω 2 , therefore:

Ω = 2 { arctan [ z / ( y − p / 2 ) ] − arctan [ z / ( y + p / 2 ) ] } (9)

Equation (9) shows the solid angles seen by P in any point of the space but those on the band plane, where it is valid only for points with P’ is outside the band. If we make z = 0 on Equation (9), we get Ω = 0 .

The problem on the band plane is that Ω is discontinuous on it. To by-pass this problem, we use Figure 11 where we have two bands with width p / 2 − y and p / 2 + y . The solid angle Ω seen by P with P’ inside the band is the sum of the solid angle corresponding to the two bands. Using Equation (7) we get:

Ω 1 = π − 2 arctan [ z / ( p / 2 + y ) ] and Ω 2 = π − 2 arctan [ z / ( p / 2 − y ) ]

Ω = Ω 1 + Ω 2 , therefore:

Ω = 2 π − 2 { arctan [ z / ( y − p / 2 ) ] + arctan [ z / ( y + p / 2 ) ] } (10)

Equation (10) is valid for all points in the space but those on the band plane, where it is valid only for points with P’ is inside the band. If we make z = 0 on Equation (10) we get Ω = 2 π .

The solid angle seen by P when it is on the edge of the band depends on how P approaches the edge. Refer to Figure 12. For the general case, we consider P reaches the edge along the dotted line, that means, with constant φ. From the figure we may write y − p / 2 = x , y + p / 2 = x + p , z / x = tan φ and we can rewrite Equation (9) as:

Ω = 2 φ − 2 arctan [ x tan φ / ( p + x ) ] (11)

To obtain the solid angle Ω_φ with P reaching the edge under an angle φ, we calculate the limit of the Equation (11) when x tends to zero (keeping constant φ):

Ω φ = 2 φ (12)

This is independent of p (for p ≠ 0 ; if p = 0 , Ω = 0 ). So, suppose P goes to the edge of the band. When φ = 0 , that is, P’ originally off the band, then Ω φ = 0 , as expected; if φ = π and y < p , that is, P’ originally within the band, Ω φ = 2 π , also as expected; if φ = π / 2 , that is, P’ originally on the edge of the band, Ω φ = π , as expected for any smooth curve case. This dependence of Ω_φ on the arriving angle of P, in the case of P’ on the edge, is a very common fact to all curve shapes to be observed by P. This shows the not simple behavior of Ω_φ for this case, where the position of P is not enough to determine the solid angle (we need another parameter: the arriving angle).

Note that, in Figure 12, the movement of P to reach the edge is on the plane perpendicular to the band. This is not a lack of generality because the component of the movement parallel to the band does not alter the solid angle as the band length is infinite. We have indeed a cylindrical symmetry.

An Equi-Ω surface is one formed by observation points where the solid angle is the same. Those surfaces are got by fixing the value of Ω ( Ω = Ω 0 ). Normally it is hard to determine for the most of the curves because of mathematical difficulties that arise during the calculus.

One of the simple ones is that related to the infinite band case discussed in Section 4.4. We get the surface for this case making Ω = Ω 0 in Equation (9) and writing an expression relating the variables z and y. Equation (9) may be written as:

z 2 + y 2 − p z / tan ( Ω 0 / 2 ) − p 2 / 4 = 0 (13)

Equation (13) represents an arc of a circle with coordinates of the center y 0 = 0 , z 0 = p / [ 2 tan ( Ω 0 / 2 ) ] and radius R = p [ 1 + cot ( Ω 0 / 2 ) ] 1 / 2 / 2 . The overall curve, composed by those arcs of circle, is symmetrical regarding the plane of the band center straight line as in Figure 13. The curve is, indeed, the cross section of an infinite cylinder.

Let us choose two examples of such curves. The first one is the case when the solid angle Ω 0 = π and tan ( Ω 0 / 2 ) → ∞ . Equation (13) is written as:

z 2 + y 2 − p 2 / 4 = 0 (14)

The circle has y 0 = z 0 = 0 and radius R = p / 2 , as in Figure 14. The diameter line is the cross section of the band with width p. The band is normal to the paper. Note that the angle the center sees the band edges is just the solid angle value Ω₀. This is because the circle is the geometric locus of half of Ω₀ or j. The angle to the right of the figure is j of Equation (12). It is the angle through which P arrives at the edge of the band, that is, the angle of the tangent of the curve at the edge of the band. This is confirmed by the derivative d z / d y of the Equation (14) when z = 0 :

d z / d y = tan ( φ ) = y / z

When z → 0 , tan ( φ ) → ∞ or φ = π / 2 .

The second example is when the solid angle is Ω 0 = π / 2 and tan ( Ω 0 / 2 ) = 1 . Equation (13) is now:

z 2 + y 2 − p z − p 2 / 4 = 0 (15)

The first circle has its center at y 0 = 0 , z 0 = p / 2 and R = p / 2 . The overall curve is composed by two symmetrical arcs of circle as shown in Figure 15. The equi-Ω surface then is an infinite cylinder with the cross section of that figure. Note that the center angle, as in the first example, has the value Ω₀. The circle is the geometric locus of half of Ω₀ or φ. As the first case, the angle to the right of the figure is φ of Equation (12). It is the angle through which the point P arrives on the edge of the band, that is, the angle of the tangent of the curve at the edge. This can be confirmed by the derivative d z / d y of the Equation (15) at the edge or when z = 0 and y = p / 2 . This leads to φ = π / 4 .

For the case where Ω 0 = 0 , the locus of P is the band plane with P’ outside it and up to the of infinity, as shown in Figure 16.

For the case where Ω 0 = 2 π , the locus of P is the band plane for P’ inside it as shown in Figure 17.

We want to get the solid angle relative to the triangle ABC of Figure 18 when P is on the point C arriving to it through the direction of the arrow at right part of that figure.

From the triangle ACP’, at left part of Figure 18. We have:

b 2 = a 2 + c 2 + 2 a c cos ( φ / 2 ) (16)

The solid angle Ω_g for the triangle ABC is the difference between the solid angles for the isosceles triangle ABP’ and for the two identical triangles ACP’ and BCP’:

Ω γ = Ω AB P ′ − 2 Ω AC P ′ (17)

Ω_ABP’ is given by Equation (1) with j replaced by β and, as γ is constant during the movement of P, z is replaced by c tan γ and we make c tending to zero. Ω_ACP’ is given by Equation (4) where b² is replaced by its value of Equation (16). The result is:

Ω AC P ′ = arctan { [ a + c cos ( φ / 2 ) ] / [ c sin ( φ / 2 ) ] } − arctan { [ a + c cos ( φ / 2 ) ] tan γ } / { sin ( φ / 2 ) [ a 2 + 2 a c cos ( φ / 2 ) + c 2 ( 1 + tan γ ) ] 1 / 2 } − arctan [ cot ( φ / 2 ) ] + arctan { c cot ( φ / 2 ) tan γ / [ a 2 + 2 a c cos ( φ / 2 ) + c 2 ( 1 + tan γ ) ] 1 / 2 } (18)

The observer P approaches the point C if we get the limit of Equation (18) when c tends to zero with the angle γ kept constant. If Ω_γ is the resulting solid angle, we get:

Ω γ = 2 arctan [ tan γ / sin ( φ / 2 ) ] (19)

We can perform some confirmations of the above results. Suppose a smooth curve, that means, φ = π . For γ = 0 , using Equation (19), we get Ω 0 = 0 , as expected, because P initially is on the triangle plane, outside the triangle, and comes to the vertex. For γ = π / 2 , we get Ω π / 2 = φ , matching the result of Equation (2). For γ = π , we get Ω π = 2 π , as expected, because P is on the triangle plane, within the triangle, and comes to the vertex. In Equation (19), if we put φ = π (the case of smooth curves on P’), we get:

Ω γ = 2 γ (20)

Equation (20) shows that, for any smooth curve. the solid angle for the curve seen by a point P on the curve and arriving at it through a constant angle γ, is just 2γ. This confirms the result of Equation (12), for the infinite band case. This result is also valid for the common cone case, as we see next.

Figure 20 shows a non-regular polyhedron with 12 faces of two types, four squares and eight equilateral triangles. As we have two types of faces, there are two different defined solid angles seen by the center, Ω_s and Ω_t (the indexes s and t stand for square and triangle respectively). The total flux F of a point charge Q at the center of the polyhedron is:

Φ = Ω Q / ( 4 π ε 0 ) (22)

where Ω is the solid angle by which the charge sees the face. With little geometric observation, the square base pyramid with the vertex at the solid center has cos θ = 1 / 2 . So, by using Equation (3), the solid angle Ω_s for a square face is given by:

Ω s = 2 π { 1 − ( 4 / π ) arctan [ ( 1 / 2 ) tan ( π / 4 ) ] } = 1.3593

As there are six square faces and eight triangular ones, the solid angle Ω_t for one triangular face is given by:

Ω t = ( 4 π − 6 Ω s ) / 8 = 0.5513

By using [XV], we have finally:

Φ s = 0.10817 Q / ε 0

and

Φ τ = 0.04387 Q / ε 0

It would be possible to calculate Ω_t directly by the geometry as we did in the case of the square face. We easily find, for this case, cos θ = 2 / 3 .

Using Equation (3):

Ω t = 2 π { 1 − ( 3 / π ) arctan [ ( 2 / 3 ) tan ( π / 3 ) ] } = 0.5513

That is the same previous result.

By simple inspection, we see that the linear ratio between a regular polyhedron inscribed and another similar one circumscribed to the same sphere is R L = cos θ , θ being the angle of a straight regular pyramid with its vertex being the center of the polyhedron and whose base is the face of it. The ratios between the areas and the volumes of the two polyhedrons are respectively R A = cos 2 θ and R V = cos 3 θ .

From Equation (9) we can take cosθ:

cos θ = tan [ ( 2 π − Ω F ) / ( 2 N ) ] / tan ( π / N ) (23)

Using Equation (23), where Ω_F is the solid angle for one face, it is possible to calculate the area ratio R_A and volume ratio R_V between the inscribed and circumscribed polyhedrons for all five regular polyhedrons:

Tetrahedron: N = 3 ; Ω F = π \ R L = cos θ = 1 / 3 , R A = 1 / 9 and R V = 1 / 27

Cube: N = 4 ; Ω F = 2 ⋅ π / 3 \ R L = cos θ = 1 / 3 , R A = 1 / 3 and R V = 3 / 9

Octahedron: N = 3 ; Ω F = π / 2 \ R L = cos θ = 1 / 3 , R A = 1 / 3 and R V = 3 / 9

Dodecahedron: N = 5 ; Ω F = π / 3 \ R L = cos θ = 3 / [ 3 tan ( π / 5 ) ] , R A = 1 / [ 3 tan 2 ( π / 5 ) ] and R V = 3 / [ 9 tan 3 ( π / 5 ) ]

Icosahedron: N = 3 ; Ω F = π / 5 \ R L = cos θ = tan ( 3 π / 10 ) / 3 , R A = tan 2 ( 3 π / 10 ) / 3 and R V = 3 tan 3 ( 3 π / 10 ) / 9 .

We remember that:

tan ( π / 5 ) = 5 − 2 5

tan ( 3 π / 10 ) = ( 5 + 2 5 ) / 5

It is interesting to note that the cube and octahedron have both the same value of those ratios.

These results for the five regular polyhedrons are very hard to get if we do not use pyramid solid angles.