Gravitational Acceleration

GRAVITATIONAL FIELD MAPPED

GRAVITY ARCHITECT

NEWTONIAN FIELD SIMULATOR

PLANET MASS (M in kg)

Earth ≈ 5.97e24 | Jupiter ≈ 1.90e27

PLANET RADIUS ($r$ in meters)

Earth ≈ 6.37e6 | Sun ≈ 6.96e8

Gravity Core

Constant Force. Gravitational acceleration defines the rate of descent for all objects in a vacuum.

🌎 Earth Standard: 9.806 m/s 2 at sea level.
⚖️ Mass Independent: In a vacuum, a feather and a hammer fall at the same rate.
🌌 Orbital Mechanics: The foundation for Keplerian motion in your simulations.

☄️

FORCE CONSTANT: G

ACCELERATION:

9.80 m/s²

EARTH_REFERENCE_V1

G-Force Vector

Relative Load. G-force measures the apparent weight of an object during rapid velocity changes.

🏎️ Lateral G: Experienced during high-speed cornering.
🚀 Longitudinal G: Felt during rapid takeoff or braking.
🔬 Sensor Logic: Utilizing mobile accelerometers for real-time calculation.

⚖️

SENSOR: ACCELEROMETER

RELATIVE LOAD:

[ 3.42 G ]

AXIS: LONGITUDINAL

Escape Vector

Gravitational Exit. Escape velocity is the Kinetic Threshold required to leave a planetary well forever.

🚀 Threshold: 11.2 km/s required to leave Earth's influence.
📉 Inverse Square: ve decreases as you move further from the center.
⚛️ Energy Balance: Where Kinetic Energy exactly cancels Potential Energy.

☄️

CALCULATION: ESCAPE VELOCITY

VELOCITY ($v_e$):

11.18 km/s

TARGET: LEO_EXIT

Orbit Engine

Circular Balance. Low orbit speed is the Exact Equilibrium where gravity becomes a steering force rather than a collision.

🛰️ Velocity: Required speed is roughly **7.8 km/s** for LEO.
🔄 Period: One full revolution every **90 to 120 minutes**.
📉 Altitude Rule: The higher the orbit, the **slower** the required speed.

🛰️

SYSTEM: ORBITAL TRACKER

VELOCITY ($v_o$):

7.67 km/s

ALTITUDE: 400 KM

Paper

GRAVITY LOG: g = GM / r² 🍏

Subject: Kinematics & Force. Target: Constant Acceleration.

Gravitational Accel.

g = GM / r²

G = Gravitational Constant

M = Mass of the planet

r = Radius of the planet