A compound prism is a set of multiple triangular prism elements placed in contact, and often cemented together to form a solid assembly.[1] The use of multiple elements gives several advantages to an optical designer:[2]
\theta0
The simplest compound prism is a doublet, consisting of two elements in contact, as shown in the figure at right. A ray of light passing through the prism is refracted at the first air-glass interface, again at the interface between the two glasses, and a final time at the exiting glass-air interface. The deviation angle
\delta
\delta=\theta0-\theta4
\delta
\begin{align} \theta1&=\theta0-\beta1&\theta3&=\theta'2-\alpha2\\ \theta'1&=\arcsin(\tfrac{1}{n1}\sin\theta1) &\theta'3&=\arcsin(n2\sin\theta3)\\ \theta2&=\theta'1-\alpha1&\theta4&=\theta'3+\tfrac{1}{2}\alpha2\\ \theta'2&=\arcsin(\tfrac{n1}{n2}\sin\theta2) \end{align}
n1(λ)
n2(λ)
\alpha1
\alpha2
\theta0
\alphai
If the angle of incidence
\theta0
\alpha
\sin\theta ≈ \theta
arcsin(x) ≈ x
\delta
\delta(λ)=[n1(λ)-1]\alpha1+[n2(λ)-1]\alpha2 .
\Delta=
| \delta1(\bar{λ | |
| )}{V |
1}+
| \delta2(\bar{λ | |
| )}{V |
2} ,
\deltai
Vi
i
Vi=(\bar{n}-1)/(nF-nC)
\bar{λ}
Doublet prisms are often used for direct-vision dispersion. In order to design such a prism, we let
\bar{\delta}=0
\delta
\Delta
\delta1(\bar{λ})=-\delta2(\bar{λ})=-\Delta(
| 1 | |
| V2 |
-
| 1 | |
| V1 |
)-1 ,
\alpha1
\alpha2
\begin{align} \alpha1&=
| \Delta | |
| \bar{n |
1-1}(
| 1 | |
| V1 |
-
| 1 | |
| V2 |
)-1 ,\\ \alpha2&=
| \Delta | |
| \bar{n |
2-1}(
| 1 | |
| V2 |
-
| 1 | |
| V1 |
)-1 . \end{align}
While the doublet prism is the simplest compound prism type, the double-Amici prism is much more common. This prism is a three-element system (a triplet), in which the first and third elements share both the same glass and the same apex angles. The design layout is thus symmetric about the plane passing through the center of its second element. Due to its symmetry, the linear design equations (under the small angle approximation) for the double-Amici prism differ from those of the doublet prism only by a factor of 2 in front of the first term in each equation:[2]
\begin{align} \delta(\bar{λ})&=2\delta1(\bar{λ})+\delta2(\bar{λ})=2(\bar{n}1-1)\alpha1+(\bar{n}2-1)\alpha2 ,\\ \Delta&=2
| \delta1(\bar{λ | |
| )}{V |
1}+
| \delta2(\bar{λ | |
| )}{V |
2} . \end{align}
\begin{align} \alpha1&=
| \Delta | |
| 2(\bar{n |
1-1)}(
| 1 | |
| V1 |
-
| 1 | |
| V2 |
)-1 ,\\ \alpha2&=
| \Delta | |
| \bar{n |
2-1}(
| 1 | |
| V2 |
-
| 1 | |
| V1 |
)-1 . \end{align}
The exact nonlinear equation for the deviation angle
\delta
\begin{align} \theta1&=\theta0+\alpha1-\tfrac{1}{2}\alpha2&\theta'3&=\arcsin(\tfrac{n2}{n1}\sin\theta3)\\ \theta'1&=\arcsin(\tfrac{1}{n1}\sin\theta1) &\theta4&=\theta'3-\alpha1\\ \theta2&=\theta'1-\alpha1&\theta'4&=\arcsin(n1\sin\theta4)\\ \theta'2&=\arcsin(\tfrac{n1}{n2}\sin\theta2)&\theta5&=\theta'4+\alpha1-\tfrac{1}{2}\alpha2\\ \theta3&=\theta'2-\alpha2 \end{align}
\delta=\theta0-\theta5
The double-Amici prism is a symmetric form of the more general triplet prism, in which the apex angles and glasses of the two outer elements may differ (see the figure at right). Although triplet prisms are rarely found in optical systems, their added degrees of freedom beyond the double-Amici design allow for improved dispersion linearity. The deviation angle of the triplet prism is obtained by concatenating the refraction equations at each interface:[6] [7]
\begin{align} \theta1&=\theta0+\alpha1+\tfrac{1}{2}\alpha2&\theta'3&=\arcsin(\tfrac{n2}{n3}\sin\theta3)\\ \theta'1&=\arcsin(\tfrac{1}{n1}\sin\theta1) &\theta4&=\theta'3-\alpha3\\ \theta2&=\theta'1-\alpha1&\theta'4&=\arcsin(n3\sin\theta4)\\ \theta'2&=\arcsin(\tfrac{n1}{n2}\sin\theta2)&\theta5&=\theta'4+\alpha3+\tfrac{1}{2}\alpha2\\ \theta3&=\theta'2-\alpha2 \end{align}
Here to the ray deviation angle is given by
\delta=\theta0-\theta5