The general equations describing Q-switched laser operation are transcendental in nature and require numerical solutions, which greatly complicates the optimization of real devices. Here, it is shown that, using the mathematical technique of Lagrange multipliers, one can derive simple analytic expressions for all of the key parameters of the optimally coupled laser, i.e. one which uses an optimum reflector to obtain maximum laser efficiency for a given pump level. These parameters can all be expressed as functions of a single dimensionless variable z, defined as the ratio of the unsaturated small-signal gain to the dissipative (nonuseful) optical loss, multiplied by a few simple constants. Laser design tradeoff studies and performance projections can be accomplished quickly with the help of several graphs and a simple hand calculator. Sample calculations for a high-grain Nd:YAG and a low-gain alexandrite laser are presented as illustrations of the technique. >
[1]
William G. Wagner,et al.
Evolution of the Giant Pulse in a Laser
,
1963
.
[2]
John A. Caird,et al.
Spectroscopic, optical, and thermomechanical properties of neodymium- and chromium-doped gadolinium scandium gallium garnet
,
1986
.
[3]
John C. Walling,et al.
Tunable alexandrite lasers
,
1980
.
[4]
Walter Koechner,et al.
Solid-State Laser Engineering
,
1976
.
[5]
R. Morris,et al.
Tunable CW alexandrite laser
,
1980
.
[6]
D. Mccumber,et al.
Theory of Phonon-Terminated Optical Masers
,
1964
.
[7]
R. B. Kay,et al.
Complete Solutions to the Rate Equations Describing Q‐Spoiled and PTM Laser Operation
,
1965
.