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3.2: Double Integrals Over Rectangular Regions
https://math.libretexts.org/Courses/Oxnard_College/Multivariable_Calculus/03%3A_Multiple_Integration/3.02%3A_Double_Integrals_Over_Rectangular_Regions
The volume of a thin rectangular box above $R_{ij}$ is $f(x_{ij}^*, \, y_{ij}^*)\,\Delta A$ , where ( $x_{ij}^*, \, y_{ij}^*$ ) is an arbitrary sample point in each $R_{ij}$ as shown in the follo...The volume of a thin rectangular box above $R_{ij}$ is $f(x_{ij}^*, \, y_{ij}^*)\,\Delta A$ , where ( $x_{ij}^*, \, y_{ij}^*$ ) is an arbitrary sample point in each $R_{ij}$ as shown in the following figure, $f(x_{ij}^*, \, y_{ij}^*)$ is the height of the corresponding thin rectangular box, and $\Delta A$ is the area of each rectangle $R_{ij}$ .
Section 14.1: Double Integrals Over Rectangular Regions
https://math.libretexts.org/Courses/Al_Akhawayn_University/MTH2301_Multivariable_Calculus/14%3A_Multiple_Integration/14.01%3A_Double_Integrals_Over_Rectangular_Regions
The volume of a thin rectangular box above $R_{ij}$ is $f(x_{ij}^*, \, y_{ij}^*)\,\Delta A$ , where ( $x_{ij}^*, \, y_{ij}^*$ ) is an arbitrary sample point in each $R_{ij}$ as shown in the follo...The volume of a thin rectangular box above $R_{ij}$ is $f(x_{ij}^*, \, y_{ij}^*)\,\Delta A$ , where ( $x_{ij}^*, \, y_{ij}^*$ ) is an arbitrary sample point in each $R_{ij}$ as shown in the following figure, $f(x_{ij}^*, \, y_{ij}^*)$ is the height of the corresponding thin rectangular box, and $\Delta A$ is the area of each rectangle $R_{ij}$ .
4.2: Double Integrals Over Rectangular Regions
https://math.libretexts.org/Courses/Coastline_College/Math_C280%3A_Calculus_III_(Everett)/04%3A_Multiple_Integration/4.02%3A_Double_Integrals_Over_Rectangular_Regions
The volume of a thin rectangular box above $R_{ij}$ is $f(x_{ij}^*, \, y_{ij}^*)\,\Delta A$ , where ( $x_{ij}^*, \, y_{ij}^*$ ) is an arbitrary sample point in each $R_{ij}$ as shown in the follo...The volume of a thin rectangular box above $R_{ij}$ is $f(x_{ij}^*, \, y_{ij}^*)\,\Delta A$ , where ( $x_{ij}^*, \, y_{ij}^*$ ) is an arbitrary sample point in each $R_{ij}$ as shown in the following figure, $f(x_{ij}^*, \, y_{ij}^*)$ is the height of the corresponding thin rectangular box, and $\Delta A$ is the area of each rectangle $R_{ij}$ .
4.2: Double Integrals Over Rectangular Regions
https://math.libretexts.org/Courses/Coastline_College/Math_C280%3A_Calculus_III_(Tran)/04%3A_Multiple_Integration/4.02%3A_Double_Integrals_Over_Rectangular_Regions
The volume of a thin rectangular box above $R_{ij}$ is $f(x_{ij}^*, \, y_{ij}^*)\,\Delta A$ , where ( $x_{ij}^*, \, y_{ij}^*$ ) is an arbitrary sample point in each $R_{ij}$ as shown in the follo...The volume of a thin rectangular box above $R_{ij}$ is $f(x_{ij}^*, \, y_{ij}^*)\,\Delta A$ , where ( $x_{ij}^*, \, y_{ij}^*$ ) is an arbitrary sample point in each $R_{ij}$ as shown in the following figure, $f(x_{ij}^*, \, y_{ij}^*)$ is the height of the corresponding thin rectangular box, and $\Delta A$ is the area of each rectangle $R_{ij}$ .
14.2a: Double Integrals Over Rectangular Regions
https://math.libretexts.org/Courses/El_Centro_College/MATH_2514_Calculus_III/Chapter_14%3A_Multiple_Integration/14.2a%3A_Double_Integrals_Over_Rectangular_Regions
The volume of a thin rectangular box above $R_{ij}$ is $f(x_{ij}^*, \, y_{ij}^*)\,\Delta A$ , where ( $x_{ij}^*, \, y_{ij}^*$ ) is an arbitrary sample point in each $R_{ij}$ as shown in the follo...The volume of a thin rectangular box above $R_{ij}$ is $f(x_{ij}^*, \, y_{ij}^*)\,\Delta A$ , where ( $x_{ij}^*, \, y_{ij}^*$ ) is an arbitrary sample point in each $R_{ij}$ as shown in the following figure, $f(x_{ij}^*, \, y_{ij}^*)$ is the height of the corresponding thin rectangular box, and $\Delta A$ is the area of each rectangle $R_{ij}$ .
14.2a: Double Integrals Over Rectangular Regions
https://math.libretexts.org/Courses/University_of_California_Irvine/MATH_2E%3A_Multivariable_Calculus/Chapter_14%3A_Multiple_Integration/14.2a%3A_Double_Integrals_Over_Rectangular_Regions
The volume of a thin rectangular box above $R_{ij}$ is $f(x_{ij}^*, \, y_{ij}^*)\,\Delta A$ , where ( $x_{ij}^*, \, y_{ij}^*$ ) is an arbitrary sample point in each $R_{ij}$ as shown in the follo...The volume of a thin rectangular box above $R_{ij}$ is $f(x_{ij}^*, \, y_{ij}^*)\,\Delta A$ , where ( $x_{ij}^*, \, y_{ij}^*$ ) is an arbitrary sample point in each $R_{ij}$ as shown in the following figure, $f(x_{ij}^*, \, y_{ij}^*)$ is the height of the corresponding thin rectangular box, and $\Delta A$ is the area of each rectangle $R_{ij}$ .
14.2a: Double Integrals Over Rectangular Regions
https://math.libretexts.org/Under_Construction/Purgatory/Remixer_University/Username%3A_pseeburger/MATH_223_Calculus_III/Chapter_14%3A_Multiple_Integration/14.2a%3A_Double_Integrals_Over_Rectangular_Regions
The volume of a thin rectangular box above $R_{ij}$ is $f(x_{ij}^*, \, y_{ij}^*)\,\Delta A$ , where ( $x_{ij}^*, \, y_{ij}^*$ ) is an arbitrary sample point in each $R_{ij}$ as shown in the follo...The volume of a thin rectangular box above $R_{ij}$ is $f(x_{ij}^*, \, y_{ij}^*)\,\Delta A$ , where ( $x_{ij}^*, \, y_{ij}^*$ ) is an arbitrary sample point in each $R_{ij}$ as shown in the following figure, $f(x_{ij}^*, \, y_{ij}^*)$ is the height of the corresponding thin rectangular box, and $\Delta A$ is the area of each rectangle $R_{ij}$ .

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