First-Order Differential Equations

The simplest DEs — yet they model population growth, cooling, and mixing.

What Is a Differential Equation?

rLfiLbNuRzvqUY0X6hAh2hUVHlUAofVa0B33uFYFqyTBESHF65OjXKrVMg819F8dTYY/o5oohtlAIQ1qBGGAAy2dVE6jvrHrg9tZkQfMBdo+jrnBFaLyMJ0/2YOoykYy2pJYPMwucxk3hogO1kQSL70/7EAK1ewuZU5LI6j7QF/DSqZcPLtmfyIyhGSw6dOj5P1+ixEtl+0bwFersSefUqZcg/oBo1Hz98jRIjxK0eoLSTvCsuXU2SFo1jXoUD3Bmc+SNEaEtJ1Ah32uXs7uzzHbHLjh2iMruLDDSsqeB7J8avM4BWxCvqDLSAVNCBNEkzymc9UL6W2k3VvWlGKLf8z9ZBcI7xPfURzN+8nl/FwT58QhN8tErdqQprHys5Y5EkrS1U+4sGDLyIU8yAs5eKgmuN6ru0pzpdVSmLF7c3QdvnBgvZeJtiW5QA5RQnN5AyVoV7sPxsK2BEF3/WwFiXTexseQM3WPIG1FP3es6dhTb92OW8mtqtDVjbnUGd2FoMskuuRO/yfafJ6ORkX+mS1VptplSryssg3xPCJrGHNl9UuEmeG7cvc4reFkEoBuNS1Oodp6qOSL+HPwSf7gMlJ3863DQBfceUHTLLC5GkSCh+Iva4Z9Oy1dGeQ2Yu3AzAwktm61b+x0I24W8V0TVIH2ArBZ5U3BDaj7Wxpl2rSScnZOFPciHnst0N2SIYVOdxqJphGXVPt1IKYsPtztG92FAcVuuDJu0moFuLotvu5GZXoOJUNzzoozov+yJ5gOREHzjph+qZXbd93aSu4JSdN3QiAm4DF7RjDgPFN5u81vL4q3o4uiy7XD9D/i3RWrICg60LS5o/oxH13iKQYlAjaLe+9O4Egpl4I4to5BGi31PCmcUHJSwR+6LVK+JBt6wrFkT3KvIsVzzgZ/2Miyzl5ZyCodoPHJfHmBPIZ6QCJol5eRdOqBI0YyWDQMiomygS9cjLXelICzyZU6ZFY2vzIRUZ

A DE is an equation involving a function and its derivatives. The order is the highest derivative present. A first-order DE has the form dy/dx = f(x, y).

General form: F(x, y, y') = 0
Solution: a function y = φ(x) satisfying the equation
General solution: family of solutions with arbitrary constant C
Particular solution: satisfies an initial condition y(x₀) = y₀

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

Separable Equations

Form: dy/dx = g(x)·h(y)
Method: (1/h(y)) dy = g(x) dx → integrate both sides

Example: dy/dx = xy

(1/y) dy = x dx → ln|y| = x²/2 + C → y = Ae^(x²/2)

Uses integration and exponential functions.

First-Order Linear

Form: dy/dx + P(x)y = Q(x)
Integrating factor: μ(x) = e^(∫P(x)dx)
Solution: y = (1/μ) ∫ μ·Q dx

The integrating factor technique converts a non-separable DE into an exact derivative. This method uses the product rule in reverse and relies on integration techniques.

Exact Equations

Form: M(x,y)dx + N(x,y)dy = 0
Exact if: ∂M/∂y = ∂N/∂x
Solution: find F where ∂F/∂x = M and ∂F/∂y = N; then F(x,y) = C

Exactness connects to partial derivatives and conservative vector fields. Non-exact equations can sometimes be made exact with an integrating factor.

Applications

_{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}

Exponential growth/decay: dy/dt = ky → y = y₀eᵏᵗ (population, radioactive decay)
Newton's cooling: dT/dt = −k(T − Tₐ) → T = Tₐ + (T₀ − Tₐ)e⁻ᵏᵗ
Mixing problems: Rate in − rate out → first-order linear DE
Logistic growth: dP/dt = rP(1 − P/K) → S-shaped curve — uses partial fractions to integrate

First-order DEs appear in every scientific field. In systems of DEs, x' = Ax, eigenvalues determine whether solutions grow, decay, or oscillate. In probability, the exponential distribution's memoryless property comes from the DE: f'(t) = −λf(t).

← Back toDE Overview Next Lesson →Second-Order DEs

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