Difference between revisions of "BSc:Mathematical Analysis (Computer Engineering)"

= Mathematical Analysis I =

* <span>'''Course name:'''</span> Course Title

* <span>'''Course number:'''</span> BS-MA1

== Course Characteristics ==

=== Key concepts of the class ===

* Differentiation

* Integration

* Series

=== What is the purpose of this course? ===

This calculus course covers differentiation and integration of functions of one variable, with applications. The basic objective of Calculus is to relate small-scale (differential) quantities to large-scale (integrated) quantities. This is accomplished by means of the Fundamental Theorem of Calculus. Should be understanding of the integral as a cumulative sum, of the derivative as a rate of change, and of the inverse relationship between integration and differentiation.

This calculus course will provide an opportunity for participants to:

* understand key principles involved in differentiation and integration of functions

* solve problems that connect small-scale (differential) quantities to large-scale (integrated) quantities

* become familiar with the fundamental theorems of Calculus

* get hands-on experience with the integral and derivative applications and of the inverse relationship between integration and differentiation.

=== Course objectives based on Bloom’s taxonomy ===

=== - What should a student remember at the end of the course? ===

By the end of the course, the students should be able to ...

* Derivative. Differential. Applications

* Indefinite integral. Definite integral. Applications

* Sequences. Series. Convergence. Power Series

=== - What should a student be able to understand at the end of the course? ===

By the end of the course, the students should be able to ...

* Derivative. Differential. Applications

* Indefinite integral. Definite integral. Applications

* Sequences. Series. Convergence. Power Series

* Taylor Series

=== - What should a student be able to apply at the end of the course? ===

By the end of the course, the students should be able to ...

* Take derivatives of various type functions and of various orders

* Integrate

* Apply definite integral

* Expand functions into Taylor series

* Apply convergence tests

=== Course evaluation ===

{|

|+ Course grade breakdown

!

!

!align="center"| '''Proposed points'''

|-

| Labs/seminar classes

| 20

|align="center"|

|-

| Interim performance assessment

| 30

|align="center"|

|-

| Exams

| 50

|align="center"|

|}

If necessary, please indicate freely your course’s features in terms of students’ performance assessment.

=== Grades range ===

{|

|+ Course grading range

!

!

!align="center"| '''Proposed range'''

|-

| A. Excellent

| 90-100

|align="center"|

|-

| B. Good

| 75-89

|align="center"|

|-

| C. Satisfactory

| 60-74

|align="center"|

|-

| D. Poor

| 0-59

|align="center"|

|}

If necessary, please indicate freely your course’s grading features.

=== Resources and reference material ===

* Zorich, V. A. “Mathematical Analysis I, Translator: Cooke R.” (2004)

*

*

== Course Sections ==

The main sections of the course and approximate hour distribution between them is as follows:

{|

|+ Course Sections

!align="center"| '''Section'''

! '''Section Title'''

!align="center"| '''Teaching Hours'''

|-

|align="center"| 1

| Sequences and Limits

|align="center"| 28

|-

|align="center"| 2

| Differentiation

|align="center"| 24

|-

|align="center"| 3

| Integration and Series

|align="center"| 28

|}

=== Section 1 ===

==== Section title: ====

Sequences and Limits

=== Topics covered in this section: ===

* Sequences. Limits of sequences

* Limits of sequences. Limits of functions

* Limits of functions. Continuity. Hyperbolic functions

=== What forms of evaluation were used to test students’ performance in this section? ===

<div class="tabular">

<span>|a|c|</span> &amp; '''Yes/No'''<br />

Development of individual parts of software product code &amp; 1<br />

Homework and group projects &amp; 1<br />

Midterm evaluation &amp; 1<br />

Testing (written or computer based) &amp; 1<br />

Reports &amp; 0<br />

Essays &amp; 0<br />

Oral polls &amp; 0<br />

Discussions &amp; 1<br />

</div>

=== Typical questions for ongoing performance evaluation within this section ===

# A sequence, limiting value

# Limit of a sequence, convergent and divergent sequences

# Increasing and decreasing sequences, monotonic sequences

# Bounded sequences. Properties of limits

# Theorem about bounded and monotonic sequences.

# Cauchy sequence. The Cauchy Theorem (criterion).

# Limit of a function. Properties of limits.

# The first remarkable limit.

# The Cauchy criterion for the existence of a limit of a function.

# Second remarkable limit.

=== Typical questions for seminar classes (labs) within this section ===

# Find a limit of a sequence

# Find a limit of a function

=== Test questions for final assessment in this section ===

# Find limits of the following sequences or prove that they do not exist:

# <math display="inline">a_n=n-\sqrt{n^2-70n+1400}</math>;

# <math display="inline">d_n=\left(\frac{2n-4}{2n+1}\right)^{n}</math>;

# <math display="inline">x_n=\frac{\left(2n^2+1\right)^6(n-1)^2}{\left(n^7+1000n^6-3\right)^2}</math>.

=== Section 2 ===

==== Section title: ====

Differentiation

=== Topics covered in this section: ===

* Derivatives. Differentials

* Mean-Value Theorems

* l’Hopital’s rule

* Taylor Formula with Lagrange and Peano remainders

* Taylor formula and limits

* Increasing / decreasing functions. Concave / convex functions

=== What forms of evaluation were used to test students’ performance in this section? ===

<div class="tabular">

<span>|a|c|</span> &amp; '''Yes/No'''<br />

Development of individual parts of software product code &amp; 1<br />

Homework and group projects &amp; 1<br />

Midterm evaluation &amp; 1<br />

Testing (written or computer based) &amp; 1<br />

Reports &amp; 0<br />

Essays &amp; 0<br />

Oral polls &amp; 0<br />

Discussions &amp; 1<br />

</div>

=== Typical questions for ongoing performance evaluation within this section ===

# A plane curve is given by <math display="inline">x(t)=-\frac{t^2+4t+8}{t+2}</math>, <math display="inline">y(t)=\frac{t^2+9t+22}{t+6}</math>. Find

## the asymptotes of this curve;

## the derivative <math display="inline">y'_x</math>.

# Derive the Maclaurin expansion for <math display="inline">f(x)=\sqrt[3]{1+e^{-2x}}</math> up to <math display="inline">o\left(x^3\right)</math>.

=== Typical questions for seminar classes (labs) within this section ===

# Differentiation techniques: inverse, implicit, parametric etc.

# Find a derivative of a function

# Apply Leibniz formula

# Draw graphs of functions

# Find asymptotes of a parametric function

=== Test questions for final assessment in this section ===

# Find a derivative of a (implicit/inverse) function

# Apply Leibniz formula Find <math display="inline">y^{(n)}(x)</math> if <math display="inline">y(x)=\left(x^2-2\right)\cos2x\sin3x</math>.

# Draw graphs of functions

# Find asymptotes

# Apply l’Hopital’s rule

# Find the derivatives of the following functions:

## <math display="inline">f(x)=\log_{|\sin x|}\sqrt[6]{x^2+6}</math>;

## <math display="inline">y(x)</math> that is given implicitly by <math display="inline">x^3+5xy+y^3=0</math>.

=== Section 3 ===

==== Section title: ====

Integration and Series

==== Topics covered in this section: ====

* Antiderivative. Indefinite integral

* Definite integral

* The Fundamental Theorem of Calculus

* Improper Integrals

* Convergence tests. Dirichlet’s test

* Series. Convergence tests

* Absolute / Conditional convergence

* Power Series. Radius of convergence

* Functional series. Uniform convergence

=== What forms of evaluation were used to test students’ performance in this section? ===

<div class="tabular">

<span>|a|c|</span> &amp; '''Yes/No'''<br />

Development of individual parts of software product code &amp; 1<br />

Homework and group projects &amp; 1<br />

Midterm evaluation &amp; 1<br />

Testing (written or computer based) &amp; 1<br />

Reports &amp; 0<br />

Essays &amp; 0<br />

Oral polls &amp; 0<br />

Discussions &amp; 1<br />

</div>

=== Typical questions for ongoing performance evaluation within this section ===

# Find the indefinite integral <math display="inline">\displaystyle\int x\ln\left(x+\sqrt{x^2-1}\right)\,dx</math>.

# Find the length of a curve given by <math display="inline">y=\ln\sin x</math>, <math display="inline">\frac{\pi}4\leqslant x\leqslant\frac{\pi}2</math>.

# Find all values of parameter <math display="inline">\alpha</math> such that series <math display="inline">\displaystyle\sum\limits_{k=1}^{+\infty}\left(\frac{3k+2}{2k+1}\right)^k\alpha^k</math> converges.

==== Typical questions for seminar classes (labs) within this section ====

# Integration techniques

# Integration by parts

# Calculation of areas, lengths, volumes

# Application of convergence tests

# Calculation of Radius of convergence

==== Test questions for final assessment in this section ====

<ol>

<li><p>Find the following integrals:</p></li>

<li><p><math display="inline">\int\frac{\sqrt{4+x^2}+2\sqrt{4-x^2}}{\sqrt{16-x^4}}\,dx</math>;</p></li>

<li><p><math display="inline">\int2^{2x}e^x\,dx</math>;</p></li>

<li><p><math display="inline">\int\frac{dx}{3x^2-x^4}</math>.</p></li>

<li><p>Use comparison test to determine if the following series converge.</p>

<p><math display="inline">\sum\limits_{k=1}^{\infty}\frac{3+(-1)^k}{k^2}</math>;</p></li>

<li><p>Use Cauchy criterion to prove that the series <math display="inline">\sum\limits_{k=1}^{\infty}\frac{k+1}{k^2+3}</math> is divergent.</p></li>

<li><p>Find the sums of the following series:</p></li>

<li><p><math display="inline">\sum\limits_{k=1}^{\infty}\frac1{16k^2-8k-3}</math>;</p></li>

<li><p><math display="inline">\sum\limits_{k=1}^{\infty}\frac{k-\sqrt{k^2-1}}{\sqrt{k^2+k}}</math>.</p></li></ol>