Ordinary integrals are used in physics, while line integrals are used in chemistry.

Ordinary integrals are always single-variable, while line integrals are always multi-variable.

Ordinary integrals require parametric equations, while line integrals do not.

Ordinary integrals find the area under a curve, while line integrals find the area under a surface along a curve.

They convert the integral into a double integral.

They eliminate the need for derivatives in the integration process.

They simplify the calculation of the ds term in the integral.

They allow for the integration of multiple surfaces simultaneously.

y = x/2

y = 4x^2

y = 2x

y = x^2

It simplifies the expression for f(x, y).

It eliminates the need for parametric equations.

It converts the integral into a double integral.

It changes the variable of integration from t to u.

By splitting the curve into separate pieces for integration.

By using double integrals instead.

By ignoring the parametric equations.

By converting the curve into a straight line.

root[(dx/dt)^2 + (dy/dt)^2]dt

root[(dy/dt)^2 + (dz/dt)^2]dt

root[(dx/dt)^2 + (dy/dt)^2 + (dz/dt)^2]dt

root[(dx/dt)^2 + (dz/dt)^2]dt

The perpendicular component of the vector field to the curve.

The tangential component of the vector field along the curve.

The total area under the vector field.

The total volume under the vector field.