Turn apparent brightness into intrinsic luminosity measures. Choose parsecs or light‑years add correction terms instantly. Get absolute magnitude with clear steps and exports included.
Corrected apparent magnitude: mcorr = m − A − K
Absolute magnitude from distance (parsec): M = mcorr − 5 log10(d/10)
Distance modulus: μ = 5 log10(d) − 5 (with d in parsecs)
Luminosity ratio estimate: L/Lsun = 100.4(Msun − M)
Absolute magnitude compares intrinsic brightness at a standard distance of 10 parsecs.
| Apparent m | Distance (pc) | Extinction A | K-corr K | Absolute M |
|---|---|---|---|---|
| 8.1 | 120 | 0.12 | 0.05 | 2.534 |
| 12.3 | 980 | 0.2 | 0 | 2.144 |
| 16.5 | 35000 | 0.05 | 0.3 | -1.57 |
| 5.7 | 15.5 | 0 | 0 | 4.748 |
| 19.2 | 1200000 | 0.4 | 0.1 | -6.696 |
Values are illustrative and assume distance in parsecs.
Absolute magnitude, M, is the apparent magnitude an object would have if placed at a standard distance of 10 parsecs. It removes distance effects and lets you compare intrinsic brightness across stars, supernovae, and galaxies using the same photometric band.
The core relation links m and M through the distance modulus. When distance d is in parsecs, the modulus is μ = 5 log10(d) − 5. A tenfold distance increase raises μ by 5 magnitudes, making objects look 100 times fainter.
Interstellar dust dims and reddens light, shifting measured magnitudes upward. Extinction A is applied as a subtraction in this calculator, mcorr = m − A − K, to estimate the unobscured brightness. Even A = 0.2 mag changes inferred luminosity by about 20 percent.
K-correction accounts for redshift moving the emitted spectrum through the observing filter. For nearby stars it is typically negligible, but for galaxies and quasars it can be significant. Using a band-consistent K prevents systematic offsets in M when comparing sources at different redshifts.
This tool accepts parsecs or light‑years and converts using 1 pc = 3.26156 ly. For parallaxes, distances are naturally in parsecs; for outreach data, light‑years are common. Always verify whether a catalog distance is heliocentric, comoving, or luminosity distance before interpreting M.
Lower (more negative) absolute magnitude means higher intrinsic brightness. For example, M ≈ 4.8 is roughly solar in the visual band, while bright supergiants can reach M ≈ −8. A difference of 1 magnitude corresponds to a brightness factor of 2.512.
The calculator reports an approximate luminosity ratio using L/Lsun = 100.4(Msun − M). This is band-limited, not bolometric, unless your inputs and Msun reference are bolometric. For physical luminosities, apply bolometric corrections and calibrated zero points.
A strong workflow is: record m, select method, apply A and K if justified, and compute M and μ. Export CSV for spreadsheets and the PDF for lab notes or proposals. Keep units and bands consistent across your dataset to avoid hidden systematic errors.
Apparent magnitude measures how bright an object looks from Earth. Absolute magnitude is the brightness the object would have at 10 parsecs, allowing direct comparison of intrinsic luminosity independent of distance.
Use luminosity distance when converting observed flux or apparent magnitude to absolute magnitude in cosmology. If your catalog provides a distance modulus, you can enter μ directly to avoid unit confusion.
No. Nearby objects may have small extinction, but many lines of sight contain dust. If you have a reliable extinction estimate in the same band, include it; otherwise document assumptions and consider uncertainty ranges.
Select the distance modulus method and enter μ. The calculator uses M = m − A − K − μ. This is common for standard-candle work where μ is tabulated from light-curve fitting.
Magnitude is logarithmic and inverted. Brighter objects have smaller, often negative, magnitudes. A very luminous source can have M well below zero because it would still appear bright even at 10 parsecs.
It estimates brightness relative to the Sun using your chosen solar reference magnitude. It is a band-based ratio unless you use bolometric values. Treat it as a comparative indicator rather than an absolute energy output.
Magnitude depends strongly on distance: a 10% distance error changes μ by about 0.2 mag and shifts M by the same amount. Propagate distance uncertainties and report M with appropriate error bars.
Important Note: All the Calculators listed in this site are for educational purpose only and we do not guarentee the accuracy of results. Please do consult with other sources as well.