Square root by Long Division Method

 Square root by Long Division Method

Example1

1)find the square root of 14996

Step 1

Separate the digits from right to left once in two digits

                            1 49 96 

here, we got 1 before the first space

Step2

Now we have to find the square of a number such that it must be <=1

here, 1*1 =1

now, let we do this by long division

here, we subtracted and got the remainder as 0,

Step 3

Now we have to get down the next pair (49) and quotient 1 as to be multiplied by 2.

Step 4

Now we have to take same number at the two places where we mentioned _

and then we have to find the product where that product must be = or < 49.

 then subtract and we got the remainder 5

Step 5

Again bring down the next pair and repeat from step 3. that is multiply the quotient by 2.

    

Hence Square root of (14996) = +/- 122 with remainder 112

Example 2

2) find the square root of 119025

Step1

11 90 25

Step 2

Step 3

  we multiplied quotient 3 by 2=6

step 4

Step 5

Hence, square root (119025) = +/- 345

Square Root

 Square Root

       A square root of a number is a value that, when multiplied by itself , gives the number .

√a²=√a*a = a  (a² = a*a)

Note

a² = -a * -a (since - * - = +)

so, 

√a²=√-a*-a = -a

Hence,

√a²= a or -a

Example

1) Find a square root of 25 or find √25

25 = 5* 5  or  25 = -5 * -5

√25 = √5*5 = 5

or 

√25 = √-5*-5 = -5

hence, √25 = 5 or -5

2) Find a square root of 9 or √9

9 = 3*3 or 9 = -3 * -3

√9 = √3*3 = 3

or 

√9 = √-3*-3 = -3

3) find the square root for 576

 

 

√ 576 = 24 or -24

Square Of a Number

 Square of a Number

    To square a number, just multiply it by itself.

That is,

a² = a*a
also, we can write it as
 a^2 = a*a (^ is the symbol of exponent)

Example

1) Find a square of 2

here the number is 2

to find a square of a number we have to multiply that number by itself

square of 2 = 2*2 =4

that is, 2^2=2*2=4

2) Find a square of 3

3²=3*3=9

3) Find a square of 7

7²=7*7 = 49

4) Find a square of (-5)

(-5)² = -5 * -5 = 25 

Note 

- * - = +  (-3 * -3 = 9)

- * + = -  (-3 * 3 = -9)

+ * - = -  (3 * -3 = -9)

+ * + = + (3 *  3 = 9)

5) Solve (8-4)²

8-4 = 4

(8-4)² = 4² = 4*4 = 16

6) Solve (15-25)²

15-25 = -10

(15-25)² = (-10)² = -10 * -10 = 100

Note

5-3 = 2

-5-3 = -8

-5+3 = -2

5+3 = 8

Probability Tree Diagram

Probability Tree Diagram 

A probability Tree Diagram  is simply a way of representing a sequence of events.

Tree diagram particularly illustrates the PROBABILITY since they record all the possible outcomes in a clear and uncomplicated way.

To draw the tree diagram:

• The first event is always represented by a dot.
• From the dot, the branches are drawn to represent all possible outcomes. That is, the outcomes of an event is usually written at the end of the branch
• The probability of each branch is written on the branches.
• We have to repeat the process for the number of events asked.

Example

1. Draw a Tree diagram For tossing a coin

Solution

Step 1:

The first event starts by dot.

           

Step 2:

From the dot, the branches are drawn to represent all possible outcomes.

when we toss a coin, the possible outcomes are heads and tails

let , heads = H

       tails = T

so,

Step 3 

here, we are tossing just a coin for once.

So now we can list out the possible outcomes.

Step 4:

Now, we have to write the outcomes probabilities on the corresponding branches.

That is, Probability of getting heads when toss a coin = 1/2

            Probability of getting tails when toss a coin = 1/2

Hence the above diagram represents the complete Tree Diagram when tossing a coin

Example 2 

1. Draw a Tree diagram For two tosses of a coin

Solution

Step 1:

The first event starts by dot.

Step 2:

From the dot, the branches are drawn to represent all possible outcomes.

when we toss a coin, the possible outcomes are heads and tails

let , heads = H

       tails = T

so,

Step 3:

here we are tossing twice, so again we have to list the possible outcomes for the second toss.

Even when we toss again the same possible outcomes we are going to get that is Heads and Tails.

Step 4 :

Now lets list out all the possible outcomes when we toss a coin twice.

 

Step 4 :

Now, we have to write the outcomes probabilities on the corresponding branches.

That is, Probability of getting heads when toss a coin = 1/2

            Probability of getting tails when toss a coin = 1/2

Step 5 :

Now lets write the probabilities of the final outcomes.

The final outcomes, that is sample space S= { (HH) , (HT) , (TH) , (TT) }

The probability of getting HH = 1/4

The probability of getting HT = 1/4

The probability of getting TH = 1/4

The probability of getting TT = 1/4

Probability

Experiment

    A  repeatable procedure with a set of possible results.

Example

 Tossing a coin , rolling a die 

Outcome

    An outcome is a possible result of an experiment.

Example

    Getting a head or a tail when we toss a coin. So head or tail are all outcomes.

    Getting 1 , 2 , 3 , 4 , 5 , 6 are all outcomes when we roll a die.

Event 

One or more possible outcomes of an experiment.

Example

    Getting a tail when tossing a coin (one outcome)

    Getting a 5  when rolling a die (one outcome)

    Getting an odd number when rolling a die. The possible outcomes are 1 , 3 , 5 (more than one outcome) 

Sample Space

    All the possible outcomes of an experiment. It is usually denoted by the letter S. It can be written using { } (set notation).

Example

    1.When tossing a coin, the possible outcomes are head or tail.

so, Sample space (S) = { Head , Tail }

Number of sample space can be written as n(S).

here, n(S) = 2

    2. When rolling a die, the possible outcomes are 1 , 2 , 3 , 4 , 5 , 6.

S = { 1 , 2 , 3 , 4 , 5 , 6 }

n(S) = 6 

Sample point

    Each one of the possible outcome of an event.

Example 

    1. If a die is rolled, the possible outcomes are S= { 1 , 2 , 3 , 4 , 5 , 6 }

here, there are 6 sample points such as 1 , 2 , 3 , 4 , 5 , 6.

    2. When tossing a coin the possible outcomes are S= { Head , Tail }

here, there are 2 sample points such as Head and Tail.

Probability

    Probability is simply how likely something is to happen . 

Probability(Event) = No.of favorable outcomes / Total no.of outcomes 

 Example

    1.When a coin is tossed , there are 2 possible outcomes. Head (H) and Tails (T). Find the probability of getting Head.

We can say that 

 Sample space (S) = { H ,T}

                  n(S) = 2 

let us assume 'A' be an event  getting head

A={H} 

n(A) = 1  [ n(A) means number of  possible event getting head]

Probability(Event) = No.of favorable outcomes / Total no.of outcomes 

that is here, 

Probability (getting head) = n(A) / n(S)     

                                          = 1 / 2

                                           = 0.5

                                  = 50% (to convert into percentage we have to multiply by 100, so 0.5)

Types of Events

     There are 5 types of events. They are 

             1. Certain Event

             2. Likely Event

             3. Equally Likely Event

             4. Unlikely Event

             5. Impossible Event

Certain Event

    An Event is certain , if it will always happen.

Example

A box contains 10 Red balls. Since all the balls are in Red,the outcome will always be a red ball. So picking a red ball from the box is Certain Event.

Likely Event

    An Event is Likely if it has good chances of happening.

Example

A box contains 10 Red balls and 2 Green balls. Since most of the balls are in Red, picking a red ball from the box has good chance of happening. So we can say it as Likely Event.

Equally Likely Event

    An event is equally likely if it has an even chance of happening.

Example

Getting head when tossing a coin

Unlikely Event

    An event is unlikely if it has a poor chance of happening.

Example

A box contains 10 Red balls and 2 Green balls. Since most of the balls are in Red, picking a green ball from the box has poor chance of happening. So we can say it as Unlikely Event.

Impossible Event

    An event is impossible if it will never happen or has no chance of happening.

Example

Getting a number greater than 7 is Impossible event, since the possible outcomes are

 { 1 , 2 , 3 , 4 , 5 , 6 }. 

 

Key Points

• The probability always lies from 0 to 1
• The total probability is always 1
• If Probability = 1, then the event is called as Certain
• If Probability = 0, then the event is called as Impossible
• If Probability = 1/2 = 0.5, then the event is called as Equally Likely
• If Probability lies between 0 and 1/2 (0 and 0.5), then the event is called as  Unlikely event
•  If Probability lies between 1/2 and 1, then the event is called as  Likely event

 

Class 6 : Chapter 6 : Exercise 6.1

1 . Write Opposites of the following :

a) Increase in weight
        Decrease in weight

b) 30km North
        30km South

c) 80m east
        80m West

d) Loss of Rs 700
         Profit of Rs 700

e) 100m above sea level
         100m below sea level


2. Represent the following numbers as integers with appropriate signs.

a) An aeroplane is flying at a height two thousand meter above the ground level.

  Solution

        Given, above the ground level  which implies +
   so, the given expression can be represent as +2000m

b) A submarine is moving at a depth , eight hundred meter below the sea level.

   Solution

        Given, below the sea level  which implies -
   so, the given expression can be represent as -800

c) A deposit of Rs 200. 

  Solution

        Given,  deposit which means saving so its +
    so, the given expression can be represent as + Rs 200

d) Withdrawal of Rs 700.

Solution

         Given,  withdrawal which means takingout so its -
    so, the given expression can be represent as -Rs 700

3 . Represent the following numbers on a number line.

a) +5
b) -10
c) +8
d) -1
e) -6

Solution

 

Exponents and the Laws of Exponents

Exponents

The Exponent of a number says how many times to use that number in a multiplication.
That is,
Exponents are the mathematical shorthand that tells us to multiply the same number by
itself for a specified number of times.

Example

The simpler way to write 5 * 5 * 5 * 5 * 5 * 5  as 5^6 or 56 .

Base : The number being multiplied by itself.
in our example, 5 the base .

Exponent : The number of times we are multiplying the base .
in our example , 6 is the exponent. Exponent are also called as power or index .  

Laws of Exponents 

1 . x ^ 1 = x  [ identity exponent ]

Example : 

• 5 ^ 1 = 5
• 8 ^ 1 = 8
• 0 ^ 1 = 0
• (-3) ^ 1 = -3 

2 . x ^ -n =( 1 / x)  ^ n [ Negative exponent ]

Note : 

x ^ -1 = 1 / x
( x / y ) ^ -n = ( y / x ) ^ n

Example

(5/3)^- 2 = (3/5)^2

                  = (3/5) * (3/5)
                  = (3*3) /( 5*5)
                  = 9 / 25 

3 . x ^ a * x ^ b = x ^ ( a + b ) [ product of powers ]

Example

3^2 * 3^3 = 3^(2+3)
  9   *  27    = 3^5
     243        = 243

4 . x ^ m / x ^ n = x ^ ( m - n ) [ Quotient of powers ]

Example

3 ^ 5 / 3 ^ 2 =  3 ^ ( 5 - 2 )
 243 /    9      =  3 ^ 3                    or         3*3*3*3*3 / 3*3 =  3 ^ 3
      27             =  27                        or                   3 * 3 * 3       =  27
                                                                                    27             =  27 

  5 . ( x ^ m ) ^ n = x ^ ( m * n )  [ power of power ]

Example

( 5 ^ 3 ) ^ 2  =  5 ^ ( 3 * 2 )
      125  ^ 2   =  5 ^ ( 6 )
       15,625    =  15,625

6 . ( x * y ) ^ m = (x ^ m) * (y ^ m) [ power of a product ]

Example

( 5 * 4 ) ^ 2  =  (5 ^ 2) * (4 ^ 2)
    20     ^ 2   =       25    *    16
         400      =           400

7 . ( x / y ) ^ m = x ^ m / y ^ m [ power of a quotient ]

Example

      (5/3)^2     =   (5^2) / (3^2)
(5/3) * (5/3)  =     25 / 9
    25 / 9          =    25 / 9

8 . x ^ 0 = 1   [ zero exponent ]

Note:
3/3 = 1
that is, 3^1/3^1 = 1  ( by law 4 )
                3^(1-1) = 1
                3^0 = 1

 
Example

•     5^0    =  1
• (1/5)^0 =  1

9 . x^(m/n) =  (x ^m)^1/n =             [Fractional exponent]

Example

5^(3/2) = (5^3) ^ (1/2)
               = 125 ^ (1/2)