The last BC question on the exams usually concerns sequences and series. The question usually asks students to write a **Taylor or Maclaurin series** and to answer questions about it and its** interval of convergence**, or about a related series found by differentiating or integrating. The topics may appear in other free-response questions and in multiple-choice questions. Questions about the convergence of sequences may appear as multiple-choice questions. With about 8 multiple-choice questions and a full free-response question this is one of the largest topics on the BC exams.

Convergence tests for series appear on both sections of the BC Calculus exam. In the multiple-choice section, students may be asked to say if a sequence or series converges or which of several series converge.

The Ratio test is used most often to determine the radius of convergence and the other tests to determine the exact interval of convergence by checking the convergence at the end points. Click here for a __convergence test chart__ students should be familiar with; this list is also on the resource page.

Students should be familiar with and able to write several terms and the general term of a Taylor or Maclaurin series. They may do this by finding the derivatives and constructing the coefficients from them, or they may produce the series by manipulating a known or given series. They may do this by substituting into a series, differentiating it or integrating it.

The general form of a **Taylor series** is ; if *a* = 0, the series is called a **Maclaurin series**.

**What Students Should be Able to Do**** **

- Use the various convergence tests to determine if a series converges. The test to be used is rarely given so students need to know when to use each of the common tests. For a summary of the tests click:
__Convergence test chart.__and the posts “What Convergence Test Should I use?” Part 1 and Part 2 - Understand absolute and conditional convergence. If the series of the absolute values of the terms of a series converges, then the original series is said to
*absolutely convergent*(or converges absolutely). If the series of absolute values diverges, then the original series may or may not converge; if it converges it is said to be*conditionally convergent*. - Write the terms of a Taylor or Maclaurin series by calculating the derivatives and constructing the coefficients of each term.
- Distinguish between the Taylor series for a function and the function.
**DO NOT**say that the Taylor polynomial is*equal*to the function (this will lose a point); say it is*approximately equal*. - Determine a specific coefficient without writing all the previous coefficients.
- Write a series by substituting into a known series, by differentiating or integrating a known series, or by some other algebraic manipulation of a series.
- Know (from memory) the Maclaurin series for sin(
*x*), cos(*x*),*e*and and be able to find other series by substituting into them.^{x} - Find the radius and interval of convergence. This is usually done by using the Ratio test and checking the endpoints.
- Be familiar with geometric series, its radius of convergence, and be able to find the number to which it converges, . Re-writing a rational expression as the sum of a geometric series and then writing the series has appeared on the exam.
- Be familiar with the harmonic and alternating harmonic series. These are often useful series for comparison.
- Use a few terms of a series to approximate the value of the function at a point in the interval of convergence.
- Determine the error bound for a convergent series (Alternating Series Error Bound and Lagrange error bound). See my posts on Error Bounds and the Lagrange Highway
- Use the coefficients (the derivatives) to determine information about the function (e.g. extreme values).

This list is quite long, but only a few of these items can be asked in any given year. The series question on the free-response section is usually quite straightforward. Topics and convergence test may appear on the multiple-choice section. As I have suggested before, look at and work as many past exam questions to get an idea of what is asked and the difficulty of the questions. Click on Power Series in the “Posts by Topic” list on the right side of the screen to see previous posts on Power Series or any other topic you are interested in.

Free-response questions:

- 2004 BC 6 (An alternate approach, not tried by anyone, is to start with )
- 2016 BC 4 (d) and BC 6
- 2016 BC 6
- 2017 BC 6

Multiple-choice questions from non-secure exams:

- 2008 BC 4, 12, 16, 20, 23, 79, 82, 84
- 2012 BC 5, 9, 13, 17, 22, 27, 79, 90,

- Tuesday February 27 – AP Exam Review
- Friday, March 2 – Resources for reviewing
- Tuesday March 6 – Type 1 questions – Rate and accumulation questions
- Friday March 9 – Type 2 questions – Linear motion problems
- Tuesday March 13 – Type 3 questions – Graph analysis problems
- Friday March 16 – Type 4 questions – Area and volume problems
- Tuesday Match 20 Type 5 questions – Table and Riemann sum questions
- Friday March 23 Type 6 questions – Differential equation questions
- Tuesday March 27 – Type 7 questions – miscellaneous
- Friday March 30 Type 8 questions – Parametric and vector questions (BC topic)
- Tuesday April 3 Type 9 questions – Polar equations (BC topic)
- Friday April 6 Type 10 questions – Sequences and Series (BC topic)(this post)

The concludes the series of posts on the type questions in review for the AP Calculus exams.