Astrophotography Calculators
Calculate star trail exposure times, the 500 rule, NPF rule, moon phases and polar alignment.
500 Rule Calculator
Calculate the maximum shutter speed for sharp stars using the 500 Rule. Enter focal length and crop factor for instant results. Free online astrophotography calculator.
NPF Rule Calculator
Calculate precise maximum exposure time using the NPF Rule for pin-sharp stars. More accurate than the 500 Rule for high-resolution sensors. Free calculator.
Star Trail Calculator
Plan star trail photography sessions with exposure count, interval timing and total duration. Calculate trail length for stunning circular star images. Free calculator.
Moon Phase Calculator
Calculate moon illumination percentage and phase for any date. Plan astrophotography shoots around moonless nights for dark skies. Free online calculator.
ISS Pass Calculator
Estimate International Space Station visibility windows and plan pass photography settings. Get suggested exposure and focal length values. Free online calculator.
Milky Way Position Calculator
Estimate Milky Way galactic core visibility based on your date and location. Plan shoots during peak visibility windows for best results. Free calculator.
Polar Alignment Calculator
Calculate polar alignment offset for equatorial tracking mounts. Achieve accurate alignment for long-exposure deep-sky astrophotography. Free online calculator.
Astro Exposure Calculator
Calculate total integration time and number of sub-exposures needed for deep-sky image stacking. Plan your astrophotography session length. Free calculator.
8 free calculators in Astrophotography
Understanding Astrophotography
Astrophotography presents unique technical challenges. The Earth rotates at approximately 15 degrees per hour, causing stars to trail in long exposures. The classic 500 Rule divides 500 by the effective focal length to give the maximum exposure time in seconds before stars begin to visibly trail: for a 24mm lens on full-frame, that is about 20 seconds.
The more precise NPF Rule accounts for pixel pitch, aperture, and declination to give a tighter limit for modern high-resolution sensors. It typically produces shorter maximum exposure times than the 500 Rule but ensures pin-sharp stars when pixel-peeping.
Moon phase directly affects astrophotography planning. A new moon provides the darkest skies for deep-sky and Milky Way photography, while a full moon washes out faint nebulae and the galactic core. The Milky Way core is best visible from the UK between April and September, when it rises high enough above the southern horizon.
For deep-sky work with tracked mounts, total integration time (the sum of all sub-exposures) determines signal-to-noise ratio. Stacking many shorter exposures reduces noise while preserving detail. Our calculators help you plan every aspect of your night sky photography.