Differential And Integral Calculus By Feliciano And Uy Chapter 10 [ Pro ]
For current students facing Chapter 10 for the first time: the frustration is real, but so is the triumph. The chapter’s exercises are not busywork; they are mental push-ups. And when you finally solve that related rates problem — the one with the rotating lighthouse and the moving ship — you will have earned not just a correct answer, but a new way of seeing change itself.
Moreover, the chapter introduces — problem-solving strategies. For optimization, students are taught: 1) Draw a diagram. 2) Identify the quantity to be optimized. 3) Express it in terms of one variable. 4) Differentiate. 5) Test critical points. This recipe-like clarity is comforting to students who find pure mathematics intimidating. For current students facing Chapter 10 for the
Another strength is the chapter’s . Early exercises are straightforward: find the slope of the tangent to $y = x^3 - 3x$ at $x=2$. By the end of the problem set, students face multi-step optimization puzzles involving costs, revenues, and geometric constraints that mimic real engineering design challenges. The Infamous “Feliciano and Uy” Problem Sets Ask any Filipino engineer over 40 about Chapter 10, and they will likely grimace with a fond nostalgia. The unsolved exercises at the back of each subsection are legendary — not because they are impossible, but because they require translation from English to mathematics. Consider this classic optimization problem (paraphrased from memory of the 1980s edition): “A rectangular sheet of tin 12 inches by 8 inches has four equal squares cut from each corner. The flaps are then folded up to form an open box. Find the size of the square to be cut out so that the volume of the box is maximum.” The solution requires defining $x$ as the side of the square, expressing volume $V(x) = (12-2x)(8-2x)x$, differentiating, setting $V'(x)=0$, and checking the second derivative. Simple enough — but Feliciano and Uy often add a twist: “If the tin costs PhP 0.50 per square inch and the box is to be sold for PhP 15.00, is it profitable?” Suddenly, it’s not just calculus; it’s economics. 3) Express it in terms of one variable
As Feliciano and Uy themselves might say, at the end of the chapter’s answer key (printed in the back, always with just the final answers, no full solutions): “Now proceed to Chapter 11: The Definite Integral.” Because calculus, like learning, never truly ends — it only accumulates. Page numbers, exact problem statements, and subsection titles vary by edition (e.g., the 1978 SIBS Publishing edition vs. the 1990s reprints). However, the structure and spirit of Chapter 10 have remained remarkably consistent — a testament to the timeless pedagogy of Feliciano and Uy. in Chapter 4). Instead
The answer lies in what technology cannot do — at least not yet. A computer can differentiate $12x - 4x^2$, but it cannot look at a real-world scenario, identify the relevant variables, and translate the situation into a mathematical model. Chapter 10 trains exactly that skill: reading a word problem, drawing a diagram, defining variables, and setting up the equation. This is the essence of mathematical modeling , a skill invaluable in data science, engineering design, and operations research.
Veteran instructors often note that Chapter 10 is the point of the semester. Students who master its techniques rarely fail the final exam; those who struggle often repeat the course. As a result, review centers (like the famed MSA or Excel) devote entire sessions to Feliciano-and-Uy Chapter 10 problems, often reprinting them verbatim. Modern Relevance: Is Chapter 10 Still Useful in the Age of CAS? With computational algebra systems (CAS) like Wolfram Alpha, Symbolab, and even ChatGPT capable of solving any derivative and most optimization problems instantly, one might ask: is learning Chapter 10 still necessary?
The section is particularly feared. One problem might involve a lighthouse rotating its beam, a moving ship, and the speed of the light spot along a shore — requiring implicit differentiation with respect to time, the chain rule, and trigonometric substitution all at once. Pedagogical Philosophy: Why It Works Chapter 10 exemplifies a teaching philosophy that prioritizes application over abstraction . Feliciano and Uy were writing for students who would become practitioners — civil engineers calculating beam deflections, electrical engineers analyzing rates of change in circuits, business students finding break-even points. The chapter does not spend pages proving the Mean Value Theorem (that appears earlier, in Chapter 4). Instead, it shows how to use derivatives to solve a concrete problem.