Topics
Angle and Its Measurement
- Directed Angle
- Angles of Different Measurements
- Angles in Standard Position
- Measures of Angles with Various Systems
- Area of a Sector
- Length of an Arc
Trigonometry - 1
- Trigonometric Ratios
- Trigonometric Functions with the Help of a Circle
- Signs of Trigonometric Functions in Different Quadrants
- Range of Cosθ and Sinθ
- Trigonometric Functions of Specific Angles
- Trigonometric Functions of Negative Angles
- Fundamental Identities
- Periodicity of Trigonometric Functions
- Domain and Range of Trigonometric Functions
- Graphs of Trigonometric Functions
- Polar Co-ordinate System
Trigonometry - 2
- Trigonometric Functions of Sum and Difference of Angles
- Trigonometric Functions of Allied Angels
- Trigonometric Functions of Multiple Angles
- Trigonometric Functions of Double Angles
- Trigonometric Functions of Triple Angle
- Factorization Formulae
- Formulae for Conversion of Sum Or Difference into Product
- Formulae for Conversion of Product in to Sum Or Difference
- Trigonometric Functions of Angles of a Triangle
Determinants and Matrices
- Definition and Expansion of Determinants
- Minors and Cofactors of Elements of Determinants
- Properties of Determinants
- Application of Determinants
- Determinant Method (Cramer’s Rule)
- Consistency of Three Equations in Two Variables
- Area of Triangle and Collinearity of Three Points
- Concept of Matrices
- Types of Matrices
- Operation on Matrices
- Properties of Matrix Multiplication
- Transpose of a Matrix
Straight Line
- Locus of a Points in a Co-ordinate Plane
- Equations of Line in Different Forms
- Equation of a Straight Line
- Family of Lines
Circle
- Different Forms of Equation of a Circle
- General Equation of a Circle
- Parametric Form of a Circle
- Secant and Tangent
- Condition of tangency
- Tangent and Secant Properties
- Director circle
Conic Sections
- Double Cone
- Conic Sections
- Parabola
- Ellipse
- Hyperbola
Measures of Dispersion
- 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
Probability
- Basic Terminologies
- Elementary Types of Events in Probability
- Concept of Probability
- Addition Theorem for Two Events
- Conditional Probability
- Multiplication Theorem on Probability
- Independent Events
- Bayes’ Theorem
- Odds (Ratio of Two Complementary Probabilities)
Complex Numbers
- Introduction of Complex Number
- Concept of Complex Numbers
- Algebraic Operations of Complex Numbers
- Square Root of a Complex Number
- Fundamental Theorem of Algebra
- Argand Diagram Or Complex Plane
- De Moivres Theorem
- Cube Root of Unity
- Set of Points in Complex Plane
Sequences and Series
- Sequence, Series, and Progression
- Arithmetic Progression (A.P.)
- Geometric Progression (G. P.)
- Harmonic Progression (H. P.)
- Arithmetico Geometric Series
- Power Series
Permutations and Combination
- Fundamental Principles of Counting
- Invariance Principle
- Factorial Notation
- Permutations
- Permutations When All Objects Are Distinct
- Permutations When Repetitions Are Allowed
- Permutations When Some Objects Are Identical
- Circular Permutations
- Properties of Permutations
- Combination
- Properties of Combinations
Methods of Induction and Binomial Theorem
- Principle of Mathematical Induction
- Binomial Theorem for Positive Integral Index
- General Term in Expansion of (a + b)n
- Middle term(s) in the expansion of (a + b)n
- Binomial Theorem for Negative Index Or Fraction
- Binomial Coefficients
Sets and Relations
- Sets and Their Representations
- Classification of Sets
- Fundamental Concepts of Ordered Pairs and Relations
- Intervals
Functions
- Functions
- Algebra of Functions
Limits
- Concept of Limits
- Factorization Method
- Rationalization Method
- Limits of Trigonometric Functions
- Substitution Method
- Limits of Exponential and Logarithmic Functions
- Limit at Infinity
Continuity
- Continuous and Discontinuous Functions
Differentiation
- Definition of Derivative and Differentiability
- Rules of Differentiation (Without Proof)
- Derivative of Algebraic Functions
- Derivatives of Trigonometric Functions
- Derivative of Logarithmic Functions
- Derivatives of Exponential Functions
- L' Hospital'S Theorem
- Partition of a sample space
- Theorem of total probability
Notes
If `E_1, E_2 ,..., E_n` are n non empty events which constitute a partition of sample space S, i.e. `E_1, E_2 ,..., E_n` are pairwise disjoint and `E_1 ∪ E_2 ∪ ... ∪ E_n` = S and A is any event of nonzero probability, then
P(Ei|A) =`(P(E_i) P (A | E_i))/( sum_(i=1)^n P(E_j) P(A|E _j ))`
P for any i = 1, 2, 3, ..., n
Proof: By formula of conditional probability, we know that
`P(E_i|A) = (P(A ∩ E_i )) / (P(A))`
`= (P(E_i ) (P(A|E_i )))/ (P(A))` (by multiplication rule of probability)
`= (P(E_i )P(A|E_i ))/ (sum_(j = 1)^n P(E _j)P(A|E_j)) ` (by the result of theorem of total probability)
Remark: The following terminology is generally used when Bayes' theorem is applied. The events `E_1, E_2, ..., E_n` are called hypotheses.
The probability `P(E_i)` is called the priori probability of the hypothesis `E_i`
The conditional probability `P(E_i |A)` is called a posteriori probability of the hypothesis `E_i`.
Bayes' theorem is also called the formula for the probability of "causes". Since the `E_i's` are a partition of the sample space S, one and only one of the events `E_i` occurs (i.e. one of the events `E_i` must occur and only one can occur). Hence, the above formula gives us the probability of a particular Ei (i.e. a "Cause"), given that the event A has occurred.
Video link : https://youtu.be/UVx7q7qN-6k
1) Partition of a sample space:
A set of events `E_1, E_2, ..., E_n` is said to represent a partition of the sample space S if
(a) `E_i ∩ E_j = φ, i ≠ j, i, j = 1, 2, 3, ..., n`
(b) `E_1 ∪ Ε_2 ∪ ... ∪ E_n= S` and
(c) `P(E_i) > 0 "for all" i = 1, 2, ..., n.`
In other words, the events `E_1, E_2, ..., E_n` represent a partition of the sample space S if they are pairwise disjoint, exhaustive and have nonzero probabilities.
As an example, we see that any nonempty event E and its complement E′ form a partition of the sample space S since they satisfy E ∩ E′ = φ and E ∪ E′ = S.
2) Theorem of total probability:
Let `{E_1, E_2,...,E_n}` be a partition of the sample space S, and suppose that each of the events `E_1, E_2,..., E_n` has nonzero probability of occurrence. Let A be any event associated with S, then
`P(A) = P(E_1) P(A|E_1) + P(E_2) P(A|E_2) + ... + P(E_n) P(A|E_n)`
= ` sum _(j=1) ^ n P(E_j) P(A|E_j)`
Proof : Given that `E_1, E_2,..., E_n` is a partition of the sample space S in following fig.
Therefore , S =` E_1 ∪ E_2 ∪ ... ∪ E_n` ... (1)
and `E_i ∩ E_j = φ, i ≠ j, i, j = 1, 2, ..., n`
Now, we know that for any event A,
A = A ∩ S
=` A ∩ (E_1 ∪ E_2 ∪ ... ∪ E_n)`
= `(A ∩ E_1) ∪ (A ∩ E_2) ∪ ...∪ (A ∩ E_n)`
Also A ∩ `E_i` and A ∩ `E_j` are respectively the subsets of `E_i` and `E_j`. We know that `E_i` and `E_j` are disjoint, for i ≠ j, therefore, `A ∩ E_i` and `A ∩ E_j` are also disjoint for all i ≠ j, i, j = 1, 2, ..., n.
Thus,
`P(A) = P [(A ∩ E_1) ∪ (A ∩ E_2)∪ .....∪ (A ∩ E_n)]`
= `P (A ∩ E_1) + P (A ∩ E_2) + ... + P (A ∩ E_n)`
Now, by multiplication rule of probability, we have
`P(A ∩ E_i) = P(E_i) P(A|E_i) as P (E_i) ≠ 0 ∀ i = 1,2,..., n`
Therefore, P (A) = `P (E_1) P (A|E_1) + P (E_2) P (A|E_2) + ... + P (E_n)P(A|E_n)`
or `P(A) = sum_(j = 1)^n P(E_j) P(A|E_j)`
Video list :https://youtu.be/_jY8B_0dZgo
