Integral Calculus Reviewer By Ricardo Asin Pdf 54 Today
The valve is at (y = 3). A slice at position (y) must be lifted vertically from (y) up to 3. Distance = (3 - y).
Thus: [ \int_-3^0 y\sqrt9-y^2,dy = -9. ] So minus that term: ( -\int_-3^0 y\sqrt9-y^2 , dy = -(-9) = +9).
I’m unable to provide a direct PDF file or a specific page (like “page 54”) from Ricardo Asin’s Integral Calculus Reviewer , as that would likely violate copyright laws. However, I can offer you an original, illustrative story inspired by the kind of integral calculus problem you might find on such a page—complete with a worked-out solution in the spirit of Asin’s teaching style. Inspired by typical problems on page 54 of many integral calculus reviewers—specifically, “Applications: Work Done in Pumping Liquid.”
[ dW = \textforce \times \textdistance = 196000\sqrt9-y^2 \cdot (3 - y) , dy. ] Integral Calculus Reviewer By Ricardo Asin Pdf 54
He grabbed a notebook. Page 54 of his old reviewer flashed in his mind—a similar problem with a horizontal cylinder.
He placed the center of the circular cross-section at (0,0). The circle’s equation: (x^2 + y^2 = 9). The tank’s length (into the page) was 10 m. The valve was at the top of the circle, at (y = 3).
Therefore: [ W = 196000 \left( \frac27\pi4 + 9 \right) \quad \textJoules. ] The valve is at (y = 3)
The water filled from the bottom ((y = -3)) up to the center line ((y = 0)), so half-full.
Split it: [ W = 196000 \left[ 3\int_-3^0 \sqrt9-y^2 , dy ;-; \int_-3^0 y\sqrt9-y^2 , dy \right]. ]
Weight of the slice = volume × density of water (1000 kg/m³ × 9.8 m/s² = 9800 N/m³): [ dF = 9800 \cdot 20\sqrt9-y^2 , dy = 196000\sqrt9-y^2 , dy \quad \text(Newtons). ] Thus: [ \int_-3^0 y\sqrt9-y^2,dy = -9
First integral: (\int \sqrt9-y^2, dy) is a standard semicircle area formula. From (y=-3) to (0), it’s a quarter circle of radius 3. Area of quarter circle = (\frac14\pi (3^2) = \frac9\pi4). So (3 \times \frac9\pi4 = \frac27\pi4).
[ W = 196000 \int_-3^0 (3 - y)\sqrt9-y^2 , dy. ]
Rico remembered Ricardo Asin’s golden rule: “For work problems, slice it, find the force on each slice, multiply by the distance that slice travels, then integrate.”