Mathematics 311 Homepage
Fall 2024 University of Nevada Reno
311 INTRODUCTION TO ANALYSIS I (3+0) 3 credits
Continuation of MATH 310. Emphasizes proving theorems about series, uniform convergence, functions of several variables: limits, continuity, differentiation, extrema, integration, implicit and inverse function theorems.
Prerequisite(s): MATH 310 with a "C" or better. Corequisite(s): MATH 330.
Instructor Course Section Time
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Eric Olson 1001 Math 311 INTRO TO ANALYSIS II MWF 10:00-10:50am AB206
Course Information
- Instructor:
- Eric Olson
- email:
- Please contact me through WebCampus
- Office:
- DMS 238 MWF from 11am to noon
- Homepage:
- https://fractal.math.unr.edu/~ejolson/311/
- Live Stream:
- If you can't come to class due to sickness, quarantine or other reasons,
please join via the Zoom link in WebCampus.
- Primary Texts:
- Gerald Folland, Advanced Calculus, Second Edition, Pearson.
(pdf)
- Other Reading:
- Eric's
Lecture notes from Math 310, Spring 2024.
- Frank Dangello, Michael Syfried, Introductory Real Analysis,
Houghton Mifflin Company, 2000.
- Joseph Taylor, Foundations of Analysis, Twelfth Edition, American
Mathematical Society, 2012.
- Jay Cummings, Real Analysis, A Long-Form Mathematics Textbook, 2019.
- Walter Rudin, Principles of Mathematical Analysis, Third Edition,
McGraw-Hill, 1976.
- Robert C. Wrede, Murray Spiegel, Schaum's Outline of
Advanced Calculus, Second Edition, McGraw-Hill.
Student Learning Outcomes
Upon completion of this course, students will be able to
- Write cogent proofs using different methods like direct proof, indirect proof, proof by contradiction, proof by induction.
- Demonstrate an understanding of the algebraic structure and the topology of Euclidean space.
- Apply theorems about differentiability and integrability of vector functions of several variables.
- Test infinite series for convergence.
Class Handouts
Course materials specific for this section of Math 311 are available
by clicking on this link. Details for how to
access these files may be found on our course page in WebCampus.
Homework
- HW1 due Sept 13 (solutions)
- Turn in (page 33) 1.6#4
- Practice (page 29) 1.5#5, 1.5#7, (page 33) 1.6#1ab, 1.6#6, (page 38) 1.7#6, 1.7#8
- HW2 due Sept 27 (solutions)
- Turn in (page 74) 2.3#2abc
- Practice (page 41) 1.8#4, 1.8#5, (page 52) 2.1#2, 2.1#9, (page 61-62) 2.2#1abc, 2.2#8, (page 77) 2.5#5
- HW3 due Oct 4 (solutions)
- Turn in (page 84) 2.6#10
- Practice (page 41) 1.8#1, (page 84) 2.6#2, 2.6#11, (page 94-95) 2.7#5, 2.7#10 (page 100) 2.8#2
- HW4 due Nov 1 (solutions)
- Turn in (page 133) 3.3#5ab
- Practice (page 119) 3.1#2, (page 125) 3.2#4, (page 139) 3.4#4abcde
- HW5 due Nov 15 (solutions)
- Turn in (page 167) 4.2#7
- Practice (page 158) 4.1#6, (page 167) 4.2#3,4,5 (page 176) 4.3#5abc
Quizzes
Lecture Notes
Announcements
[12-Dec-2024] Sample Final Exam
Here is a sample final to help you
study for the exam on Friday.
[13-Dec-2024] Final Exam
The final exam is Friday, December 13 from
10:15am-12:15pm in AB206. The exam is cumulative. Here is a
list of topics to help you review for the exam.
- Everything on the review for the Midterm.
- Material from all homework assignments and quizzes.
- The following additional definitions:
- A smooth curve (page 123)
- A partition and a refinement of a partition (page 148)
- Upper and lower Rieman sums (page 148)
- Upper and lower integrals (page 149)
- A set of zero content (page 154 and 161)
- Characteristic or indicator function χS (page 160)
- A set to be Jordan measurable (page 162)
- 5.7 Line integral of a scalar function (page 215)
- 5.9 Scalar-valued line integral of a vector field (page 217)
- Rectifiable curve (page 219)
- x-simple, y-simple and simple regions (page 223)
- Statement without poof of the additional theorems:
- 3.9 The Implicit Function Theorem for
Systems (page 118)
- 3.18 The Inverse Mapping Theorem (page 137)
- 4.26 Fubini's Theorem on Iterated Integrals (page 169)
- 4.41 Change of Variables for Multiple Integrals (page 183)
- 5.12 Green's Theorem General Statment (page 223)
- 6.19 Rearrangment of Absolutely Convergent (page 298)
- 6.19 Rearrangment of Conditionally Convergent (page 298)
- Proofs of the following additional theorems:
- 3.1 Implicit Function Theorem for
One Equation (page 114)
- 4.10 Bounded Monotone Functions are Integrable (page 152)
- 4.11 Continuous Functions are Integrable (page 152)
- 4.15 The Fundamental Theorem of Calculus (page 155)
- 4.24 The Mean Value Theorem for Integrals (page 166)
- 5.11 C1 Curves are Rectifiable (page 220)
- 5.12 Green's proof for a Simple Region (page 223)
- 6.3 Geometric Series Formula (page 281)
- 6.8 The Integral Test (page 285)
- 6.9 The p test for ∑1∞ n−p (page 286)
- 6.12 The Limit Comparison Test (page 288)
- 6.13 The Ratio Test (page 289)
- 6.14 The Root Test (page 290)
- 6.17 Absolute Convergent implies Convergent (page 295)
[9-Dec-2024] Quiz 5
There is a quiz Monday, December 9 in class. Please know the
statement of Corollary 6.8 The Integral Test on page 285 in the text.
Also review problems 6.2#2 and 6.2#5 on page 293 to test the series
∑1∞ n e−n and
∑0∞ (2n+1)3n/(3n+1)2n
for convergence. Note the back side of your quiz paper will include
the statements of Theorems 6.9, 6.11, 6.12, 6.13 and 6.14 for reference.
[6-Dec-2024] Quiz 4
There is a quiz Friday, December 6 in class. Please know the
statement of Theorem 5.12 Green's Theorem on page 223 in the text.
Also review problem 5.2#3 on page 228 find the positively oriented
simple closed curve C that maximizes the line
integral
∫C[y3dx + (3x−x3)dy].
Note that the way I did problem 5.2#3 was to apply Green's Theorem
and then switch to polar coordinates. There may be other ways.
[4-Dec-2024] Quiz 3
There is a quiz Wednesday, December 4 in class. Please know the
statement of Theorem 3.9 The Implicit Function Theorem for a System
of Equations on page 118 in the text.
Also review problem 3.1#5 on page 120 suppose F(x,y) is a C1
function such that F(0,0)=0. What conditions on F will guarantee that
the equation F(F(x,y),y)=0 can be solved for y as a
C1 function of x near (0,0)?
[2-Dec-2024] Quiz 2
There is a quiz Monday, December 2 in class. Please know the
definition of the line integral of a scalar function as given
by (5.7) on page 215 from the text.
Also review problem 5.1#4 on page 221 to compute
∫C √z ds where C is parametrized
by g(t)=(2 cos t, 2 sin t, t2) with 0 ≤ t ≤ 2π.
[27-Nov-2024] Quiz 1
There is a quiz Friday, November 27 in class. Please know the
statement of Theorem 4.41 The Change of Variables Formula
for multi-dimensional integrals.
[8-Oct-2024] Sample Midterm
I have created a sample midterm to
help you study for the in-class exam on Friday.
[7-Oct-2024] Homework 3 Solutions
I have posted my solutions to
Homework 3 to help you study.
[11-Oct-2024] Midterm
The midterm will be Friday October 11. Here is a list of topics
to help you prepare for the exam.
- Material from HW1, HW2 and HW3.
- The following definitions:
- The open ball B(r,a) of radius r about a.
- An interior point and a boundary point.
- A bounded set, a convex set and a compact set.
- A connected set and a disconnected set.
- A function f to be of class Ck.
- Multi-index notation.
- The definition of derivative for f:Rn→R.
- The definition of derivative for F:Rn→Rm.
- Statement without proof of the following theorems:
- Taylor's theorem in Rn using multi-index notation.
- Bolzano-Weierstrass theorem in Rn.
- The Heine-Borel Theorem in Rn.
- Spectral theorem for symmetric H in Rn×n.
- The chain rule for f(g(t)) where f:Rn→R
and g:R→Rn.
- The conditions on ∂jf
that imply f is differentiable at a.
- Proofs of the following theorems:
- Every bounded monotone sequence in R is convergent.
- Bolzano-Weierstrass theorem in Rn.
- A continuous function on a compact set is uniformly continuous.
- A continuous function on a compact set attains its maximum.
- If S is connected and f continuous then f(S) is connected.
- If S is open and connected then S is arcwise connected.
[6-Oct-2024] Homework 2 Solutions
I have posted my solutions to
Homework 2 to help you study.
[24-Sep-2024] Homework 1 Solutions
I have posted my solutions to
Homework 1 to help you study.
[19-Jan-2024] Welcome Fall 2024
I am looking forward to seeing you starting the first week of class.
This section of Math 311 is in person.
I will maintain an online archive of course materials including
lecture notes, assignments and other announcements in case you
miss a class or want to compare your notes.
Tentative Course Schedule
# Date Chapter Topic
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1 Aug 26 1.5 Completeness
2 Aug 28 1.5 Bolzano Weierstrass Theorems
3 Aug 30 1.6 Compactness
Sep 02 *** Labor Day
4 Sep 04 1.7 Connectedness
5 Sep 06 1.8 Uniform Continuity
6 Sep 09 2.1 Differentiability in One Variable
7 Sep 11 2.2 Differentiability in Several Variables
8 Sep 13 2.3 The Chain Rule
9 Sep 16 2.4 The MVT and Implicit Functions
10 Sep 18 2.5 Implicit Functions
11 Sep 20 2.6 Higher-Order Partial Derivatives
12 Sep 23 2.7 Taylor's Theorem
13 Sep 25 2.8 Critical Points
14 Sep 27 2.9 Extreme Values
15 Sep 30 2.10 Derivatives of Vector-Valued Functions
16 Oct 02 3.1 The Implicit Function Theorem
17 Oct 04 3.2 Curves in the Plane
18 Oct 07 3.2 Curves in the Plane (continued)
19 Oct 09 3.3 Surfaces and Curves in Space
20 Oct 11 Midterm
21 Oct 14 3.4 Inverse Mapping Theorem
22 Oct 16 B.2 The Implicit Function Theorem
23 Oct 18 B.2 The Implicit Function Theorem (continued)
24 Oct 21 4.1 Integration on the Line
25 Oct 23 4.1 Integration on the Line (continued)
Oct 25 *** Nevada Day
26 Oct 28 4.2 Integration in Higher Dimensions
27 Oct 30 4.2 Integration in Higher Dimensions (continued)
28 Nov 01 4.2 The Mean Value Theorem for Integrals
29 Nov 04 4.4 Change of Variables on the Line
30 Nov 06 4.4 Change of Variables for Multiple Integrals
31 Nov 08 4.4 Matrix Transformations
Nov 11 *** Veteran's Day
32 Nov 13 5.1 Arc Length
33 Nov 15 B.4 Double and Iterated Integrals
34 Nov 18 5.1 Line Integrals
35 Nov 20 5.2 Green's Theorem
36 Nov 22 B.1 The Heine-Borel Theorem
37 Nov 25 B.7 Partitions of Unity
38 Nov 27 B.7 Proof of Green's Theorem
Nov 29 *** Thanksgiving Family Day
39 Dec 02 6.1/6.2 Infinite Series and Nonnegative Terms
40 Dec 04 6.3 Absolute and Conditional Convergence
41 Dec 06 6.4 More Convergence Tests
42 Dec 09 Review
*** Final exam Monday, Friday 13 from 10:15am-12:15pm in AB206
Grading
Midterm 100 points
5 Quizzes 5 points each
5 Homework Assignments 5 points each
Final Exam 100 points
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250 points total
Exams and quizzes will be interpreted according to the following
grading scale:
Grade Minimum Percentage
A 90 %
B 80 %
C 70 %
D 60 %
The instructor reserves the right to give plus or minus grades and
higher grades
than shown on the scale if he believes they are warranted.
Quiz and Exam Schedule
There will be two quizzes, a midterm and a final exam. In person
attendance is mandatory for all exams.
Course Policies
Communications Policy
Lectures and classroom activities will held in person.
If you wish to set up an appointment for office hours
please send me a message through
WebCampus.
I am available to meet in my office or through Zoom.
Late Policy
Students must have an approved university excuse to be eligible for a
make-up exam. If you know that you will miss a scheduled exam please
let me know as soon as possible.
Plagiarism
Students are encouraged to work in groups and consult resources outside
of the required textbook when doing the homework for this class. Please
cite any sources you used to complete your work including Wikipedia, other
books, online discussion groups as well as personal communications. Exams
and quizzes, unless otherwise noted, will be closed book, closed notes
and must reflect your own independent work. Please consult the section
on academic conduct below for additional information.
Diversity
This course is designed to comply with the UNR Core
Objective 10 requirement on diversity and equity. More information about
the core curriculum may be found in the UNR Catalog
here.
Statement on Academic Success Services
Your student fees cover usage of the University Math Center, University
Tutoring Center, and University Writing and Speaking Center. These
centers support your classroom learning; it is your responsibility to
take advantage of their services. Keep in mind that seeking help outside
of class is the sign of a responsible and successful student.
Equal Opportunity Statement
The University of Nevada Department of Mathematics and Statistics
is committed to equal opportunity in education
for all students, including those with documented physical disabilities
or documented learning disabilities. University policy states that it is
the responsibility of students with documented disabilities to speak
with the Disability Resource
Center during the first week of each semester to discuss appropriate
accommodations to ensure equity in grading, classroom experiences and
outside assignments.
For assistance with accessibility, or to report an issue,
please use the
Accessibility
Help Form. The form is set up to automatically route your request
to the appropriate office that can best assist you.
Statement on Audio and Video Recording
Surreptitious or covert video-taping of class or unauthorized audio
recording of class is prohibited by law and by Board of Regents
policy. This class may be videotaped or audio recorded only with the
written permission of the instructor. In order to accommodate students
with disabilities, some students may be given permission to record class
lectures and discussions. Therefore, students should understand that
their comments during class may be recorded.
Academic Conduct
Bring your student identification to all exams.
Work independently on all exams and quizzes.
Behaviors inappropriate to test taking may disturb other
students and will be considered cheating.
Don't send electronic messages, talk or pass notes with other
students during a quiz or exam.
Homework may be discussed freely.
When taking a quiz, midterm or exam
don't read notes or books unless explicitly permitted.
Sanctions for violations are specified in the
University Academic Standards Policy.
If you are unclear as to what constitutes cheating,
please consult with me.
Final Exam
The final exams will be held in person at the time listed in
the standard schedule of final exams for this section.
Namely, the final exam is Friday, December 13 from
10:15am-12:15pm in AB206.
Last Updated:
Mon Aug 26 09:16:11 AM PDT 2024