Students entering into upper-division physics courses are typically familiar and comfortable with integration as taught in mathematics courses. In physics, there is additional language and interpretation which accompany integration. By reintroducing integration early in upper-division courses, many common student difficulties which arise in electricity and magnetism and other physics courses can be addressed.
Students may be encountering new approaches to integration which are not addressed in math courses. For example, Internal Energy of the "Derivative Machine" may be the first time students have experimentally measured an integral and can be used to encourage fluency between multiple representations of integration such as numerical, graphical, and algebraic representations. Additionally, students typically integrate with respect to the variable of the function such as $x$ in $f(x)=\int_{x_0}^{x_f}(mx+b)dx$. However, oftentimes in physics the resulting function is of a different variable such as $g(m)=\int_{x_0}^{x_f}(mx+b)dx$ which students may not have encountered in previous calculus and introductory physics courses.
This sequence can serve as a quick reintroduction to integration and can likely be completed entirely in less than one hour.