MAT2214

Three-Dimensional Coordinate Systems

• One-dimensional coordinate systems
• Two-dimensional coordinate systems
• Algebraic Expressions
• Solving Inequalities
• [[Distance Formula for R² ]]

• Three-dimensional coordinate systems
• Distance Formula in R³
• Standard Equation for a Sphere

Vectors

• Line Segments
• Length of a Line

• Vector Algebra Operations
• Magnitude of a vector
• Unit Vectors
• Midpoint of a Line Segment
• Angle between vectors
• Definition of Dot product
• Orthogonal vectors
• Vector projection

The Dot Product

• Basic Trig Functions
• Customary domain restrictions for Trigonometric Functions
• Vectors
• Midpoint formula

• Find the area of plane regions bounded by the graphs of functions.

The Cross Product

• Basic Trig Functions
• The Dot Product
• Determinants

• Define the cross product
• Properties of the cross product
• Area of a parallelogram
• Cross product as a determinant

Cylinders and Quadratic Surfaces

• Quadratic Functions
• Parametric Equations
• '''Conics'''

• Find equations for cylinders that are generated by rotating lines that are parallel to a plane
• Understand basic quadratic surfaces
• Understand general quadratic surfaces

Curves in Space and Vector Functions

• Parametric Equations
• Vectors
• The Derivative as a Function
• The Limit of a Function
• Continuity
• The Dot Product
• The Cross Product

• Vector functions
• Limits of vector functions
• Continuity of vector functions
• Differentiation of vector functions
• Differentiation rules for vector functions
• Curves and paths in space

Integrals of Vector Functions

• Initial Value Problems
• Solving Basic Integrals
• Parametric Equations
• Vector Functions

• Indefinite integrals of vector functions
• Definite integrals of vector functions
• Vector and parametric equations for ideal projectile motion

Arc Length

• Length of a Line
• Vector Functions
• Integrals of Vector Functions

• Length of a curve in R³
• General arc length formula
• Arc length for parameterized curves
• The Unit tangent vector

Curvature and Normal Vectors

• Antiderivatives
• Vectors
• Parametric Equations
• The Unit Tangent Vector
• [[Conics]]

• Curvature in R²
• Formula for curvature
• Definition of Principal unit normal
• Curvature and normal vectors for higher dimensions.

Tangential and Normal Components of Acceleration

• The Cross Product
• Derivatives of Vector Functions
• Curvature and Normal Vectors
• Determinants

• Binormal Vectors
• Definition of tangential and normal components of acceleration
• Torsion

Functions of Several Variables

• Domain of a Function
• Range of a Function
• Interval Notation
• Graphing a Function
• Equation of a Circle

• Domain and range of multivariable functions
• Functions with two variables
• Bounded regions
• Graphs and level curves of two variable functions
• Functions of three variables
• Level surfaces

Limits and Continuity in Higher Dimensions

• The Limit of a Function
• Continuity
• The Limit Laws
• Composition of Functions
• The Dot Product
• The Cross Product

• Limits of functions of two variables
• Properties of limits of functions of two variables
• Continuity for functions of two variables
• Continuity of composition
• Functions of more than two variables
• Extreme values on closed and bounded sets

Partial Derivatives

• Second derivatives
• Limits and Continuity in Higher Dimensions
• Functions of Several Variables

• Partial derivatives for functions of two variables
• Partial derivatives for functions of more than two variables
• Partial derivatives and continuity
• Second order partial derivatives
• Mixed derivative theorem
• Define differentiability for functions of two variables

The Chain Rule for Functions of more than One Variable

• Differentiation Rules
• The Chain Rule
• Implicit Differentiation
• Parametric Equations
• Partial Derivatives

• Chain rule for functions of one independent variable and two intermediate variables.
• Chain rule for functions of one independent variable and three intermediate variables.
• Chain rule for functions of two independent variable and two intermediate variables.
• Additional method for implicit differentiation.
• The general chain rule

Directional Derivatives and Gradient Vectors

• Trigonometric Functions
• The Chain Rule for Functions of more than One Variable
• Unit Vectors
• Partial Derivatives
• The Dot Product

• Direction Derivatives in the plane
• Gradients
• Properties of directional derivatives
• Tangents to level curves
• Directional derivatives for functions of three variables
• The chain rule for paths

Tangent Planes and Differentials

• Linear Approximations and Differentials
• Parametric Equations
• Partial Derivatives
• Slope of a Line
• Cylinders and Quadratic Surfaces

• Tangent Planes and Normal lines
• The plane tangent to a surface
• How to linearize a function of two variables
• Differentials for functions of two variables
• Linearization and differentials for functions of more than two variables

Extreme Values and Saddle Points

• Extreme values on closed and bounded sets
• Partial Derivatives
• Critical Points of a Function
• Continuity of functions with two variables

• The derivative test for local extreme values
• Critical points and saddle points for functions of two variables
• Second derivative test for local extreme values
• Absolute maxima and minima on closed and bounded regions

EDIT

• Extreme Values and Saddle Points
• Cylinders and Quadratic Surfaces
• Directional Derivatives and Gradient Vectors

• Define the convergence or divergence of an infinite series.
• Find the sum of a geometric or telescoping series.

Taylors formula for Two Variables

• Taylor and Maclaurin Series
• Partial Derivatives
• Limits and Continuity in Higher Dimensions

• The derivation of the second derivative test
• Taylor's formula for functions of two variables

Double and Iterated Integrals over Rectangles

• Approximating Areas
• Limits of Riemann Sums

• Double Integrals
• Fubini's Theorem (part 1)

Double Integrals over General Regions

• Continuity
• Determining Volumes by Slicing
• Double and Iterated Integrals over Rectangles

• Double integrals over bounded, nonrectangular regions
• Volumes of solid regions
• Fubini's theorem (part 2)
• Finding the limits of integration for regions in the plane
• Properties of double Integrals

Area by Double Intgration

• Double Integrals over General Regions
• Average value of a fucntion
• Conics

• Areas of bounded regions in the plane
• Average value for functions of two or more variables

Double Integrals in Polar Form

• Double Integrals over General Regions
• Polar Form

• Integrals in Polar Form
• Finding limits of integration for polar coordinates
• Changing Cartesian Integrals into Polar Integrals

Triple Integrals in Rectangular Coordinates

• Double and Iterated Integrals over Rectangles
• Area by Double Integration
• Change of Variables

• Triple Integrals
• Volume of a region in space
• Finding the limits of integration for triple integrals
• Average value of a function in space

Applications of Double and Triple Integrals

• Moments and Center of Mass
• Triple Integrals in Rectangular Coordinates
• Partial Derivatives

• Masses and First moments
• Moments of Inertia

Triple Integrals in Cylindrical and Spherical Coordinates

• Double Integrals in Polar Form
• Polar Form
• Triple Integrals in Rectangular Coordinates

• Integration in Cylindrical Coordinates
• Equations relating rectangular and cylindrical coordinates
• Spherical coordinates and integrations
• Equations relating spherical coordinates to Cartesian and cylindrical coordinates

Taylor and Maclaurin Series

• The Derivative of a Function
• Power Series and Functions
• Properties of Power Series

• Find the Taylor or Maclaurin series representation of a function.
• Find the radius of convergence of a Taylor Series.
• Estimate the remainder in a Taylor polynomial approximation.

Parametric Equations

• Trigonometric Functions
• Exponential Functions
• Sketching Common Functions

• Sketch the graph of a parametric curve