optics Optics is the branch of physics that studies the behaviour and properties of light, including its interactions with matter and the construction of instruments that use or detect it. Optics usually describes the behaviour of visible, ultraviole ...

, the complex beam parameter is a

complex number In mathematics, a complex number is an element of a number system that extends the real numbers with a specific element denoted , called the imaginary unit and satisfying the equation i^= -1; every complex number can be expressed in the form ...

that specifies the properties of a Gaussian beam at a particular point z along the axis of the beam. It is usually denoted by ''q''. It can be calculated from the beam's vacuum

wavelength In physics, the wavelength is the spatial period of a periodic wave—the distance over which the wave's shape repeats. It is the distance between consecutive corresponding points of the same phase on the wave, such as two adjacent crests, tro ...

λ₀, the radius of curvature ''R'' of the

phase front Phase or phases may refer to: Science *State of matter, or phase, one of the distinct forms in which matter can exist *Phase (matter), a region of space throughout which all physical properties are essentially uniform * Phase space, a mathematic ...

, the

index of refraction In optics, the refractive index (or refraction index) of an optical medium is a dimensionless number that gives the indication of the light bending ability of that medium. The refractive index determines how much the path of light is bent, or ...

''n'' (''n''=1 for air), and the beam radius ''w'' (defined at 1/''e''² intensity), according to: :

\frac = \frac - \frac

. Alternatively, ''q'' can be calculated according to :

q(z) = z + \frac= z + z_\mathrm i\ ,

where ''z'' is the location, relative to the location of the beam waist, at which ''q'' is calculated, ''z''_R is the

Rayleigh range In optics and especially laser science, the Rayleigh length or Rayleigh range, z_\mathrm, is the distance along the propagation direction of a beam from the waist to the place where the area of the cross section is doubled. A related parameter ...

, and ''i'' is the

imaginary unit The imaginary unit or unit imaginary number () is a solution to the quadratic equation x^2+1=0. Although there is no real number with this property, can be used to extend the real numbers to what are called complex numbers, using addition an ...

Beam propagation

The complex beam parameter is usually used in ray transfer matrix analysis, which allows the calculation of the beam properties at any given point as it propagates through an optical system, if the ray matrix and the initial complex beam parameter is known. This same method can also be used to find the fundamental mode size of a stable

optical resonator An optical cavity, resonating cavity or optical resonator is an arrangement of mirrors or other optical elements that forms a cavity resonator for light waves. Optical cavities are a major component of lasers, surrounding the gain medium and provi ...

. Given the initial beam parameter, ''q''_i, one can use the ray transfer matrix of an optical system,

\begin A & B \\ C & D \end

, to find the resulting beam parameter, ''q''_f, after the beam has traversed the system: :

q_f = \frac

. It is often convenient to express this equation in terms of the reciprocals of ''q'': :

= \frac

Free-space propagation

The effect of propagation in free space is just that of adding the travelled axial distance to the complex beam parameter:Kochkina, eq. 4.16 :

q_f = q_i + \Delta z

Interfaces

For ''simple astigmatic'' fundamental Gaussian beams,Kochkina, ch. 4 the q- parameters for the tangential and sagittal planes are ''independent''. This is no longer true if those planes do not coincide with the principal direction of the surface on which the beam impinges; that case is called ''general astigmatism''. Formulas for an incidence angle ''θ''_i were derived in Massey and Siegman's 1969 paper. For reflection, the matrices read:Kochkina, eq. 4.35 :

\begin
M_t&=\begin 1 & 0 \\ \frac & 1 \end, &
M_t&=\begin 1 & 0 \\ \frac & 1 \end.
\end

The ones for refraction are:Kochkina, eq. 4.42,43 :

\begin
M_t&=\begin \frac & 0 \\ 
\frac & \frac \end, &
M_t&=\begin 1 & 0 
\\ \frac &  \end.
\end

Fundamental mode of an optical resonator

To find the complex beam parameter of a stable

, one needs to find the ray matrix of the cavity. This is done by tracing the path of beam in the cavity. Assuming a starting point, find the matrix that goes through the cavity and return until the beam is in the same position and direction as the starting point. With this matrix and by making ''q''_i = ''q''_f, a quadratic is formed as: :

C^2 + (D-A)q_f - B = 0

. Solving this equation gives the beam parameter for the chosen starting position in the cavity, and by propagating, the beam parameter for any other location in the cavity can be found.

References

* {{DEFAULTSORT:Complex Beam Parameter Optics