Algebraic Expressions and Identities-NCERT Solutions

Class VIII Math
NCERT SOLUTIONS for ALGEBRAIC EXPRESSIONS

EXERCISE : 9.1

1. Construct the following quadrilaterals:

(i) Quadrilateral ABCD

(ii) Quadrilateral JUMP

1. Identify the terms, their coefficients for each of the following expressions:

(i) 5xyz² – 3zy

(ii) 1 + x + x²

(iii) 4x²y² – 4x²y²z² + z²

(iv) 3 – pq + qr – rp

(v)

(vi) 0.3 a – 0.6 ab + 0.5 b

Sol. (i) 5xyz² – 3zy

In the expression 5xyz² – 3zy, the terms are 5xyz² and –3zy.

coefficient of xyz² in the term 5xyz² is 5.

coefficient of zy in the term –3zy is –3.

(ii) 1 + x + x²

In the expression 1 + x + x², the terms are 1, x and x².

Coefficient of x° in the term 1 is 1.

Coefficient of x in the term x is 1.

Coefficient of x² is the term x² is 1.

(iii) In the expression 4x²y² – 4x²y²z² + z², the terms are 4x²y², –4x²y²z² and z².

Coefficient of x²y² in the term 4x²y² is 4.

Coefficient of x²y²z² in the term –4x²y²z² is –4.

Coefficient of z² in the term z² is 1.

(iv) 3 – pq + qr – rp

In the expression 3 – pq + qr – rp, the terms are 3, –pq, qr and –rp

Coefficient of x° in the term 3 is 3.

Coefficient pq in the term –pq is –1.

Coefficient qr in the term qr is 1.

Coefficient rp in the term –rp is 1.

(v) In the expression

the terms are

Coefficient of x in the term

Coefficient of y in the term

Coefficient of xy in the term – xy is – 1.

(vi) In the expression 0.3 a, – 0.6 ab and 0.5 b

Coefficient of a in the term 0.3a is 0.3.

Coefficient of ab in the term –0.6ab is

–0.6.

Coefficient of b in the term 0.5b is 0.5.

2. Classify the following polynomials as monomials, bionomials, trinomlals. Which polynomials do not fit in any of these three categories?

x + y, 1000, x + x² + x³ + x⁴, 7 + y + 5x,

²y – 3y², 2y – 3y² + 4y³, 5x – 4y + 3xy,

4z – 15z²,

ab + bc + cd + da, pqr, p²q + pq², 2p + 2q.

Sol. The given polynomials are classified as under:

Monomials: 1000, pqr

Binomials: x + y, 2y – 3y², 4z – 15z², p²q + pq², 2p + 2q.

Trinomials: 7 + y + 5x, 2y – 3y² + 4y³,

5x – 4y + 3xy.

Polynomials that do not fit in any categories:

x + x² + x³ + x4, ab + bc + cd + da

3. Add the following:

(i) ab – bc, bc – ca, ca – ab

(ii) a – b + ab, b – c + bc, c – a + ac

(iii) 2p²q² – 3pq + 4, 5 + 7pq – 3p²q²

(iv) l² + m², m² + n², n² + l², 2lm + 2mn + 2nl

Sol. (i) Writing the given expressions in separate rows with like terms one below the other, we have

(ii) Writing the given expressions in separate rows with like terms one below the other, we have

(iii) Writing the given expressions in separate rows with like terms one below the other, we have

(iv) Writing the given expressions in separate rows with like terms one below the other, we have

4. (a) Subtract 4a – 7ab + 3b + 12

from 12a – 9ab + 5b – 3

(b) Subtract 3xy + 5yz – 7zx

from 5xy – 2yz – 2zx + 10xyz

from 18 – 3p – 11q + 5pq – 2pq² + 5p²q.

Sol. Rearranging the terms of the given expressions, changing the sign of each term of the expression to be subtracted and adding the two expressions, we get.

(b) Rearranging the terms of the given expressions, changing the sign of each term of the expression to be subtracted and adding the two expressions, we get.

(c) Rearranging the terms of the given expressions, changing the sign of each term of the expression to be subtacted and adding the two expressions, we get.

EXERCISE : 9.2

1. Find the product of the following pairs of monomials

(i) 4, 7p (ii) – 4p, 7p

(iii) – 4p, 7pq (iv) 4p³, – 3p

(v) 4p, 0

Sol. (i) 4 × 7p = (4 × 7) × p = 28p

(ii) – 4p × 7p = (– 4 × 7) × (p × p)

= 28 p¹⁺¹

= 28p²q

(iii) –4p × 7pq = (–4 × 7) × (p × p × q)

= – 28p¹⁺¹q

= – 28p²q

(iv) 4p³ × (–3p) = {4 × (–3)} × (p³ × p)

= – 12 × p³+1

= –12p⁴

(v) 4p × 0 = (4 × 0) × (p)

= 0 × p

= 0.

2. Find the areas of rectangles with the following pairs of monomials as their lengths and breadths respectively:

(p, q); (10m, 5n); (20x², 5y²); (4x, 3x²);

(3mn, 4np)

Sol. We know that the area of a rectangle = l × b, where l = length and b = breadth.

Therefore, the areas of rectangles with pair of monomials (p, q); (10m, 5n); (20x², 5y²);

(4x, 3x²) and (3mn, 4np) as their lengths and breadths are given by

p × q = pq

10m × 5n = (10 × 5) × (m × n) = 50mn

20x² × 5y² = (20 × 5) × (x² × y²)

= 100x²y²

4x × 3x² = (4 × 3) × (x × x²)

= 12x³

and, 3mn × 4np = (3 × 4) × (m × n × n × p)

= 12mn²p

3. Complete the table of products:

Sol. Complete table is as under:

4. Obtain the volume of rectangular boxes with the following length, breadth and height respectively:

(i) 5a, 3a², 7a⁴ (ii) 2p, 4q, 8r

(iii) xy, 2x²y, 2xy² (iv) a, 2b, 3c

Sol. (i) Required volume = 5a × 3a² × 7a⁴

= (5 × 3 × 7) × (a × a² × a⁴)

= 105a¹+2+4 = 105a⁷

(ii) Required volume = 2p × 4q × 8r

= (2 × 4 × 8) × (p × q × r)

= 64 pqr.

(iii) Required volume = xy × 2x²y × 2xy²

= (1 × 2 × 2) × (xy × x²y × xy²)

= (4) × (x¹+2+1 × y¹+1+2)

= 4x⁴y⁴

(iv) Required volume = a × 2b × 3c

= (1 × 2 × 3) × (a × b × c)

= 6abc

5. Obtain the product of

(i) xy, yz, zx (ii) a, –a², a³

(iii) 2, 4y, 8y², 16y³ (iv) a, 2b, 3c, 6abc

(v) m, – mn, mnp

Sol. (i) xy × yz × zx = x × x × y × y × z × z

= x¹+1 xy¹+1 × y¹+1 × z¹+1

= x²y²z²

(ii) a × (–a²) × a³

= [1 × (–1) × 1] × (a × a × a × a × a × a)

= (–1) × (a⁶)

= –a⁶

(iii) 2 × (4y) × 8y² × 16y³

= (2 × 4 × 8 × 16) × (y × y² × y³)

= (1024) × (y¹ + 2 + 3)

= 1024y⁶

(iv) a × 2b × 3c × 6abc

= (2 × 3 × 6) × (a × b × c × abc)

= (36) × (a¹⁺¹ × b¹⁺¹ × c¹⁺¹⁾

= 36a²b²c²

(v) m × – mn × mnp

= (1 × – 1 × 1)× (m × m × m × n × n × p)

= –1 × m³ × n² × p

= – m³n²p

EXERCISE : 9.3

1. Carry out the multiplication of the expression in each of the following pairs:

(i) 4p, q + r

(ii) ab, a – b

(iii) a + b, 7a²b²

(iv) a² – 9, 4a

Sol. (i) 4p × (q + r)

= 4p × q + 4p × r

= 4pq + 4pr

(ii) ab × (a – b)

ab × a – ab × (b)

= a²b – ab²

(iii) (a + b) × (7a²b²)

= 7a²b² × a + 7a²b² × b

= 7a³b² + 7a²b³

(iv) (a²

– 9) × 4a

= a²

× 4a – 9 × 4a

4a³ – 36a

(v) (pq + qr + rp) × 0 = 0

2. Complete the table

Sol. (i) a(b + c + d)

= a × b + a × c + a × d

= ab + ac + ad

(ii) (x + y – 5) × (5xy)

= 5xy × x + 5xy × y + 5xy × (–5)

= 5x²y + 5xy²

– 25xy

(iii) 6p³ – 7p² + 5p

4p⁴q² – 4p²q⁴

(iv) 4p⁴q² – 4p²q⁴

(v) a²bc + ab²c + abc²

3. Find the product:

(i) (a²) × (2a²2) × (4a²6)

(iv) x × x² × x³ × x⁴

Sol. (i) (a²) × (2a²2) × (4a²6)

= (1 × 2 × 4) × (a² × a²² × a²⁶)

= 8a^{2 + 22 + 26} = 8a⁵⁰

4. (a) Simplify : 3x(4x – 5) + 3 and find its value for

(b) Simplify : a(a² + a + 1) + 5 and find its value for (i) a = 0, (ii) a = 1, (iii) a = – 1

Sol. (a) We have,

3x(4x – 5) + 3

= 3x × 4x – 3x × 5 + 3

= 12x² – 15x + 3

(i) When x = 3, then

3x(4x – 5) + 3

= 3 × 3(4 × 3 – 5) + 3

= 12x² – 15x + 3

= 9(12 – 5) + 3 = 9 × 7 + 3

= 63 + 3 = 66

(ii) When

then 3x(4x – 5) + 3

(b) We have,

a(a² + a + 1) + 5

= a × a² + a × a + a × 1 + 5

= a³ + a² + a + 5

(i) a(a² + a + 1) + 5

= 0(02 + 0 + 1) + 5

= 0(1) + 5

= 0 + 5 = 5.

(ii) When a = 1, then

a(a² + a + 1) + 5

= (12 + 1 + 1) + 5

= 1(1 + 1 + 1) + 5

= 1(3) + 5 = 3 + 5 = 8.

(iiI) When a = –1, then

a(a² + a + 1) + 5

= –1[(–1)² + (–1) + 1] + 5

= –1(1 –1 + 1) + 5

= –1(1) + 5 = –1 + 5 = 4

5. (a) Add : p(p – q), q(q – r) and r(r – p)

(b) Add : 2x(z – x – y) and 2y(z – y – x)

(d) Subtract : 3a(a + b + c) – 2b(a – b + c) from 4c(–a + b + c)

Sol. (a) p(p – q) + q(q – r) + r(r – p)

= p × p – p × q + q × q – q × r + r × r – r × p

= p² – pq + q² – qr + r² – pr

= p² + q² + r2 – pq – qr – pr

(b) 2x(z – z – y) + 2y(z – y – x)

= (2x × z) – (2x × x) – (2x × y)

+ (2y × z) – (2y × y) – (2y × x)

= 2xz – 2x² – 2xy + 2yz – 2y² – 2xy

= – 2x² – 2y² – 4xy + 2xz + 2yz.

= (4l × 10n) – (4l × 3m) + (4l × 2l) + (–3l × l) + (–3l × –4m) + (–3l × 5n)

= 40ln – 12lm + 8l2 – 3l2 + 12lm – 15ln

= 5l2 + 25ln

(d) 4c(–a + b + c) – {3a(a + b + c) – 2b(a – b + c)}

= {4c × (–a) + 4c × b + 4c × c}

– {(3a × a + 3a × b + 3a × c)} +

{(–2b × a) + (–2b × –b) + (–2b × c)}

= –4ac + 4bc + 4c²|

–{3a² + 3ab + 3ac – 2ab + 2b² – 2bc}

= –4ac + 4bc + 4c² – 3a² – 3ab – 3ac + 2ab – 2b² + 2bc

= –3a² – 2b² + 4c² – 7ac + 6bc – ab

EXERCISE : 9.4

1. Multiply the binomials:

(i) (2x + 5) and (4x – 3)

(ii) (y – 8) and (3y – 4)

(iii) (2.51 – 0.5m) and (2.51 + 0.5m)

(iv) (a + 3b) and (x + 5)

(v) (2pq + 3q²) and (3pq – 2q²)

(vi)

Sol. (i) (2x + 5) and (4x – 3)

= 2x(4x – 3) + 5(4x – 3)

= 8x² – 6x + 20x – 15

(ii) (y – 8) × (3y – 4)

= y(3y – 4) –8(3y – 4)

= 3y² – 4y – 24y + 3\2

= 3y² – 28y + 32

(iii) (2.5l – 0.5m) × (2.5l + 0.5m)

= 2.5l(2.5l + 0.5m) – 0.5m(2.51 + 0.5m)

= 6.25l2 + 1.25lm – 1.25lm – 0.25m²

= 6.25l2 – 0.25m²

(iv) (a + 3b) × (x + 5)

= a(x + 5) + 3b(x + 5)

= ax + 5a + 3bx + 15b

= ax + 3bx + 5a + 15b

(v) (2pq + 3q²) × (3pq – 2q²)

= 2pq(3pq – 2q²) + 3q²(3pq – 2q²)

= 6p²q² – 4pq³ + 9pq³ – 6q⁴

= 6p²q²

+ 5pq³ – 6q⁴

2. Find the product:

(i) (5 � 2x)(3 + x)

(ii) (x + 7y)(7x � y)

(iii) (a² + b)(a + b²)

(iv) (p² � q²)(2p + q)

Sol. (i) (5 � 2x)(3 +x)

= 5(3 + x) � 2x(3 + x)

= 15 + 5x � 6x � 2x²

= �2x² � x + 15

(ii) (x + 7y)(7x � y)

= x(7x � y) + 7y(7x � y)

= 7x² � xy + 49 xy � 7y²

= 7x² + 48xy � 7y²

(iii) (a² + b)(a +b²)

= a²(a +b²) + b(a + b²)

= a³ + a²b² + ab + b³

(iv) (p² � q²)(2p + q)

= p²(2p + q) � q²(2p + q)

= 2p³ + p²q � 2pq² � q³

3. Simplify:

(i) (x² � 5)(x + 5) + 25

(ii) (a² + 5)(b³ + 3) + 5

(iii) (t + s²)(t² � s)

(iv) (a + b)(c � d) + (a � b)(c + d) + 2(ac + bd)

(v) (x + y)(2x + y) + (x + 2y)(x � y)

(vi) (x + y)(x² xy + y²)

(vii) (1.5x � 4y)(1.5x + 4y + 3) � 4.5x + 12y

(viii) (a + b + c)(a + b � c)

Sol. (i) (x² � 5)(x + 5) + 25

= x²(x + 5) � 5(x + 5) + 25

= x³ + 5x² � 5x � 25 + 25

= x³ + 5x² � 5x

(ii) (a² + 5)(b³ + 3) + 5

= a²(b³ + 3) + 5(b³ + 3) + 5

= a²b² + 3a² + 5b³ + 15 + 5

= a²b³ + 3a² + 5b³ + 20

(iii) (t + s²)(t² � s)

= t(t² � s) + s²(t² � s)

= t³ � ts + s²t² � s³

(iv) (a + b)(c � d) + (a � b)(c + d) + 2(ac + bd)

= a(c � d) + b(c � d) + a(c + d) � b(c + d) + 2ac + 2bd

= ac � ad + bc � bd + ac + ad � bc � bd + 2ac + 2bd

= 4ac

(v) (x + y)(2x + y) + (x + 2y)(x � y)

= x(2x + y) + y(2x + y) + x(x � y) + 2y(x � y)

= 2x² + xy + 2xy + y² + x² � xy + 2xy � 2y²

= (2 + 1)x² + (1 + 2 � 1 + 2)xy + (1 � 2)y²

= 3x² + 4xy � y²

(vi) (x + y)(x² � xy + y²)

= x(x² � xy � y²) + y(x² � xy + y²)

= x³ � x²y + xy² + x²y � xy² +y³

= x³ + y³

(vii) (1.5x � 4y)(1.5x + 4y + 3) � 4.5x + 12y

= 1.5x(1.5x + 4y + 3) � 4y(1.5x + 4y + 3) � 4.5x + 12y

= 1.5x � 1.5x + 1.5x � 4y + 1.5x � 3 � 4y � 1.5x � 4y � 4y � 4y � 3 � 4.5x + 12y

= 2.25x² + 6xy + 4.5x � 6xy �16y² � 12y � 4.5x + 12y

= 2.25x² + (6 � 6)xy + (4.5 � 4.5)x � 16y² + (�12 + 12)y

= 2.25x² + (0)xy + (0)x � 16y² + (0)y

= 2.25x² + 0 + 0 � 16y² + 0

= 2.25x² � 16y²

(viii) (a + b + c)(a + b � c)

= a(a + b � c) + b(a + b � c) + c(a + b � c)

= a² + ab � ac + ab + b² � bc + ac + bc � c²

= a² + 2ab + b² � c²

EXERCISE : 9.5

1. Use a suitable identity to get each of the following products.

(i) (x + 3)(x + 3)

(ii) (2y + 5)(2y + 5)

(iii) (2a – 7)(2a – 7)

(iv)

(v) (1.1m – 0.4)(1.1m + 0.4)

(vi) (a² + b²)(–a² + b²)

(vii) (6x – 7)(6x + 7)

(viii) (–a + c)(–a + c)

(ix)

(x) (7a – 9b)(7a – 9b)

Sol. (i) (x + 3)(x + 3)

= x² + (3 + 3)x + (3)(3)

[Using: (x + a)(x + b) = x² + (a + b)x + ab]

= x² + 6x + 9

(x +3)(x + 3) = (x + 3)²

= x² + 2(3)x + (3)^2|

[Using: (a + b)2 = a² + 2ab + b²]

= x² + 6x + 9.

(ii) (2y + 5)²

= (2y)² + 2(2y)(5) + (5)²

{Using : (a + b)² = a² + 2ab + b²}

= 4y² + 20y + 25.

(iii) (2a – 7)²

= (2a)² – 2(2a)(7) + (7)²

{Using : (a – b)² = a² – 2ab + b²}

= 4a² – 28a + 49

(iv)

(v) (1.1m – 0.4)(1.1m + 0.4)

= (1.1m)² – (0.4)²

[Using: (a – b)(a + b) = a² – b²] = 1.21m² – 16

(vi) (a² + b²)(– a² + b²) = (b² + a²)(b² – a²)

= (b²)2 – (a²)²

[Using: (a + b)(a – b) = a² – b²]

= b⁴ – a⁴

(vii) (6x – 7)(6x + 7) = (6x)² – (7)²

{Using: (a – b)(a + b) = a² – b²}

= 36x² – 49

(viii) (–a + c)(–a +c)

= (–a + c)² or (c – a)²

= (c)² – 2(c)(a) + (a)²

{Using: (a – b)² = a² – 2ab + b²}

= c² – 2ac + a²

(ix)

(x) (7a – 9b)(7a – 9b) = (7a – 9b)²

= (7a)² – 2(7a)(9b) + (9b)²

{Using: (a – b)² – 2ab + b²}

= 49a² – 126ab + 81b²

2. Use the identity (x + a)(x + b)

= x² + (a + b)x + ab to find the following products.

(i) (x + 3)(x + 7)

(ii) (4x + 5)(4x + 1)

(iii) (4x – 5)(4x – 1)

(iv) (4x + 5)(4x – 1)

(v) (2x + 5y)(2x + 3y)

(vi) (2a² + 9)(2a² + 5)

(vii) (xyz – 4)(xyz – 2)

Sol. (i) (x + 3)(x + 7)

= x² + (3 + 7)x + 3 × 7

= x² + 10x + 21

(ii) (4x + 5)(4x + 1)

= (4x)² + (5 + 1)4x + (5)(1)

= 16x² + 24x + 5.

(iii) (4x – 5)(4x – 1)

= [4x + (– 5)][4x + (–1)]

= (4x)² + [(–5) + (–1)]4x + (–5)(–1)

= 16x² + (–5–1)4x + 5

= 16x² – 24x + 5.

(iv) (4x + 5)(4x – 1)

= (4x + 5)(4x + (–1))

= (4x)² + [5 + (–1)](4x) + (5)(–1)

= 16x² + 16x – 5

(v) (2x + 5y(2x + 3y)

= (2x)² + (5y + 3y)²x + (5y)(3y)

= 4x² + (8y)(2x) + 15y²

= 4x² + 16xy + 15y²

(vi) (2a² + 9)(2a² + 5)

= (2a²)² + (9 + 5)²a² + (9)(5)

= 4a² + 28a² + 45

(vii) (xyz – 4)(xyz – 2)

= (xyz)² + (– 4 – 2)(xyz) + (–4)(–2)

= x²y²z² – 6xyz + 8

3. Find the following squares by using the identities:

(i) (b – 7)²

(ii) (xy + 3z)²

(iii) (3x² – 5y)²

(iv)

(v) (0.4p – 0.5q)²

(vi) (2xy + 5y)²

Sol. (i) (b – 7)²

= b² – 2(7)b + (7)²

= b² – 14b + 49

(ii) (xy + 3z)²

= (xy)² + 2(xy)(3z) + (3z)²

{Using: (a + b)² = a² + 2ab + b²}

= x²y² + 6xyz + 9z²

(iii) (3x² – 5y)²

= (3x²)² – 2(3x)²(5y) + (5y)²

{Using: (a – b)² = a² – 2ab + b²}

= 9x⁴ – 30x²y + 25y²

(iv)

(v) (0.4p � 0.5q)²

= (0.4p)² � 2(0.4p)(0.5q) + (0.5q)²

= 0.16p² � 0.4pq + 0.25q²

(vi) (2xy + 5y)²

(2xy)² + 2(2xy)(5y) + (5y)²

[Using: (a + b)² = a² + 2ab + b²}

= 4x²y² + 20xy² + 25y²

4. Simplify:

(i) (a² � b²)²

(ii) (2x + 5)² � (2x � 5)²

(iii) (7m � 8n)² + (7m + 8n)²

(iv) (4m + 5n)² + (5m + 4n)²

(v) (2.5p � 1.5q)² � (1.5p � 2.5q)²

(vi) (ab + bc)² � 2ab²c

(vii) (m² � n²m)² + 2m³n²

Sol. (i) (a² � b²)

= (a²)² � 2(a²)(b²) + (b²)²

[Using: (a � b)² = a² � 2ab + b²)

= a⁴ � 2a²b² + b⁴

(ii) (2x + 5)² � (2x � 5)²

{(2x)² + 2(2x)(5) + (5)²} � {(2x)² � 2(2x)(5) + (5)²}

{Using: (a + b)² = a² + 2ab + b² and (a � b)² = a² � 2ab + b²}

= (4x² + 20x + 25) � (4x² � 20x + 25)

= 4x² + 20x + 25 � 4x² + 20x � 25

= 40x

(iii) (7m � 8n)² + (7m + 8n)²

= (49m² � 112mn + 64n²)

+ (49m² + 112mn + 64n²)

= 49m² � 112mn + 64n²

+ 49m² + 112m + 64n²

= 98m² + 128n²

(iv) (4m + 5n)² + (5m + 4n)²

= {(4m)² + 2(4m)(5n) + (5n)²}

+{(5m)² + 2(5m)(4n) + (4n)²}

= 16m² + 40mn + 25n² + 25m² + 40 mn + 16n²

= 16m² + 25m² + 25n² + 80mn + 16n²

= 41m² + 80mn + 41n².

(v) (2.5p � 1.5q)² � (1.5p � 2.5q)²

= (6.25p² � 7.5pq + 2.25q²)

� (2.25p² � 7.5pq + 6.25q²)

= (6.25 � 2.25)p² + (�7.5 + 7.5)pq

+ (2.25 � 6.25)q²

= 4p² + (0)pq � 4q = 4p² � 4q²

(vi) (ab + bc)² � 2ab²c

= (ab)² + 2(ab)(bc) + (bc²) � 2ab²c

= a²b² + 2ab²c + b²c² � 2ab²c

= a²b² + b²c²

(vii) (m² – n²m)² + 2m³n²

= {(m²)² – 2(m²)(n²m) + (n²m)²} + 2m³n²

= m⁴ – 2m³n² + m²n⁴ + 2m³n²

= m⁴ + m² n⁴

5. Show that:

(i) (3x + 7)² – 84x = (3x – 7)²

(ii) (9p – 5q)² + 180pq = (9p + 5q)²

(iii)

(iv) (4pq + 3q)² – (4pq – 3q)² = 48pq²

(v) (a – b)(a + b) + (b – c)(b + c)

+ (c – a)(c + a) = 0

Sol. (i) LHS = (3x + 7)² – 84x

= (9x² + 42x + 49) – 84x

= 9x² – 42x + 49

= (3x)² – 2(3x)(7) + (7)²

= (3x – 7)² = RHS

(ii) LHS = (9p – 5q)² + 180 pq

= {(9p)² – 2(9p)(5q) + (5q)²} + 180 pq

= 81p² – 90pq + 25p² + 180 pq

= 81p² + 90pq + 25q²

= (9p)² + 2(9p)(5q⁰ + (5q)²

= (9p + 5q)² = RHS.

(iii)

(iv) LHS = (4pq + 3q)² � (4pq � 3q)²

= {(4pq)² + 2(4pq)(3q) + (3q)²}

� {(4pq)² � 2(4pq)(3q) + (3q)²}

= {16p²q² + 24pq² + 9q²}

� {16p²q² � 24pq² + 9q²}

= 16p²q² + 24pq² + 9q² � 16p²q²

+ 24pq² � 9q²

= 48pq² = RHS

(v) LHS = (a � b)(a + b) + (b � c)(b + c)

+ (c � a)(c + a)

= a² � b² + b² � c² + c² � a²

= (a² � a²) + (�b² + b²) + (�c² + c²)

= 0 + 0 + 0 = 0 = RHS

6. Using identities, evaluate:

(i) 712 (ii) 992 (iii) 1022

(iv) 9982 (v) 5.22 (vi) 297 × 303 (vii) 78 × 82 (viii) 8.92 (ix) 1.05 × 9.5

Sol. (i) 71²

= (70 + 1)² = (70)² + 2 × 70 × 1 + (1)²

{Using: (a + b)² = a² + 2ab + b²)

= 4900 + 140 + 1 = 5041

(ii) 99²

= (100 – 1)²

= (100)² – 2 × 100 × 1 + (1)²

[Using: (a – b)² = a² – 2ab + b²)

= 10000 – 200 + 1 = 9801

(iii) 102² = (100 + 2)²

= (100)² + 2(100)(2) + (2)²

[∵ (a – b)² = a² – 2ab + b²]

= 10000 + 4000 + 4 = 10404

(iv) 998²

= (1000 – 2)3

= (1000)² – 2(1000)(2) + (2)²

[∵ (a – b)² = a² – 2ab + b²]

= 1000000 – 4000 + 4 = 996004

(v) (5.2)²

= (5.0 + 0.2)²

= (5.0)² + 2(5.0)(0.2) + (0.2)²

[∵ (a + b)² = a² + 2ab + b²]

= 25 + 2 + 0.01 = 27.04

(vi) 297 × 303

= (300 – 3) × (300 + 3)

= (300)² – (3)²

[Using: (a – b)(a + b) = a² – b²]

= 90000 – 9 = 89991

(vii) 78 × 82

= (80 – 2)(80 +2)

= (80)² – (2)²

[∵ (a + b)(a – b) = a² – b²]

= 6400 – 4 = 6396

(viii) 8.92

= (9 – 0.1)²

= (9)² – 2(9)(0.1) + (0.1)²

[Using: (a – b²) = (a² – 2ab + b²]

= 81 – 1.8 + 0.01 = 79.21

(ix) 1.05 × 9.5

= 1.05 × 0.95 × 10

= (1 + 0.05)(1 – 0.05) × 10

= [(1)² – (0.05)²] × 10

= [1 – 0.0025] × 10

[∵ (a + b)(a – b) = a² – b²]

= 0.9975 × 10 = 9.975

7. Using a² � b² = (a + b)(a � b)(a � b), find

(i) 51² � 49²

(ii) (1.02)² � (0.98)²

(iii) 153² � 147²

(iv) 12.1² � 7.9²

Sol. (i) 51² � 49²

= (51 + 49) (51 � 49)

= (100)(2) = 200

(ii) (1.02)² � (0.98)²

= (1.02 + 0.98)(1.02 � 0.98)

= (2)(0.04) = 0.08

(iii) 153² � 147²

= (153 + 147)(153 � 147)

= (300)(60) = 1800

(iv) 12.1² � 7.9²

= (12.1 + 7.9)(12.1 � 7.9)

= (20.0)(4.2) = 84

8. Using (x + a)(x = b)

= x² + (a + b)x + ab, find

(i) 103 � 104

(ii) 5.1 � 5.2

(iii) 103 � 98

(iv) 9.7 � 9.8

Sol. (i) 103 � 104

= (100 + 3)(100 + 4)

= (100)² + (3 + 4)(100) + (3)(4)

= 10000 + 700 + 12 = 10712

(ii) 5.1 � 5.2 = (5 + 0.1)(5 + 0.2)

= (5)² + (0.1 + 0.2)(5) + (0.1)(0.2)

= 25 + 1.5 + 0.02 = 26.52

(iii) 103 � 98 = (100 + 3)(100 � 2)

= (100)² + [3 + (�2)](100) + (3)(�2)

= 10000 + 100 � 6

= 10094

(iv) 9.7 � 9.8 = (10 � 0.3)(10 � 0.2)

= (10)² + [(�0.3) + (�0.2)](10)

+ (�0.3)(�0.2)

= 100 + (�0.5)10 + 0.06 = 100.06 � 5

= 95.06