Evaluate
The radical term in the denominator is a hint for trigonometric substitution. However, this problem requires first a clever factoring manipulation and algebraic substitution before trigonometric substitution can be employed.
Let
Another substitution
From
the illustration below follows.
...
Monday, November 23, 2009
Thursday, November 12, 2009
Partial fractions
I already finished the contents of my workbook X and Why: Integration Techniques. I am now in the reproduction stage. While waiting for the finished product, let me present some of its contents.
Solve the following:
a)
b)
The problems look easy. Indeed, they are. So, how do we solve these?
For me, the basic step is to examine the function. There are several integration techniques but in these problems, it should be obvious that trigonometric integration, trigonometric substitution and integration by parts are not applicable. Why? The answer lies in the nature of the function in the given problems.
The power formula will not work because we cannot split these expressions to produce a function matching its derivative. Algebraic substitution will not work because the expressions are already simplified. The other option, which turns out to be applicable, is integration using partial fractions.
For a, note the like powers for numerator and denominator, so divide first. The first term in the answer should be obvious.
For b, there are non-repeating linear factors.
Easy.
...
Reference: [4]
Solve the following:
a)
b)
The problems look easy. Indeed, they are. So, how do we solve these?
For me, the basic step is to examine the function. There are several integration techniques but in these problems, it should be obvious that trigonometric integration, trigonometric substitution and integration by parts are not applicable. Why? The answer lies in the nature of the function in the given problems.
The power formula will not work because we cannot split these expressions to produce a function matching its derivative. Algebraic substitution will not work because the expressions are already simplified. The other option, which turns out to be applicable, is integration using partial fractions.
For a, note the like powers for numerator and denominator, so divide first. The first term in the answer should be obvious.
For b, there are non-repeating linear factors.
Easy.
...
Reference: [4]
Tuesday, October 13, 2009
Integration Techniques: Problems 2.1.27.23 and 2.1.29.23
Obtain the general solution for the following problems:
2.1.27.23]
2.1.29.23]
Obviously, trigonometric identities will come into play here. Problems like these will be covered in the integration techniques workshop.
...
Reference: [5]
2.1.27.23]
2.1.29.23]
Obviously, trigonometric identities will come into play here. Problems like these will be covered in the integration techniques workshop.
...
Reference: [5]
Labels:
calculus,
integration techniques
Mathematics
Mathematics is made of 50 percent formulas, 50 percent proofs, and 50 percent imagination.
...
Reference: [7]
...
Reference: [7]
Sunday, October 11, 2009
Integration Techniques: Problem 3.17.21
Problem 3.17.21] Solve
This is one of the problems which looks intimidating because of its form. A simple technique can solve this although one approach is superior than the other.
We'll solve this in the workshop.
...
Reference: [6]
This is one of the problems which looks intimidating because of its form. A simple technique can solve this although one approach is superior than the other.
We'll solve this in the workshop.
...
Reference: [6]
Labels:
calculus,
integration techniques
Thursday, October 8, 2009
Book: Fermat's Last Theorem
This is an immensely enjoyable treasure.
[image source: Amazon.com. 2009. Fermat's Last Theorem. http://ecx.images-amazon.com/images/I/51WX45QBQBL._SL500_AA240_.jpg. Last accessed: Oct 9, 2009.]
...
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