Hubble's Law and Recession Velocity Calculator

Apply Hubble's law in all three directions: find recession velocity from distance, distance from velocity, or both from redshift.

🌌 Hubble's Law and Recession Velocity Calculator
Hubble Constant (H₀)70 km/s/Mpc
km/s/Mpc
50100
Distance100 Mpc
Mpc
1 Mpc4,000 Mpc
Recession Velocity7000 km/s
km/s
100 km/s200,000 km/s
Redshift (z)0.100
z
0.0015
Recession Velocity
Fraction of c
Distance
Redshift (z)
Lookback Time
Hubble Time (1/H₀)

🌌 What is Hubble's Law?

Hubble's law is the foundational observation of modern cosmology, stating that every galaxy in the universe is receding from every other galaxy at a speed proportional to its distance. The relationship is written v = H₀ × d, where v is the recession velocity in km/s, d is the proper distance in megaparsecs, and H₀ is the Hubble constant. Published by Edwin Hubble in 1929 using Cepheid variable distances and Vesto Slipher's spectroscopic redshift data, it was the first direct evidence that the universe is not static but expanding.

The Hubble constant H₀ is the current expansion rate of the universe. Its value remains one of the most actively debated numbers in physics. Measurements based on the cosmic microwave background radiation (Planck 2018) give H₀ = 67.4 km/s/Mpc, meaning for every additional megaparsec of distance a galaxy is separated from us, it recedes by an extra 67.4 km/s. Direct measurements using Type Ia supernovae and Cepheid distance ladders (the SH0ES program) consistently give H₀ = 73 km/s/Mpc. The 5-sigma tension between these two values is one of cosmology's biggest open questions.

A common misconception is that recession velocities faster than light are forbidden by special relativity. They are not. Special relativity limits the speed of objects moving through space, not the rate at which space itself expands. Galaxies beyond the Hubble sphere (at distance c/H₀, roughly 4,280 Mpc for H₀ = 70) are currently receding faster than the speed of light, yet we can still observe them because light they emitted in the past has been travelling toward us ever since.

This calculator implements Hubble's law in all three directions: enter a distance in megaparsecs to find the recession velocity, enter a recession velocity to find the implied distance, or enter a spectroscopic redshift z to convert it to both. A fourth output is the lookback time, which estimates how long ago the light left the galaxy, computed as the light travel time d/c. This approximation is accurate to within a few percent for z less than 0.5 and gives the right order of magnitude for larger redshifts.

📐 Formula

v  =  H₀ × d
v = recession velocity (km/s)
H₀ = Hubble constant (km/s/Mpc); current best values: 67.4 (Planck) to 73 (SH0ES)
d = proper distance (Mpc; 1 Mpc = 3.086 × 1019 km = 3.262 million light-years)
z ≈ v/c for v << c (non-relativistic redshift approximation)
tₗₙ ≈ d/c (lookback time, light travel time approximation)
tH = 1/H₀ (Hubble time; 13.97 Gyr for H₀ = 70 km/s/Mpc)
Example: Galaxy at d = 100 Mpc, H₀ = 70: v = 70 × 100 = 7,000 km/s, z ≈ 0.0234

The Hubble distance DH = c/H₀ is the distance at which recession velocity equals c. For H₀ = 70 km/s/Mpc, DH = 299,800 / 70 = 4,283 Mpc. Galaxies beyond this distance recede superluminally. The Hubble time tH = 1/H₀ is computed as (3.0857 × 1019 km/Mpc) ÷ (H₀ × 3.156 × 1016 s/Gyr), giving 13.97 Gyr for H₀ = 70. The lookback time tₗₙ = d / c = d[Mpc] × 3.0857 × 1019 / (2.998 × 105 km/s) / (3.156 × 1016 s/Gyr), which equals d[Mpc] × 3.261 Myr/Mpc.

📖 How to Use This Calculator

Steps

1
Choose a calculation mode using the Distance, Velocity, or Redshift tab at the top of the widget, depending on which quantity you already know.
2
Set the Hubble constant H₀ using the top slider or input field. The default is 70 km/s/Mpc. Use 67.4 for Planck 2018 or 73 for the SH0ES local measurement.
3
Enter your input value (distance in Mpc, recession velocity in km/s, or redshift z) using the number field or drag the slider. Results update instantly.
4
Read the results panel, which shows recession velocity, fraction of c, inferred distance, redshift z, lookback time (light travel time), and the Hubble time for your chosen H₀.

💡 Example Calculations

Example 1 — Galaxy at 100 Mpc (H₀ = 70 km/s/Mpc)

Distance 100 Mpc: a typical nearby galaxy cluster separation

1
Apply Hubble's law: v = H₀ × d = 70 × 100 = 7,000 km/s.
2
Fraction of light speed: v/c = 7,000 / 299,800 = 2.3349% of c.
3
Redshift: z ≈ v/c = 0.02335. Lookback time: tₗₙ = 100 × 3.261 Myr/Mpc = 326 Myr.
v = 7000.00 km/s  |  z = 0.02335  |  Lookback = 326.13 Myr
Try this example →

Example 2 — Virgo Cluster at 16.5 Mpc (H₀ = 70 km/s/Mpc)

Virgo Cluster at d = 16.5 Mpc: the nearest large galaxy cluster

1
Recession velocity: v = 70 × 16.5 = 1,155 km/s. The Virgo Cluster's measured recession velocity is indeed near this value.
2
Fraction of c: 1,155 / 299,800 = 0.3853% of c. Redshift z = 0.00385.
3
Lookback time: 16.5 × 3.261 Myr/Mpc = 53.81 Myr. We see the Virgo Cluster as it was about 54 million years ago.
v = 1155.00 km/s  |  z = 0.00385  |  Lookback = 53.81 Myr
Try this example →

Example 3 — Recession velocity 15,000 km/s (H₀ = 70 km/s/Mpc)

Velocity mode: recession velocity 15,000 km/s (5% of c)

1
Invert Hubble's law: d = v / H₀ = 15,000 / 70 = 214.29 Mpc.
2
Fraction of c: 15,000 / 299,800 = 5.0033% of c. Redshift z = 0.05003.
3
Lookback time: 214.29 × 3.261 Myr/Mpc = 698.84 Myr (about 0.7 billion years of light travel time).
d = 214.2857 Mpc  |  z = 0.05003  |  Lookback = 698.84 Myr
Try this example →

Example 4 — Spectroscopic redshift z = 0.1 (H₀ = 70 km/s/Mpc)

Redshift mode: z = 0.1, a moderately distant galaxy survey target

1
Non-relativistic recession velocity: v = c × z = 299,800 × 0.1 = 29,980 km/s.
2
Hubble distance: d = v / H₀ = 29,980 / 70 = 428.29 Mpc (about 1.4 billion light-years).
3
Lookback time: 428.29 Mpc × 3.261 Myr/Mpc = 1.397 Gyr. This galaxy is seen as it was about 1.4 billion years ago.
v = 29980.00 km/s  |  d = 428.2857 Mpc  |  Lookback = 1.397 Gyr
Try this example →

❓ Frequently Asked Questions

What is Hubble's law and what does it tell us about the universe?+
Hubble's law (v = H₀ × d) states that every galaxy recedes at a speed proportional to its distance. Discovered by Edwin Hubble in 1929, it was the first direct observational evidence that the universe is expanding. Combined with general relativity, it implies the universe began in a hot, dense state (the Big Bang) and has been expanding ever since.
What is the current best value of the Hubble constant H₀?+
Two independent measurements give different answers: the Planck 2018 CMB analysis gives H₀ = 67.4 plus or minus 0.5 km/s/Mpc, while the SH0ES distance ladder gives 73.0 plus or minus 1.0 km/s/Mpc. The 5-sigma tension between them has not been resolved and is one of the biggest open problems in cosmology. This calculator defaults to 70 km/s/Mpc as a round midpoint, but you can set any value from 50 to 100.
Can recession velocity exceed the speed of light?+
Yes. Recession velocity in Hubble's law is the rate at which proper distance between two points grows due to the expansion of space, not the motion of an object through space. Special relativity only limits speeds through space to c. Galaxies beyond the Hubble distance DH = c/H₀ (about 4,280 Mpc for H₀ = 70) are currently receding faster than light, yet light they emitted in the past has been reaching us the whole time.
What is the Hubble time and how is it calculated?+
The Hubble time is tH = 1/H₀, the inverse of the Hubble constant. For H₀ = 70 km/s/Mpc: tH = (3.0857 × 1019 km/Mpc) / (70 km/s/Mpc) / (3.156 × 1016 s/Gyr) = 13.97 Gyr. In a universe that expanded at a constant rate it would equal the age of the universe exactly. The true age of the universe (13.8 Gyr) is close but slightly different due to deceleration by matter and acceleration by dark energy.
What is the lookback time and how accurate is the light travel time approximation?+
Lookback time is how long ago the light you observe left its source. The light travel time approximation t = d/c (used here) is accurate to within a few percent for z less than 0.3. For z = 0.1, this calculator gives 1.397 Gyr; the exact LCDM result is about 1.286 Gyr (about 8% lower). For z = 0.5 the approximation overestimates by about 25%. For precise results at high redshift, use the full Friedmann integral with matter, radiation, and dark energy parameters.
What is redshift and how does it relate to recession velocity in Hubble's law?+
Redshift z is the fractional change in wavelength: z = (lambdaobs - lambdarest) / lambdarest. For recession velocities much smaller than c, z equals v/c (the non-relativistic Doppler approximation). Hubble's law then reads z = H₀ × d / c, giving a direct linear relationship between redshift and distance. This approximation holds well for z less than about 0.3; for higher redshifts the relativistic Doppler formula gives v = c × ((z+1)2 - 1) / ((z+1)2 + 1).
Why does Hubble's law break down at large distances?+
Hubble's law is a linear approximation valid only when the look-back time is short compared to the age of the universe. At large distances, two corrections matter: (1) the linear Taylor expansion of the scale factor fails at high z, and (2) the expansion rate itself has changed over cosmic time. The universe decelerated for the first 8 billion years as matter dominated, then began accelerating as dark energy took over, so H₀ today does not describe the rate of expansion in the early universe.
How do astronomers measure the recession velocity of a galaxy?+
Astronomers take a spectrum of the galaxy and identify known spectral features such as the hydrogen Lyman-alpha line (rest wavelength 121.6 nm), the hydrogen H-alpha line (656.3 nm), or the calcium H and K doublet (396.8 and 393.4 nm). The observed wavelength divided by the rest wavelength gives (1 + z), from which the recession velocity follows as v = cz for small z. Modern surveys like SDSS measure redshifts for millions of galaxies this way.
What is the Hubble tension and why does it matter?+
The Hubble tension is the 5-sigma disagreement between early-universe (CMB) measurements of H₀ and late-universe (distance ladder) measurements. If systematic errors do not explain it, the standard LCDM model is incomplete and new physics is needed, possibly early dark energy, extra relativistic species, or a non-standard dark matter interaction. Resolving the tension is one of the highest priorities in observational cosmology.
What units is the Hubble constant measured in and why km/s/Mpc?+
The Hubble constant is expressed in km/s/Mpc because it relates recession velocity (km/s) to distance (Mpc). The unit makes the proportionality explicit: for every additional megaparsec of distance, the recession velocity increases by H₀ km/s. In SI units, H₀ has dimensions of s-1 (inverse seconds): 70 km/s/Mpc = 70 × 103 / (3.0857 × 1022) s-1 = 2.27 × 10-18 s-1.
How far away is a galaxy with redshift z = 0.05 for H₀ = 70 km/s/Mpc?+
Using v = cz = 299,800 × 0.05 = 14,990 km/s, then d = v/H₀ = 14,990 / 70 = 214.1 Mpc (about 699 million light-years). The lookback time is about 699 Myr. Many galaxies in medium-depth surveys like 2dFGRS and 6dFGS fall in this redshift range.
What is the difference between proper distance and comoving distance in Hubble's law?+
Proper distance is the physical separation between two objects at a fixed cosmic time, measured by a ruler laid out across the universe right now. Comoving distance factors out the expansion: two objects in the Hubble flow maintain the same comoving separation as the universe expands. Hubble's law v = H₀ × d uses the current proper distance d. For small redshifts these two distances are nearly identical; they diverge significantly only at z greater than about 0.5.

What is Hubble's law and what does it mean?

Hubble's law states that the recession velocity of a galaxy is proportional to its distance: v = H0 x d. Discovered by Edwin Hubble in 1929, it was the first observational evidence that the universe is expanding. The constant of proportionality H0 (the Hubble constant) gives the current rate of expansion in km/s per megaparsec.

What is the current accepted value of the Hubble constant?

There are two competing measurements. The Planck 2018 CMB analysis gives H0 = 67.4 km/s/Mpc with an uncertainty of about 0.5 km/s/Mpc. Direct local distance-ladder measurements (SH0ES) give H0 = 73.0 plus or minus 1.0 km/s/Mpc. The tension between these two values is one of the biggest open problems in cosmology.

Can recession velocity exceed the speed of light?

Yes. Recession velocities in Hubble's law represent the rate at which space expands between two points, not the motion of an object through space. Special relativity limits the speed of objects through space to c, but there is no such restriction on the expansion rate of space itself. Galaxies beyond the Hubble distance (c/H0, about 4,280 Mpc for H0 = 70) are currently receding faster than light.

What is the Hubble time?

The Hubble time is 1/H0, the inverse of the Hubble constant. For H0 = 70 km/s/Mpc it equals about 13.97 billion years. In a universe with no acceleration or deceleration it would be the exact age of the universe, but in the real LCDM universe the actual age (13.8 Gyr) is close but not identical.

What is the lookback time shown by this calculator?

The lookback time is the light travel time approximation: t = d/c, where d is the distance in Mpc and c is the speed of light. This is accurate to a few percent for z less than 0.5. For large redshifts, the true lookback time requires integrating over the Friedmann equation with matter, radiation, and dark energy density parameters.

What is redshift and how does it relate to recession velocity?

Redshift z is the fractional change in wavelength of light emitted by a receding galaxy. For small recession velocities (v much less than c), z equals v/c, which is the formula this calculator uses. For z greater than about 0.3, the relativistic Doppler formula or the full cosmological treatment gives more accurate results.

Why does Hubble's law break down at very large distances?

At large distances two effects matter. First, the linear relationship v = H0 x d is a first-order Taylor expansion of the full scale factor evolution, so it fails at high z. Second, the expansion rate itself has changed over cosmic time (it decelerated due to matter and then accelerated due to dark energy), so the current H0 does not describe the expansion rate in the distant past.

How do astronomers measure recession velocities?

Recession velocities are inferred from spectroscopic redshift. Astronomers compare the observed wavelengths of known spectral lines (hydrogen Lyman-alpha at 121.6 nm, calcium H and K at 397 and 393 nm, etc.) against laboratory wavelengths. The redshift z = (lambda_obs - lambda_rest) / lambda_rest directly gives v = cz for nearby galaxies.

What is the Hubble tension and why does it matter?

The Hubble tension is the 5-sigma discrepancy between early-universe CMB measurements (H0 approximately 67 km/s/Mpc) and late-universe distance-ladder measurements (H0 approximately 73 km/s/Mpc). If the tension is real and not due to systematic errors, it implies new physics beyond the standard LCDM model, possibly involving early dark energy or modified gravity.

What units is the Hubble constant measured in?

The Hubble constant H0 is measured in km/s/Mpc (kilometres per second per megaparsec). This means for every additional megaparsec of distance, the recession velocity increases by H0 km/s. In SI units, H0 has dimensions of inverse time (s to the power minus 1), with 70 km/s/Mpc corresponding to about 2.27 times 10 to the power minus 18 per second.

What is the difference between proper distance and comoving distance?

Proper distance is the actual physical separation between two points at a given cosmic time. Comoving distance factors out the expansion so that two objects in the Hubble flow have a fixed comoving separation even as the universe expands. The distance d in Hubble's law v = H0 x d refers to the current proper distance.

How far away is a galaxy with recession velocity 1000 km/s for H0 = 70?

Using d = v/H0: d = 1000 / 70 = 14.29 Mpc, or about 46.6 million light-years. This is roughly the distance to the Virgo Cluster, whose member galaxies do indeed show recession velocities near 1000 km/s.