Evaluate ∫C ydx + xdy, where C is a path with initial point (0, 0) and terminal point (1, 1).

Question

Evaluate [latex]\int_{C} y d x+x d y[/latex], where [latex]C[/latex] is a path with initial point [latex](0,0)[/latex] and terminal point [latex](1,1)[/latex].

Accepted Answer

The path [latex]C[/latex] shown in FIGURE 9.9.2 represents any piecewise-smooth curve with initial and terminal points [latex](0,0)[/latex] and [latex](1,1)[/latex]. We have just seen that [latex]\mathrm{F}=y \mathrm{i}+x \mathrm{j}[/latex] is a conservative vector field defined at each point of the [latex]x y[/latex]-plane and that [latex]\phi(x, y)=x y[/latex] is a potential function for [latex]\mathrm{F}[/latex]. Thus, in view of (2) of Theorem 9.9.1 and (3), we can write

[latex]\int_C F \cdot d r =\int_C abla \phi \cdot d r =\phi(B)-\phi(A),[/latex] (2)

[latex]\int_A^B F \cdot d r =\int_A^B abla \phi \cdot d r .[/latex] (3)

[latex] \begin{aligned} \int_{C} y d x+x d y & =\int_{(0,0)}^{(1,1)} \mathrm{F} \cdot d \mathrm{r}=\int_{(0,0)}^{(1,1)} abla \phi \cdot d \mathrm{r} \ & =x y\bigg]_{(0,0)}^{(1,1)} \ & =1 \cdot 1-0 \cdot 0=1 . \end{aligned} [/latex]

Question 9.9.3: Evaluate ∫C ydx + xdy, where C is a path with initial point ......

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