Calculus III:

Triple integrals in caresian coordinates

The formula for the general triple integrals is:

∫∫∫_E f(x, y, z) dV where dV = dx dy dz

1. Triple integrals in caresian coordinates
over a box : rectangular regions

Consider the box E = B = [a,b] x [c,d] x [r,s], where are listed the x’s first, the y’s second and the z’s third.

The triple integral in this case is:

∫∫∫_B f(x, y, z) dV = ∫_r^s ∫_c^d ∫_a^b f(x, y, z) dx dy dz

Note that we integrated with respect to x first, we iterate then for y, and finally for z.

Notice that this order is not important. There are 6 different possible orders to do the integral and that give the same result regardless of the order. It is a matter of convenience and doing the calculus in the easiest manner.

2. Examples

Example 1

Conmpute ∫∫∫_B 24 x y z dV over the box B = [1,2] x [0,1] x [2,3].

The triple integral is:

∫∫∫_B f(x, y, z) dV = ∫₂³ ∫₀¹ ∫₁² 24 x y z dx dy dz =

24 ∫₂³ ∫₀¹ ∫₁² x dx y z dy dz = 24 ∫₂³ ∫₀¹ (x²/2)|₁² y z dy dz =

12 ∫₂³ ∫₀¹ (4 - 1) y z dy dz = 36 ∫₂³ ∫₀¹ y dy z dz =

18 ∫₂³ y²|₀¹ z dz = 18 ∫₂³ 1 z dz = 18 ∫₂³ z dz = 9 z²|₂³ =

9 (9 - 4) = 45 . Therefore

∫∫∫_B 12 x y z dV = 45

Example 2

Conmpute ∫∫∫_E dV over the box B = [a,b] x [c,d] x [r,s].

The triple integral is:

∫∫∫_EdV = ∫_r^s ∫_c^d ∫_a^b dx dy dz = (b - a)(d - c)(s - r). That is the volume of the box of sides (b - a), (d - c), and (s - r).

In the general case, the volume of the three-dimetional region E is given by:

V = ∫∫∫_E dV

3. Triple integrals in general three-dimensional regions

1. Along the z-axis

The region E is defined as :

E = {(x,y,z)|(x,y) ∈ D, u1(x,y) ≤ z ≤ u2(x,y)}

The triple integral is:

∫∫∫_E f(x,y,z) dV = ∫∫_D ∫_u1(x,y)^u2(x,y) f(x,y,z) dz dA

R(x,y) = ∫_u1(x,y)^u2(x,y) f(x,y,z) dz

The double integral ∫∫_D R(x,y) dA can be evaluated in any of the methods that we have seen.

Example 1

Compute ∫∫∫_E f(x, y, z) dV . Where E is the region under the plane 3x + 5y + z = 15 , that lies in the first octant.



The region D lies in the xy-plane. It is the triangle with vertices at (0,0), (5,0), and (0,3).

Here are the limits of integration:

The region E is located in the first octant. So it is above the plane z = 0.

0 ≤ z ≤ 15 - 3x - 5y

0 ≤ x ≤ 5
0 ≤ y ≤ - (3/5) x + 3

Or :

0 ≤ x ≤ - (5/3) y + 5
0 ≤ y ≤ 3

Therefore, the integral is:

∫∫∫_E f(x,y,z) dV = ∫∫_D ∫₀ ^{15 - 3x - 5y} f(x,y,z) dz dA

= ∫∫_D R(x,y) dA = ∫₀⁵ ∫₀^{- (3/5) x + 3} R(x,y) dy dx

= ∫₀⁵ Q(x) dx = Real value.

2. Along the x-axis

The region E is defined as :

E = {(x,y,z)|(y,z) ∈ D, u1(y,z) ≤ z ≤ u2(y,z)}

The triple integral is:

∫∫∫_E f(x,y,z) dV = ∫∫_D ∫_u1(y,z)^u2(y,z)) f(x,y,z) dz dA

R(y,z) = ∫_u1(y,z)^u2(y,z) f(x,y,z) dz

The double integral ∫∫_D R(y,z) dA can be evaluated in any of the methods that we have seen.

Example 2

Compute ∫∫∫_E dV . Where E is the region under the plane 2x + y + z = 8 , delimited by z = 3√y and z = 3y/2.



Here are the limits of integration:

3y/2 ≤ z ≤ 3√y
0 ≤ x ≤ (8 - y - z)/2
0 ≤ y ≤ 4

Therefore, the integral is:

∫∫∫_E dV = ∫∫_D ∫₀^{(8 - y - z)/2} dx dA

∫₀⁴ ∫_3y/2^3√y (8 - y - z)/2 dz dy = ∫₀⁴ R(y) dy

= Real value.

3. Along the y-axis

The region E is defined as :

E = {(x,y,z)|(x,z) ∈ D, u1(x,z) ≤ z ≤ u2(x,z)}

The triple integral is:

∫∫∫_E f(x,y,z) dV = ∫∫_D ∫_u1(x,z)^u2(x,z)) f(x,y,z) dy dA

= ∫∫_D R(x,z) dA

The double integral ∫∫_D R(x,z) dA can be evaluated in any of the methods that we have seen.

Example 3

Compute ∫∫∫_E f(x,y,z) dV . Where E is the solid bounded by y = 4x² + 4z², and the plane y = 8.



The disk at y = 8 has the equation: 4x² + 4y² = 8 → x² + z² = 2, then the radius of √2.

In polar coordiantes, we have: x = r cos θ z = r sin θ

Here are the limits of integration:

4x² + 4y² ≤ y ≤ 8
0 ≤ r ≤ √2
0 ≤ θ ≤ 2π

Therefore, the integral is:

∫∫∫E dV = ∫∫D ∫4x2 + 4y2 8 f(x,y,z) dy dA

∫₀ ^2Ï€ ∫₀ ^2√2 R(x,z) r dr dθ

= Real value.

 
Gnuplot: 

Example 1: 
---------- 
reset 
set ticslevel 0 
set grid 
set xtics 1
set ytics 1
set ztics  2
set hidden3d
set isosamples 30,30 
set xzeroaxis lt 2 lw 2
set yzeroaxis lt 2 lw 2 
set style line 3 lw 3 
set xrange [0:6]
set yrange [0:6] 
set zrange [0:16] 
set ylabel "Y"
set xlabel "X"
set zlabel "Z" 
splot (15 -  3*x - 5*y) lw 1 


Example 2: 
----------
reset 
set ticslevel 0 
set grid 
set xtics 1
set ytics 1
set ztics  1
set hidden3d
set isosamples 30,30 
set xzeroaxis lt 2 lw 2
set yzeroaxis lt 2 lw 2 
set style line 3 lw 3 
set xrange [0:6]
set yrange [0:4] 
set zrange [0:8] 
set ylabel "Y"
set xlabel "X"
set zlabel "Z" 
splot (8 - 2*x - y) ,  3*sqrt(y), 3*y/2 


Example 3: 
----------
reset 
set grid 
set xtics 1
set ytics 1
set ztics  1
set ticslevel 0 
set isosamples 80,40 
set xzeroaxis lt 2 lw 2
set yzeroaxis lt 2 lw 2 
set style line 3 lw 3 
set xrange [-2:2]
set yrange [0:8] 
set zrange [-6:6] 
set ylabel "Y"
set xlabel "X"
set zlabel "Z" 
splot sqrt(y - 4*x**2)/2, - sqrt(y - 4*x**2)/2