Earth Observation

Sharper imagery from a closer orbit.

At 200 km, the same sensor delivers 3× the resolution it achieves at 600 km. The cheapest way to a sharper image is a lower orbit.

600 km · same sensor
200 km · 3× sharper

Simulated — drag to compare. Aperture scales linearly with altitude, so the same optics resolve ~3× finer detail at 200 km.

Why VLEO for EO

Resolution is a function of altitude.

3× resolution

Same aperture, finer detail (inverse-square relationship). A 0.5 m mission needs only a 0.22 m aperture at 200 km vs 0.88 m at 800 km.

Better signal-to-noise

Up to 12× signal strength improvement at lower altitude.

Longer sensor life

Reduced radiation extends sensor life and allows less shielding.

Validated commercially

Albedo's Clarity-1 at ~275 km proved VLEO EO; 10 cm-class imagery is achievable.

The 50 kg advantage

Same resolution. A fraction of the mass.

For a fixed 0.5 m-resolution mission, spacecraft dry mass drops from ~1,559 kg at 800 km to ~17 kg at 200 km — smaller satellites, lower launch costs, faster constellations.

At 800 km
1,559kg

dry mass for a 0.5 m mission

At 200 km
~17kg

same resolution, on BREATHE

Market context
$42B

EO market by 2030, at 33.5% CAGR.

Demand for sub-meter imagery is growing fast across agriculture, climate, insurance, and infrastructure monitoring — and resolution is the dimension customers pay most for.

Find your orbit

Explore what your sensor can achieve at 200 km.