Pulse Train Calculator
This calculator will help you calcaulate the vairous properties of an optical pulse train.
Input
Pulse Duration, $T$:
ns
Repetition rate, $f$:
MHz
Average Power, $P_{ave}$:
W
Spot Diameter:
mm
Output
Duty Cycle, $D$:
Pusle Energy:
μJ
Peak Power$^2$, P$_{peak}$:
W
Pulse separation:
μs
Average Intensity:
W/cm$^2$
Peak Intensity:
kW/cm$^2$
×
Duty cycle
The formula that will be used to find
Duty Cycle
is as followed:
$D$ = $T.f$
Duty Cycle, $D$;
Pulse Duration, $T$; Repetition Rate, $f$;
×
Pulse Energy
The formula that will be used to find
Pulse Energy
is as followed:
$E_{pulse}$ = $\frac{P_{avg}}{f}$
Pulse Energy, $E_{pulse}$
Average Power, $P_{ave}$; Repetition Rate, $f$;
×
Peak Power
The formula that will be used to find
Peak Power
is as followed:
$P_{peak}$ = $\frac{E_{pulse}}{T}$
Peak Power$^2$, P$_{peak}$;
Pulse Energy, $E_{pulse}$; Pulse Duration, $T$;
×
Pulse Separation
The formula that will be used to find
Pulse Separation
is as followed:
$\triangle T$ = $\frac{1}{f}$
Pulse separation, $\triangle T$;
Repetition Rate, $f$;
×
Average_intensity
The formula that will be used to find
Average Intensity
is as followed:
${Area}$ = $\pi (\frac{d}{2})^2$
Intensity$_{avg}$ = $\frac{P_{ave}}{Area}$
Average Intensity, Intensity$_{avg}$; Area;
Spot Diameter, $d$; Average Power, $P_{ave}$;
×
Peak Intensity
The formula that will be used to find
Peak Intensity
is as followed:
${Area}$ = $\pi (\frac{d}{2})^2$
Intensity$_{peak}$ = $\frac{P_{peak}}{Area}$
Peak Intensity, Intensity$_{peak}$; Area;
Spot Diameter, $d$; Peak Power$^2$, P$_{peak}$;
