College of Engineering, Forestry, and Natural Sciences
Department of Mathematics and Statistics
Secondary Education - Mathematics, Bachelor of Science in Education
Overview
In addition to University Requirements:
- At least 80 units of major requirements which includes at least 30 units of Mathematics and Science Teaching requirements
- Up to 9 units of major prefix courses may be used to satisfy Liberal Studies requirements; these same courses may also be used to satisfy major requirements.
- For this major the liberal studies prefixes are MAT and STA
- Please note that the usual 35 units for liberal studies are reduced to 32 units for mathematics majors, who are exempted from the 3-unit mathematics foundation requirement
- Elective courses, if needed, to reach an overall total of at least 120 units.
Candidates in this program are required to demonstrate content knowledge, pedagogical knowledge and skills, professional knowledge, and professional dispositions to be eligible to enter student teaching or internship placements.
Content, pedagogical, and professional knowledge or skills, professional dispositions are demonstrated through candidate performance on key assessments embedded in the following course(s):
Students may be able to use some courses to meet more than one requirement. Contact your advisor for details.
Minimum Units for Completion |
120 |
Major GPA |
2.5 |
Highest Mathematics Required |
MAT 442 |
Additional Admission Requirements |
Required |
Student Teaching/Supervised Teaching |
Required |
University Honors Program |
Optional |
Progression Plan Link |
View Progression Plan |
Purpose Statement
The NAUTeach program is a challenging undergraduate course of study solely designed to prepare mathematics and science teachers for grades 6-12. The program emphasizes the pre-service teacher’s ability to develop research-based pedagogy through a STEM (Science, Technology, Engineering, Mathematics) focused, field intensive, rigorous curriculum. This allows undergraduate students to be highly supported by faculty who specialize in mathematics and science education research and Master Teachers that have years of professional classroom experience. Our program is designed for students with strong skills in mathematics or science seeking certification to teach biology, chemistry, physics, Earth sciences, general science, or mathematics at the secondary level.
The NAUTeach program, modeled after the successful UTeach program at the University of Texas, provides opportunities for you to:
- graduate in four years. Students earn a Bachelor of Science in education in their field of study.
- earn dual degrees. Students have the ability to earn degrees both in specific fields of science or mathematics and in teaching science or math.
- have early classroom teaching immersion. Students are in the K-12 mathematics or science classroom teaching and observing from the first semester and throughout the NAUTeach program to prepare for their capstone student teaching experience.
- work cooperatively in a STEM focused center. Course of study partnered with the department of Mathematics, Biology, Chemistry, Geology, and Physics.
- experience “student-centered” instruction. Course structure supports deep student understanding of concepts related to teaching, science, and mathematics.
- develop numerous STEM based lessons and a full STEM based unit. Students teach numerous STEM lessons and a STEM unit at local secondary schools, which build towards a capstone student teaching experience that utilizes the full range of skills and experiences.
- engage in educational dialogue and planning. Students plan lessons that promote deep content knowledge, analytical reasoning, creative thought and use of appropriate teaching strategies.
- use technology to enhance learning. Students experience technology throughout NAUTeach courses and develop lessons that model technology use in 6-12 classrooms.
- earn scholarships, internships and loan forgiveness. Numerous financial opportunities exist for secondary mathematics and science education majors.
- inspire future scientists, engineers, and mathematicians to change the world. Visit Teachers who inspired great scientists to see how teachers change the world.
Student Learning OutcomesOutcomes align with Standards from the Council for the Accreditation of Educator Preparation, the National Mathematics Teachers Association, and the Interstate New Teacher Assessment and Support Consortium - Design instruction that develops all students’ abilities to meet academic standards
- Reflect on teaching practices including the creation of a classroom environment based on respect and rapport that fosters a positive climate for learning, equity, and excellence.
- Create and maintain a learning climate that supports the development of all students’ abilities to meet academic standards.
- Implement and manage instruction that develops all students’ abilities to meet academic standards.
- Assess learning and communicate results to all students, parents and other appropriate professionals with respect to all students’ abilities to meet academic standards.
- Collaborate with colleagues, parents the community and other appropriate agencies to design, implement, and support learning that supports all students’ abilities to meet academic standards.
- Review and evaluate personal performance in order to improve teaching practices through reflection.
- Develop and nurture current professional knowledge of the teaching/learning process.
- Provide evidence of student learning through the design and implementation of instruction that makes use of effective communication techniques, is based on student prior knowledge, actively engages students in the learning process, and provides timely high-quality feedback.
- Reflect on the roles and responsibilities and adhere to legal and ethical requirements of the profession.
- In collaboration with other professionals, participate in the design, implementation, and assessment of individual education programs.
- Provide evidence of meeting the Arizona Professional Teaching Standards by taking the AEPA Secondary Professional Knowledge exam.
- Number and Quantity: To be prepared to develop student mathematical proficiency, all secondary mathematics teachers should know the following topics related to number and quantity with their content understanding and mathematical practices supported by appropriate technology and varied representational tools, including concrete models:
- Structure, properties, relationships, operations, and representations including standard and non-standard algorithms, of numbers and number systems including integer, rational, irrational, real, and complex numbers
- Fundamental ideas of number theory (divisors, factors and factorization, primes, composite numbers, greatest common factor, least common multiple, and modular arithmetic)
- Quantitative reasoning and relationships that include ratio, rate, and proportion and the use of units in problem situations
- Vector and matrix operations, modeling, and applications
- Historical development and perspectives of number, number systems, and quantity including contributions of significant figures and diverse cultures
- Algebra: To be prepared to develop student mathematical proficiency, all secondary mathematics teachers should know the following topics related to algebra with their content understanding and mathematical practices supported by appropriate technology and varied representational tools, including concrete models:
- Algebraic notation, symbols, expressions, equations, inequalities, and proportional relationships, and their use in describing, interpreting, modeling, generalizing, and justifying relationships and operations
- Function classes including polynomial, exponential and logarithmic, absolute value, rational, and trigonometric, including those with discrete domains (e.g., sequences), and how the choices of parameters determine particular cases and model specific situations
- Geometry and Trigonometry: To be prepared to develop student mathematical proficiency, all secondary mathematics teachers should know the following topics related to geometry and trigonometry with their content understanding and mathematical practices supported by appropriate technology and varied representational tools, including concrete models:
- Core concepts and principles of Euclidean geometry in two and three dimensions and two-dimensional non-Euclidean geometries
- Transformations including dilations, translations, rotations, reflections, glide reflections; compositions of transformations; and the expression of symmetry in terms of transformations
- Congruence, similarity and scaling, and their development and expression in terms of transformations
- Right triangles and trigonometry
- Application of periodic phenomena and trigonometric identities
- Identification, classification into categories, visualization, and representation of two- and three-dimensional objects (triangles, quadrilaterals, regular polygons, prisms, pyramids, cones, cylinders, and spheres)
- Formula rationale and derivation (perimeter, area, surface area, and volume) of two- and three-dimensional objects (triangles, quadrilaterals, regular polygons, rectangular prisms, pyramids, cones, cylinders, and spheres), with attention to units, unit comparison, and the iteration, additivity, and invariance related to measurements
- Geometric constructions, axiomatic reasoning, and proof
- Analytic and coordinate geometry including algebraic proofs (e.g., the Pythagorean Theorem and its converse) and equations of lines and planes, and expressing geometric properties of conic sections with equations
- Historical development and perspectives of geometry and trigonometry including contributions of significant figures and diverse cultures
- Statistics and Probability: To be prepared to develop student mathematical proficiency, all secondary mathematics teachers should know the following topics related to statistics and probability with their content understanding and mathematical practices supported by appropriate technology and varied representational tools, including concrete models:
- Statistical variability and its sources and the role of randomness in statistical inference
- Creation and implementation of surveys and investigations using sampling methods and statistical designs, statistical inference (estimation of population parameters and hypotheses testing), justification of conclusions, and generalization of results
- Univariate and bivariate data distributions for categorical data and for discrete and continuous random variables, including representations, construction and interpretation of graphical displays (e.g., box plots, histograms, cumulative frequency plots, scatter plots), summary measures, and comparisons of distributions
- Empirical and theoretical probability (discrete, continuous, and conditional) for both simple and compound events
- Random (chance) phenomena, simulations, and probability distributions and their application as models of real phenomena and to decision making
- Historical development and perspectives of statistics and probability including contributions of significant figures and diverse cultures
- Calculus: To be prepared to develop student mathematical proficiency, all secondary mathematics teachers should know the following topics related to calculus with their content understanding and mathematical practices supported by appropriate technology and varied representational tools, including concrete models:
- Limits, continuity, rates of change, the Fundamental Theorem of Calculus, and the meanings and techniques of differentiation and integration
- Parametric, polar, and vector functions
- Sequences and series
- Multivariate functions
- Applications of function, geometry, and trigonometry concepts to solve problems involving calculus
- Historical development and perspectives of calculus including contributions of significant figures and diverse cultures
- Discrete Mathematics: To be prepared to develop student mathematical proficiency, all secondary mathematics teachers should know the following topics related to discrete mathematics with their content understanding and mathematical practices supported by appropriate technology and varied representational tools, including concrete models:
- Discrete structures including sets, relations, functions, graphs, trees, and networks
- Enumeration including permutations, combinations, iteration, recursion, and finite differences
- Propositional and predicate logic
- Applications of discrete structures such as modeling and solving linear programming problems and designing data structures
- Historical development and perspectives of discrete mathematics including contributions of significant figures and diverse cultures
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