Rate of Change of Volume Calculator

Select Geometric Shape: Sphere (e.g., expanding balloon) Cube (e.g., melting ice cube) Cylinder (Fixed Radius, changing Height)

Current Radius (r):

Rate of Change of Radius (dr/dt):

Current Side Length (s):

Rate of Change of Side (ds/dt):

Constant Radius (r):

Rate of Change of Height (dh/dt):

Result

cubic units per time unit

Understanding the Rate of Change of Volume

In calculus, specifically when dealing with related rates, we often need to determine how the volume of an object changes over time (denoted as dV/dt) based on how its dimensions are changing. This concept is fundamental in physics, engineering, and fluid dynamics.

Common Mathematical Formulas

The rate of change is found by taking the derivative of the volume formula with respect to time (t) using the chain rule.

Sphere: If $V = \frac{4}{3}\pi r^3$, then $\frac{dV}{dt} = 4\pi r^2 \frac{dr}{dt}$.
Cube: If $V = s^3$, then $\frac{dV}{dt} = 3s^2 \frac{ds}{dt}$.
Cylinder: If $V = \pi r^2 h$ and the radius is constant, then $\frac{dV}{dt} = \pi r^2 \frac{dh}{dt}$.

Real-World Example

Imagine a spherical balloon being inflated. If the radius is currently 10 cm and is increasing at a rate of 2 cm/s, how fast is the volume increasing?

Identify $r = 10$ and $dr/dt = 2$.
Apply the formula: $dV/dt = 4 \times \pi \times (10)^2 \times 2$.
$dV/dt = 4 \times \pi \times 100 \times 2 = 800\pi$.
The volume is increasing at approximately 2,513.27 cm³/s.

Why This Matters

Calculating the rate of volume change is critical for determining how fast a tank fills, how quickly a glacier melts, or the rate at which pressure changes in a combustion chamber. Using this calculator, you can instantly find the derivative of volume for common shapes without manually performing the differentiation.