Tentative Syllabus Math 1011
Tentative
Syllabus ED 3440
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Course: |
Math 1011 3 credits |
Mathematics
for Elementary School Teachers I |
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Department: |
Mathematics
and Computer Science |
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Program(s): |
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Meeting: |
8:00-8:50 AM
MWF |
HS 231 |
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Extras: |
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Dr. Glen
Richgels |
HS 360 Office:
218-755-2824 Email:
grichgels@bemidjistate.edu www:
http://faculty.bemidjistate.edu/grichgels/ |
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7- 8 M-F 11-12 M-F |
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1011 MATHEMATICS FOR
ELEMENTARY SCHOOL TEACHERS I (3 credits) This
course meets the BOT fundamental topics in arithmetic competencies. These
topics include addition, subtraction, multiplication, and division of whole
numbers; number theory related to fractions; fractions; decimals; and
integers. This is the first of two mathematics courses providing the
background for teaching in the elementary school. Emphasizes the use of
mathematics manipulatives for modeling the basic operations. |
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Prerequisite: |
Prerequisite:
Elementary education major or consent of instructor. |
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Professional
Education Mission Statement |
Bemidji State
University prepares teachers through inquisitive, involved, reflective
practice. The framework outlining our program sets a standard that is
rigorous, exemplary and innovative. The curricular structure is research
based and organized around the Standards of Effective Practice. Graduates are
proficient, collaborative, technologically literate and environmentally aware
teachers, who work effectively in various settings with diverse learners. |
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Text: |
Mathematics for
Elementary Teachers a Contempory Approach, |
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Recommended: |
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Technology: |
A calculator. |
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Attendance by all students is expected
for all classes.
Homework: Homework assignments will be made in
class. You should come prepared to
discuss the various reading assignments and compare and contrast them with what
you have observed in schools.
Class
participation and quizzes:
Class participation is expected and in order to participate you need to
be present.
Exams: Exams will be
approximately tri-weekly. There will be a final exam.
Evaluation:There will be 3-5 tests given
throughout the quarter. Quizzes
may be given frequently and may be unannounced. The content for the quizzes and tests will be based on
assignments, classroom discussion and lecture, and textbook material.
Grades: Grades will be based on the
homework, quizzes, tests, and final exam.
Homework, Quizzes - one-sixth
Tests -
one-half
Final -
one-third
The
following grading scale will be used to determine grades:
A 90%
- 100%
B 80%
- 89%
C 70%
- 79%
D 60%
- 69%
A grade of C or better indicates that the student has successfully
met the competencies measured in this class through discussion, homework, and
projects.
Incomplete: An incomplete (I) grade will only be
given in documented emergency situations. BSU policies will be followed.
Students
are expected to practice the highest standards of ethics, honesty, and
integrity in all of their academic work.
Any form of academic dishonesty (e.g. plagiarism, cheating,
misrepresentation) may result in disciplinary action. Possible disciplinary actions include failure for part or
all of the course, as well as suspension from the University.
NOTE: Upon request,
this document and others distributed in this course can be made available in
alternate formats. If you have a documented disability and need
accommodations for this course please contact the instructor, the Disability Services Office in 202
Sanford Hall, Bemidji State University or Kathi Hagen in the Office for
Students with Disabilities at 755-3883 for assistance.. Any other questions
about this course should be directed to the instructor.
Change
in Course Syllabus: The Instructor reserves the right to change
this syllabus as this course proceeds if the need arises. Should a change be
required the class will be notified.
Course
Outline:
Chapter 1 Problem
Solving
Chapter 2 Sets,
Functions, and Reasoning
Chapter 3 Whole
Numbers
Chapter 4 Number
Theory
Chapter 5 Integers
and Fractions
Assignments can be found
on line. This is an example of the assignment page.
Tentative Assignments
Mathematics for Elementary Teachers a
Contempory Approach,
Musser, Burger & Peterson
Please
pay attention to section numbers, not just page numbers.
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p. 17 / 1,3,5,7,9,11,13,15,17,19 |
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1.2A |
p. 32 / 1,3,5,7,9,11,14,15,17 |
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2.1A |
p. 54 / 1,3,5,7,9,11,13,15,17,19,21,23 , Venn
Diagrams |
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2.2A |
p. 67 / 1,3,5,7,8,9,10,11,13,15,17,19 |
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2.3A |
p. 77 / 1,3,5,7,9,11,13,15,17,19,21,23 |
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2.4A |
p. 88 / 1-25 odd |
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3.1A |
p. 115 / 1-17 odd |
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3.2A |
p. 131 / 1-29 odd |
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3.3A |
p. 141 / 1-17 odd |
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4.1A |
p. 162 / 1-39 odd |
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4.2A |
p. 179 / 1-31 odd |
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4.3A |
p. 189 / 1-15 odd |
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5.1A |
p. 208 / 1-43 odd |
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5.2A |
p. 221 / 1-27 odd |
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6.1A |
p. 243 / 1-25 odd |
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6.2A |
p. 254 / 1-27 odd |
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6.3A |
p. 269 / 1-31 odd |
Test
1 : 1.1A-2.1A
Test 2 : 2.2A-4.3A Addition and Subtraction
Test 3 : 3.2A-4.3A Multiplication and Division
Test 4 : 5.1A-5.2A
Test 5 : 6.1A-6.3A
Final Exam: Comprehensive
Instructional Strategies used by
instructor in course:
PolyaÕs problem solving steps
1.
Understand
the problem
- Devise a
plan
- Carry out
the plan
- Reflect
Lesson Sequencing
Intuitions
Þ Concrete ó Semi-Concrete ó Abstract
GlenÕs
Teaching/Learning Principles
1.
Teach
the way students learn
2.
Use
group work, heterogenous, 3-4, change monthly
3.
Communication
student ó student
4.
Communication
teacher ó student
5.
Multiple
solution paths
6.
Use
contextual settings / problem solving
7.
Assessment
a.
Grading
b.
To inform instruction
Updated
by Glen Richgels
February 26, 2010
TENTATIVE
Daily Course Outline
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Day
1 |
Syllabus,
Assignments, Bruner |
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Day
2 |
7 Learning
Principles; exercise vs problem; triangle problem |
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Day
3 |
Polya problem solving steps; R-Model; Chicken
and eggs |
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Day
4 |
Sets |
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Day
5 |
Sets; Venn
Diagrams |
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Day
6 |
Sets; Venn
Diagrams |
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Day
7 |
Sets; Venn
Diagrams |
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Day
8 |
Sets; Venn
Diagrams |
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Day
9 |
Test 1 |
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Day
10 |
Ancient
Number Systems; Egyptian, Roman; Win-A-Block |
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Day
11 |
Babylonian;Lose-A-Block |
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Day
12 |
Mayan; Count
in other Bases |
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Day
13 |
Functions,
relations |
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Day
14 |
Change bases; |
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Day
15 |
Add using
game boards |
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Day
16 |
Addition fact
table base n |
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Day
17 |
Add base n;
Subtract using game board take away model |
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Day
18 |
Test 2 |
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Day
19 |
Subtract
using game boards; 4 fact table; properties; Lattice addition |
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Day
20 |
Add, Subtract
using game boards; 4 fact table; properties; Lattice addition |
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Day
21 |
Multiplication
Models |
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Day
22 |
Partial
Product Multiplication base 10 |
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Day
23 |
Base n fact
table |
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Day
24 |
Partial Product
Multiplication base n; Lattice multiplication |
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Day
25 |
Division
Models; grouping v sharing; Scaffold |
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Day
26 |
Division with
blocks; Place value long division |
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Day
27 |
Test 3 |
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Day
28 |
Locker
problem |
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Day
29 |
Prime numbers
and sieve |
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Day
30 |
Factors, factor
trees, fundamental theorem of arithmetic |
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Day
31 |
Factors in rectangles; A divides B |
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Day
32 |
Divisibility
rules |
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Day
33 |
Divisibility
rules |
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Day
34 |
LCD,
LCM set definition, prime factorization, Euclidean algorithm, formula |
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Day
35 |
LCD,
LCM set definition, prime factorization, Euclidean algorithm, formula |
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Day
36 |
Test 4 |
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Day
37 |
6 fraction
models |
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Day
38 |
6 fraction
models |
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Day
39 |
Rectangular
array fraction models |
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Day
40 |
Rectangular
array fraction models |
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Day
41 |
Division of
fractions |
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Day
42 |
Division of
fractions |
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Day
43 |
Review
abstract fraction operations |
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Day
44 |
Test 5 |
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Day
45 |
Final Exam
Review |
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Day
46 |
Final Exam |
Board
of Teaching Standards
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Department of Mathematics and
Computer Science |
EVIDENCE
OF LEARNING & ASSESSMENT OPPORTUNITIES
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8710.3200 Teachers of Elementary Education
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Course ID Number |
Activity or Unit |
Assessment |
Subp.
3. Subject matter standards, elementary education. A candidate must complete a
preparation program for licensure under subpart 2, item C, that must include
the candidate's demonstration of the knowledge and skills in items A to G.
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C. A teacher of children in kindergarten through grade 6 must
demonstrate knowledge of fundamental concepts of mathematics and the
connections between them. The
teacher must know and apply: |
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(1) concepts of mathematical
patterns, relations, and functions, including the importance of number and
geometric patterns in mathematics and the importance of the educational link
between primary school activities with patterns and the later conceptual
development of important ideas related to functions and be able to: |
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(a) identify and justify observed
patterns; |
M1011 |
Text sections
1.2, 2.4 |
Test 1, Test 2 |
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(b) generate patterns to
demonstrate a variety of relationships; and |
M1011 |
Text sections
1.2, 2.4 |
Test 1, Test 2 |
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(c) relate patterns in one strand of
mathematics to patterns across the discipline; |
M1011 |
Text sections 1.2,
2.4 |
Test 1, Test 2 |
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(2) concepts and techniques of
discrete mathematics and how to use them to solve problems from areas
including graph theory, combinatorics, and recursion and know how to: |
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(a) help students investigate
situations that involve counting finite sets, calculating probabilities,
tracing paths in network graphs, and analyzing iterative procedures; and |
M1011 |
Text sections 2.1,
2.4 |
Test 1, Test 2
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(b) apply these ideas and methods
in settings as diverse as the mathematics of finance, population dynamics,
and optimal planning; |
M1011 |
Text sections 2.1,
2.4 |
Test 1, Test 2 |
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(3) concepts of numerical
literacy: |
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(a) possess number sense and be able
to use numbers to quantify concepts in the students' world; |
M1011 |
Text sections 2.1,
2.2, 2.3, 2.4 |
Test 1, Test 2 |
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(b) understand a variety of
computational procedures and how to use them in examining the reasonableness
of the students' answers; |
M1011 |
Text
sections 3.1,
3.2, 3.3, 4.1, 4.2, 4.3 |
Test 3 |
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(c) understand the concepts of
number theory including divisibility, factors, multiples, and prime numbers,
and know how to provide a basis for exploring number relationships; and |
M1011 |
Text
sections 5.1,
5.2 |
Test 4 |
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(7) mathematical processes: |
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(a) know how to reason
mathematically, solve problems, and communicate mathematics effectively at
different levels of formality; |
M1011 |
Text sections 1.1,
1.2, 2.1 |
Test 1 |
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(b) understand the connections
among mathematical concepts and procedures, as well as their application to
the real world; |
M1011 |
Text sections 1.1,
1.2, 2.1 |
Test 1 |
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(d) understand and apply problem
solving, reasoning, communication, and connections; and |
M1011 |
Text sections 1.1,
1.2, 2.1 |
Test 1 |
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(8) mathematical perspectives: |
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(a) understand the history of
mathematics and the interaction between different cultures and mathematics;
and |
M1011 |
Text sections 2.2,
2.3 |
Test 2 |
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(b) know how to integrate
technological and nontechnological tools with mathematics. |
M1011 |
Text sections 2.3, 3.1, 3.2, 4.1, 4.2 |
Test 2, Test 3 |
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Professional
Education Mission Statement |
Bemidji State
University prepares teachers through inquisitive, involved, reflective
practice. The framework outlining our program sets a standard that is
rigorous, exemplary and innovative. The curricular structure is research
based and organized around the Standards of Effective Practice. Graduates are
proficient, collaborative, technologically literate and environmentally aware
teachers, who work effectively in various settings with diverse learners. |
The elementary teachers from BSU that take the
campus M1011 class will increase their content knowledge and understanding of
how students learn as they experience studying foundational operations in other
and then in any base system from 2 to 9. M1011 is a mixture of challenging
students in the understanding of basic mathematics and experiencing activity
based pedagogy. Students in this class become more proficient in mathematics
because they finally understand how and why fundamental operations work. This
translates into a more positive attitude toward mathematics for themselves that
hopefully they will take with them into their teaching. Students experience the
integration of pedagogy and content so that they can better teach their future
students.
The best practices of activity oriented learning
is demonstrated in class from day one. In addition group work and collaborative
learning are encouraged and used almost daily. Finally the construction of
lessons that proceed from intuitions, to concrete, semi-concrete, and then to
abstract are modeled throughout the entire semester. These best practices are
discussed at the beginning of the course and pointed out and discussed
throughout the semester.