Where E<span> is the region that </span>lies<span> inside the cylinder </span><span>x2</span><span> + y</span>2<span> = 16 and between the planes. </span>z<span> = ?</span>4<span>. and. </span>z<span> = 6.</span>Use cylindrical coordinates<span>. </span>Evaluate<span>. (x + y + </span>z<span>) </span>dV<span>. iiintegral.gif. </span>E<span>. ,. where </span>E<span> is the </span>solid<span> in the </span>first octant<span> that </span>lies<span> under the </span>paraboloid<span>. </span>z<span> = 9 ? </span><span>x2</span><span> ? </span><span>y2</span><span>. Show transcribed image text </span>Use cylindrical coordinates<span>.</span>
Step-by-step explanation:
for that we use Pythagoras, as the distance is always the baseline (Hypotenuse) of a right-angled triangle created by the x and y coordinate differences between the 2 points.
15.
distance² = (8-3)² + (9-2)² = 5² + 7² = 25 + 49 = 74
distance = sqrt(74) = 8.602325267...
16.
we need to write down the point coordinates first :
(-4, 3)
(1, -3)
distance² = (1 - -4)² + (-3 - 3)² = 5² + (-6)² = 25 + 36 = 61
distance = sqrt(61) = 7.810249676...
You just need to make a line with the most dots that you can. Make the most dots you can fit on one line from the 0 to the end of the graph diagonally and fit as many points as you can. <span />
Answer:
108
Step-by-step explanation:
- Base+Base÷2 × height
- 10+7+7=10+14
- 24÷2=12
- 12×9=108
Well 8÷2=4. So half of 8 would be 4
