### 1. Limits –

For a function the limit of the function at a point is the value the function achieves at a point which is very close to .

Formally,

Let be a function defined over some interval containing , except that it

may not be defined at that point.

We say that, if there is a number for every number such that

whenever

The concept of limit is explained graphically in the following image –

As is clear from the above figure, the limit can be approached from either sides of the number line i.e. the limit can be defined in terms of a number less that or in terms of a number greater than . Using this criteria there are two types of limits –

**Left Hand Limit –** If the limit is defined in terms of a number which is less than then the limit is said to be the left hand limit. It is denoted as which is equivalent to where and .

**Right Hand Limit –** If the limit is defined in terms of a number which is greater than then the limit is said to be the right hand limit. It is denoted as which is equivalent to where and .

**Existence of Limit –** The limit of a function at exists only when its left hand limit and right hand limit exist and are equal and have a finite value i.e.

**Some Common Limits –**

**L’Hospital Rule –**

If the given limit is of the form or i.e. both and are 0 or both and are , then the limit can be solved by **L’Hospital Rule**.

If the limit is of the form described above, then the L’Hospital Rule says that –

where and obtained by differentiating and .

If after differentitating, the form still exists, then the rule can be applied continuously until the form is changed.

**Example 1 –**Evaluate**Solution –**The limit is of the form , Using L’Hospital Rule and differentiating numerator and denominator**Example 2 –**Evaluate**Solution –**On multiplying and dividing by and re-writing the limit we get –

**Example 1 –**For what value of is the function defined bycontinuous at ?

**Solution –**For the function to be continuous the left hand limit, right hand limit and the value of the function at that point must be equal.

Value of function at

Right hand limit-

RHL equals value of function at 0-

**Example 2 –**Find all points of discontinuity of the function defined by –

.**Solution –**The possible points of discontinuity are since the sign of the modulus changes at these points.

For continuity at ,

LHL-

RHL

Value of at ,

Since LHL = RHL = , the function is continuous atFor continuity at ,

LHL-

RHL

Value of at ,

Since LHL = RHL = , the function is continuous at

So, there is no point of discontinuity.- Mathematics | Predicates and Quantifiers | Set 1
- Mathematics | Mean, Variance and Standard Deviation
- Mathematics | Sum of squares of even and odd natural numbers
- Mathematics | Eigen Values and Eigen Vectors
- Mathematics | Introduction and types of Relations
- Mathematics | Representations of Matrices and Graphs in Relations
- Mathematics | Covariance and Correlation
- Mathematics | Predicates and Quantifiers | Set 2
- Mathematics | Closure of Relations and Equivalence Relations
- Mathematics | Partial Orders and Lattices
- Mathematics | Graph Isomorphisms and Connectivity
- Mathematics | Planar Graphs and Graph Coloring
- Mathematics | Euler and Hamiltonian Paths
- Mathematics | PnC and Binomial Coefficients
- Mathematics | Walks, Trails, Paths, Cycles and Circuits in Graph
- Mathematics | Power Set and its Properties
- Mathematics | Unimodal functions and Bimodal functions
- Mathematics | Sequence, Series and Summations
- Mathematics | Independent Sets, Covering and Matching
- Mathematics | Rings, Integral domains and Fields

### 2. Continuity –

A function is said to be continuous over a range if it’s graph is a single unbroken curve.

Formally,

A real valued function is said to be continuous at a point in the domain if –

exists and is equal to .

If a function is continuous at then-

Functions that are not continuous are said to be discontinuous.

### 3. Differentiability –

The derivative of a real valued function wrt is the function and is defined as –

A function is said to be **differentiable** if the derivative of the function exists at all points of its domain. For checking the differentiability of a function at point ,

must exist.

If a function is differentiable at a point, then it is also continuous at that point.

**Note –** If a function is continuous at a point does not imply that the function is also differentiable at that point. For example, is continuous at but it is not differentiable at that point.

**GATE CS Corner Questions**

Practicing the following questions will help you test your knowledge. All questions have been asked in GATE in previous years or in GATE Mock Tests. It is highly recommended that you practice them.

1. GATE CS 2013, Question 22

2. GATE CS 2010, Question 5

3. GATE CS 2008, Question 1

4. GATE CS 2007, Question 1

5. GATE CS 2015 Set-1, Question 14

6. GATE CS 2015 Set-3, Question 19

7. GATE CS 2016 Set-1, Question 13

8. GATE CS 1998, Question 4

**References-**

Continuity – Wikipedia

Limits – Wikipedia

Differentiability – Wikipedia

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