Topics
Mathematical Logic
- Statements and Truth Values in Mathematical Logic
- Logical Statements & Equivalence
- Tautology, Contradiction, and Contingency
- Quantifier, Quantified and Duality Statements in Logic
- Negations of Compound Statements
- Converse, Inverse, and Contrapositive
- Algebra of Statements
- Application of Logic to Switching Circuits
11th Std
Trigonometry - II
- Trigonometric Functions of Allied Angels
- Trigonometric Functions of Compound Angles
- Trigonometric Functions of Sum and Difference of Three Angles
- Trigonometric Functions of Multiple Angles
- Trigonometric Functions of Sub-Multiple Angles
- Conversion Formulae in Trigonometry
- Trigonometric Functions of Angles of a Triangle
- Important Identities and Standard Results
12th Std
Matrices
- Symmetric and Skew Symmetric Matrices
- Inverse of a Matrix
- Application of Matrices
- Transpose of a Matrix
- Symmetric and Skew Symmetric Matrices
- Determinant of a Matrix
- Minors and Co-factors
- Adjoint of a Matrix
- System of Homogeneous and Non – Homogeneous Equations
Straight Line
- Coordinate Geometry Foundations
- Locus
- Shift of Origin
- Concept of Slope (or, gradient)
- Equations of Line in Different Forms
- The Angle Between Two Intersecting Lines
- Distance of a Point from a Line
- Family & Concurrent Lines
- Relative Position and Standard Results of Straight Lines
Circle
- Equation of a Circle in Different Forms
- Equation of a Circle in some special cases
- Director circle
- Equation of Tangent and Condition of Tangency
- Important Results for Circles
Trigonometric Functions
- Trigonometric Equations and Their Solutions
- Solutions of Triangle
- Meaning and Interpretation of Inverse Trigonometric Functions
- Graphs and Domains & Ranges of Inverse Trigonometric Functions
- Principal Values of Inverse Trigonometric Functions
- Properties of Inverse Trigonometric Functions
Conic Sections
- Fundamentals of Conic Sections
- Parabola and its types
- Ellipse and its Types
- Hyperbola and its Types
- Equations of Tangents and Conditions of Tangency for Conic Sections
- Equations of Auxiliary Circle and Director Circle
Pair of Straight Lines
- Combined Equation of a Pair Lines
- Homogeneous Equation of Degree Two
- Angle between lines represented by ax2 + 2hxy + by2 = 0
- General Second Degree Equation in x and y
Measures of Dispersion
- Range, Variance and Standard Deviation
- Coefficient of Variation
- Standard Deviation for Combined Data
- Meaning and Definition of Dispersion
- Measures of Dispersion
- Quartiles and Range in Statistics
- Variance
- Standard Deviation
- Change of Origin and Scale of Variance and Standard Deviation
- Standard Deviation for Combined Data
- Coefficient of Variation
- Mean Deviation
Probability
- Elementary Types of Events and Properties of Probability
- Addition Theorem for Two Events
- Conditional Probability
- Multiplication Theorem on Probability
- Independent Events
- Bayes’ Theorem
- Odds (Ratio of Two Complementary Probabilities)
Vectors
- Vector Algebra: Representation and Types
- Algebra of Vectors
- Collinearity and Coplanarity of Vectors
- Vector in Two Dimensions (2-D)
- Three Dimensional (3-D) Coordinate System
- Components of Vector
- Position Vector of a Point P(X, Y, Z) in Space
- Component Form of a Position Vector
- Vector Joining Two Points
- Section Formula
- Product of Vector in Algebra (Dot Product)
- Direction Ratios, Direction Cosine & Direction Angles
- Vector Product of two vectors in Algebra (Cross Product)
- Scalar Triple Product
- Vector Triple Product
Line and Plane
- Vector and Cartesian Equations of a Line
- Distance of a Point from a Line
- Distance Between Skew Lines and Parallel Lines
- Equation of a Plane
- Angle Between the Planes
- Coplanarity of Two Lines
- Distance of a Point from a Plane
Complex Numbers
- Concept of Complex Numbers
- Algebraic Operations of Complex Numbers
- Equality of Two Complex Numbers
- Conjugate of a Complex Number
- Square Root of a Complex Number
- Fundamental Theorem of Algebra
- Argand Diagram or Complex Plane
- Modulus of a Complex Number
- Argument of a Complex Number
- DeMoivre's Theorem
- Cube Root of Unity
- Set of Points in Complex Plane
- Important Result of Complex Number
Linear Programming
- Linear Inequations in Two Variables
- Linear Programming Problem (L.P.P.)
- Formal Definitions and Solution of L.P.P
- Formal Definitions and Solution of L.P.P
- Methods to Find the Solution of L.P.P> Graphical Method
- Methods to Find the Solution of L.P.P> Corner - Point Method
Permutations and Combinations
- Factorial Notation
- Fundamental Principles of Counting
- Invariance Principle
- Permutations
- Circular Permutations
- Combination
- Important Result for Permutation and Combination
Functions
- Domain and Range of a Function
- Types of Functions
- Representation of Function
- Special Type of Function
- Algebra of Functions
- Composition of Functions
Differentiation
- Introduction & Derivatives of Some Standard Functions
- Derivative of Composite Functions
- Geometrical Meaning of Derivative
- Derivative of Inverse Functions
- Derivatives of Inverse Trigonometric Functions
- Logarithmic Differentiation
- Derivative of Implicit Functions
- Derivative of Parametric Functions
- Higher Order Derivatives
- Successive Differentiation
Limits
- Concept of Limits
- Algebra of Limits
- Methods to Find Limit of Rational Function>Factorization Method
- Methods to Find Limit of Rational Function> Rationalization Method
- Methods to Find Limit of Rational Function> Substitution Method
- Limits of Exponential and Logarithmic Functions
- Limits of Trigonometric Functions
- Limit at Infinity
Applications of Derivatives
- Application of Derivative in Geometry
- Derivative as a Rate Measure
- Velocity, Acceleration and Jerk
- Approximations
- Rolle's Theorem
- Lagrange's Mean Value Theorem (LMVT)
- Increasing and Decreasing Functions
- Maxima and Minima
Continuity
- Continuous and Discontinuous Functions
- Types of Discontinuity
- Continuity Over an Interval
- Intermediate Value Theorem
- Algebra of Continuous Functions
Indefinite Integration
- Indefinite Integration with Standard Indefinite Integral Formulae
- Methods of Integration> Integration by Substitution
- Methods of Integration> Integration by Parts
- Methods of Integration> Integration Using Partial Fraction
- Integrals of Trignometric Functions
- Some Special Integrals
Definite Integration
- Definite Integral as Limit of Sum
- Fundamental Theorem of Integral Calculus
- Properties of Definite Integrals
Conics
- Double Cone
- Fundamentals of Conic Sections
- Parabola and its types
- Ellipse and its Types
- Hyperbola and its Types
Application of Definite Integration
- Area Under Simple Curves
- Area Bounded by Two Curves
- Symmetrical Area
Sets and Relation
- Concept of Sets
- Classification of Sets
Differential Equations
- Order and Degree of a Differential Equation
- Solution of a Differential Equation
- Formation of Differential Equations
- Equations in Variable Separable Form
- Homogeneous Differential Equations
- Linear Differential Equations
- Applications of Differential Equation
Sequences and Series
- Sequence, Series, and Progression
- nth Term of A.G.P
- Expressing Recurring Decimals as Rational Numbers
- Arithmetic Progression (A.P.)
- Geometric Progression (G. P.)
- Sum to' n' Terms of a Geometric Progression
- Harmonic Progression (H. P.)
- Types of Means
- Arithmetico Geometric Series
- Power Series
Probability Distribution
- Random Variables
- Probability Distribution of Discrete Random Variables
- Probability Mass Function (P.M.F.)
- Cumulative Distribution Function (c. d. f. )
- Expected Value and Variance of a Random Variable
- Probability Distribution of a Continuous Random Variable
- Probability Density Function (P.D.F.)
- Cumulative Distribution Functions (c. d. f.)
Methods of Induction and Binomial Theorem
- Principle of Mathematical Induction
- General Term in Expansion of (a + b)n
- Middle term(s) in the expansion of (a + b)n
Binomial Distribution
- Bernoulli Trial
- Binomial Distribution
- Mean and Variance of Binomial Distribution
Determinants and Matrices
- Minors and Cofactors of Elements of Determinants
- Properties of Matrix Multiplication
- Definition of Vector Product
Notes
Vector Product or Cross Product of two vectors:
The vector product or cros product of two vectors `vec"A"` and `vec"B"` is another vector `vec"C"`, whose magnitude is equal to the product of the magnitudes of the two vectors and sine of the smaller angle between them.
If Θ is the smaller angle between `vec"A"` and `vec"B"`, then
`vec"A"xxvec"B" = vec"C" = "AB" sin theta hat"C"`
where `hatC` is a unit vector in the direction of `vecC`. The direction of `vecC` or `hatC`(i.e. vector product of two vectors) is perpendicular to the plane containing `vec"A"` and `vec"B"` and pointing in the direction of advance of a right handed screw when rotated from `vec"A"` to `vec"B"`.
Some important properties of cross products are as follows:
(a) For parallel as well as anti parallel vectors(i.e. when `theta` = 0° or 180°), the cross product is zero.
(b) the magnitude of cross product of two perpendicular vectors is equal to the product of the magnitudes of the given vectors.
(c) Vector product is anti-commutative i.e. `vec"A" xx vec"E" = -vec"B" xx vec"A"`
(d) Vector product is distributive i.e. `vec"A"xx(vec"B" +vec"C")=vec"A" xx vec"B" + vecA xx vec"C"`
(e)`vecA xx vecB` does not change sign under reflection i.e. `(-vecA)xx(-vecB)=vecA xx vecB`
(f) For unit orthogonal vectors, we have
`hatixxhati=hatjxxhatj=hatkxxhatk=0,hatixxhatj=hatk,hatjxxhatk=hati and hatkxxhati=hatj`
moreover `hatjxxhati=-hatk, hatkxxhatj=-hati and hatixxhatk=-hatj`
(g) In terms of components `vec"A"xxvec"B"= |(hati,hatj,hatk),(A_x,A_y,A_z),(B_x,B_y,B_z)|`
The angular velocity of a body or a particle is defined as the ratio of the angular dispacement of the body or the particle to the time interval during which this displacement occurs.
ω = `("d" theta)/"dt"`
The direction of angular velocity is along the axis of rotation. it is measured in radian/sec and its dimensional formula is [M°L°T-1].
The relation betwennt angular velocity and linear velocity is given by
`vecv = vecomegaxxvecr`
The angular acceleration of a body is defined as the ratio of the change in the angular velocity to the time interval.
`"Angular acceleration" = "Change in angular velocity"/("Time taken")`
`vecalpha = ("d"vecomega)/"dt"`
The unit of angular acceleration is rad s-2 and dimensional formula is [M°L°L-2]
