Physics Calculators
Computes an object’s final velocity under uniform acceleration over time, enabling fast prediction of linear kinematic behavior. Also computes any other variable—initial velocity, acceleration, or time—by letting the user supply the remaining values.
Computes an object’s displacement under constant acceleration using initial velocity, time, and acceleration to model linear kinematics. Also computes any one variable—initial velocity, acceleration, or time—by letting the user supply the remaining values.
Computes an object’s final velocity based on its initial velocity, acceleration, and displacement, enabling direct prediction of motion without needing time. Also computes any other variable—initial velocity, acceleration, or displacement—by letting the user supply the remaining values.
Computes ground speed under zero-wind and wind-aligned conditions by applying strict unit-harmonized airspeed and wind component logic.
Captures how far and in what direction an object has truly shifted by measuring its straight-line positional change from start to end, independent of the path taken.
Computes time, velocity, displacement, terminal speed and full motion trajectories under gravity using both ideal and drag-inclusive physics models.
Evaluates how forces applied over time change an object’s motion by calculating impulse, momentum variation, and collision-related force effects in linear, angular, and multi-body cases.
Determines post-interaction velocities, impulses, and rotational responses by applying exact linear and angular momentum conservation across elastic, inelastic, and multi-body systems.
Computes complete projectile-motion physics—including range analyses, time of flight, horizontal and vertical displacements, velocities, impact angle, trajectory and trajectory equation.
Determines the net velocity by vector-combining multiple motion components in magnitude and direction to yield a single final velocity.
Quantifies frictional forces, energy losses, motion behavior, and traction limits across static, kinetic, rolling, and incline scenarios.
Determines an object’s maximum steady-state falling speed under multiple drag regimes, fluid conditions across multiple physical drag models.
Evaluates turbulence-model uncertainty and optimizes experiment design by analyzing flow conditions, error sources, measurement needs, and model sensitivities.
Calculates fundamental velocity relationships by determining speed, time, displacement or final velocity using direct kinematic formulas.