Multiplication of Polynomials Exercise 3.1.5-Class 9

1. If a + b + c = 0, prove the following:

(i) (b + c) (b – c) + a (a + 2b) = 0

Given a + b + c = 0 the a + b = -c, b + c = -a, c + a = -b we have

L.H.S = (b + c) (b – c) + a (a + 2b)

= (-a) (b – c) + a (a + b + b)

= -ab + ac + a (-c + b)

= -ab + ab – ac + ac

= 0= R.H.S

 

(ii) a (a² – bc) + b (b² – c) + c (c² – ab) = 0

L.H.S = a (a² – bc) + b (b² – c) + c (c² – ab)

= a³ – abc + b³ – abc + c³ – abc

= a³ + b³ + c³ – 3abc

We know that if a + b + c = 0 then

a³ + b³ + c³ = 3abc

Hence we have

= 3abc – 3abc

= 0 = R.H.S

 

(iii) a (b² + c²) + b (c² + a²) + c (a² + b²) = –3abc

L.H.S = a (b² + c²) + b (c² + a²) + c (a² + b²)

= ab² + ac²+ bc² + ba² + ca² +cb²

= ab² + ba² + b²c + bc² + ac² + a²c

= ab (a + b) + bc (b + c) + ac (a + c)

= ab (–c) + bc (–a) + ac (–b)

= –abc – abc – abc

= –3abc = R.H.S

[a + b + c =0, a + b = -c, b + c = -a, c + a = -b]

 

(iv) (ab + bc + ca)² = a²b² + b²c² + c²a²

L.H.S = (ab + bc + ca)²

= (ab)² + (bc)² + (ca)² +2ab.bc + ²bc. ca + ²ca.ab

= a²b² + b²c² + c²a² + 2ab²c + ²bc²a + ²ca²b

= a²b² + b²c² + c²a² + 2abc + (0)

= a²b² + b²c² + c²a² = R.H.S

 

(v) a² – bc = b² – ca = c² – ab = – (ab + bc + ca)

a.a – bc = a(-b-c)-bc = -ab-ac-ba = -(ab+bc+ca)——(1)

b² – ca = b.b – ca = b(-c-a)-ca = -bc-ab-ca = -(ab+bc+ca) ———-(2)

c² – ab = c.c – ab = c(-a-b) – ab = -ac-bc-ab = -(ab+bc+ca) ———-(3)

From equation (1) (2) and (3)

a² – bc = b² – ca = c² – ab = – (ab + bc + ca)

 

(vi) 2a² + bc = (a – b) (a –c)

L.H.S = 2a² + bc

= a² + a² + bc

= a² + a x a + bc

= a² + a (- b – c) + bc

= a² – ab – ac + bc

= a (a – b) – c (a – b)

= (a – b) (a –c) = R.H.S

 

(vii) (a + b) (a – b) + ca – cb = 0

We have a + b + c = 0

a + b = c

L.H.S = (a + b) (a – b) + ac – cb

= –c (a – b) + ac – cd

= – ca + bc + ac – cb

= 0 = R.H.S

 

(viii) a² + b² + c² = -2(ab + bc + ca)

We have a + b + c = 0

Squaring we get

(a + b + c)² = 0

a² + b² + c² + 2ab + 2bc +2ca = 0

a² + b² + c² = – 2ab – 2bc – 2ca

a² + b² + c² = – 2(ab + bc + ca)

Hence the proof

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2. Suppose a, b, c are non-zero real numbers such that a + b + c = 0,

Prove the following:

(i) 𝐚^𝟐/_𝐛𝐜 + 𝐛^𝟐/_𝐜𝐚 + 𝐜^𝟐/_𝐚𝐛 = 3

L.H.S = a²/_bc + b²/_ca + c²/_ab

= (a².a+b².b+c².c)/_abc

= (a³+b³+c³)/_abc ………. (1)

We have a + b + c = 0, a + b = –c

Cubing we get

(a + b)³ = (–c)³

a³ + b³ + 3ab + (a + b) = –c³

a³ + b³ – 3ab = –c³

a³ + b³ + c³ = 3abc ………. (2)

Substituting (2) in (1)

L.H.S = ^3abc/_abc = 3

(ii) ( ^+𝐛/_𝐜 + ^𝐛+𝐜/a + ^𝐜+𝐚/_𝐛 ) ( ^𝐛/_𝐜+𝐚 + ^𝐜/_𝐚+𝐛 + ^𝐚/_𝐛+𝐜 )

Whenever b + c ≠ 0, c + a ≠ 0, a + b ≠ 0

We have a + b + c =0

a + b = –c

b + c = –a

c + a = –b

L.H.S = (^𝐚+𝐛/_𝐜 + ^𝐛+𝐜/a + ^𝐜+𝐚/ ) ( ^𝐛/_𝐜+𝐚 + ^𝐜/_𝐚+𝐛 + ^𝐚/_𝐛+𝐜 )

= ( ^−c/_c + ^−a/_a + ^−a/_b ) ( ^b/_−b + ^c/_−c + ^a/_−a )

= (-1-1-1) (-1-1-1)

= (-3) (-3)

= 9 = R.H.S

 

(iii) 𝐚^𝟐/_𝟐𝐚^𝟐_+𝐛𝐜 + 𝐛^𝟐/_𝟐𝐛^𝟐_𝐜𝐚 + 𝐜^𝟐/_𝟐𝐜^𝟐_𝐚𝐛 = 1, provided the denominators do not become 0.

L.H.S = 𝐚^𝟐/_𝟐𝐚^𝟐_+𝐛𝐜 + 𝐛^𝟐/_𝟐𝐛^𝟐_𝐜𝐚 + 𝐜^𝟐/_𝟐𝐜^𝟐_𝐚𝐛

= 𝐚^𝟐/_(a-b)(a-c) + 𝐛^𝟐/_(b-c)(b-a) + 𝐜^𝟐/_(c-a)(c-b)

= 𝐚^𝟐/_(a-b)(a-c) – 𝐛^𝟐/_(a-b)(a-c + 𝐜^𝟐/_(a-c)(b-c)

= [a²(b−c)– b²(a−c) + c²(a−b)] /_{(a−b)(b−c)(a−c)}

= [a²b− a²c − b²a + b²c + c²a− c²b] /_{(ab− b}²_{− ac +bc) (a−c)}

= [a²b− a²c − b²a + b²c + c²a− c²b]/[a²b − ab²− a²c + abc − abc + b²c + ac²]

= 1 = R.H.S

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3. If a + b + c = 0, prove that b² – 4ac is a square.

We have a + b + c = 0

b = – (a + c)

Squaring on both sides

b² = [- (a + c)]²

= (a + c)²

b² = a² + c² + 2ac

Subtracting 4ac on both sides

b² – 4ac = a² + c² + 2ac – 4ac

= a² – 2ac + c²

b² – 4ac = (a – c)²

We find that b² – 4ac is the square of (a – c)

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4. If a, b, c are real numbers such that a + b + c = 2s, prove the following:

(i) s (s – a) + s (s – b) + s (s – c) = s²

L.H.S. = s (s – a) + s (s – b) + s (s – c)

= s² – as + s² – bs + s² – cs

= 3s² – as – bs – cs

= 3s² – s (a + b + c)

= 3s² – s (2s) (a + b + c = 2s)

= 3s² – 2s²

= s² = R.H.S.

 

(ii) s² (s – a)² + s (s – b)² + s (s – c)² = a² + b² + c²

L.H.S. = s² (s – a)² + s (s – b)² + s (s – c)²

= s² + s² + a² – ²sa + s² + b² + s² + c² – 2as – 2bs – 2cs

= 4s² + a² + b² + c² – 2s – 2bs – 2cs

= 4s² + a² + b² + c² – 2s (a + b + c)

= 4s² + a² + b² + c² – 2as (2s) (a + b + c = 2s)

= 4s² + a² + b² + c² – 4s²

= a² + b² + c²

= R.H.S.

 

(iii) (s – a) (s – b) + (s – b) (s – c) + (s – c) (s – a) + s² = ab + bc + ca

L.H.S. = (s – a) (s – b) + (s – b) (s – c) + (s – c) (s – a) + s²

= s² – as – bs + ab + s² – bs – cs + bc + s² – cs – as + ac + s²

= 4s² – 2 as – 2bs – 2cs + ab + bc +ca

= 4s² – 2s (a + b + c) + ab + bc +ca

= 4s² – 2s (2s) + ab + bc +ca

= 4s² – 4s2 + ab + bc +ca (a + b + c = 2s)

= ab + bc +ca

= R.H.S.

 

(iv) a² – b² – c² + 2bc = 4 (s – b) ( s – c)

L.H.S = a² – b² – c² + 2bc

= a² – (b² + c² – 2bc)

= a² – (b – c)²

= (a + b – c) [a – (b – c)]

= (a + b – c) (a + b – c)

= (2s – c – c) (2s – b – b)

= (2s – 2c) (2s – 2b)

= 2(s – c) (2) (s – b)

= 4 (s – c) (s – b)

= R.H.S.

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5. If a, b, c are real numbers, a + b + c =2s and s – a ≠ 0, s – b ≠ 0, s – c ≠ 0,

Prove that ^𝐚/_{(𝐬−𝐚)} + ^𝐛/_{(𝐬−𝐛)} + ^𝐜/_{(𝐬−𝐜)} + 2 = ^𝐚𝐛𝐜/_{(𝐬−𝐜)( 𝐬−𝐛) (𝐬−𝐜)}

L.H.S = ^a/_(s−a) + ^b/_(s−b) + ^c/_(s−c) + 2

=^{a(s−b)( s−c) + b(s−a)(s−c) + c(s−a)( s−b) + 2(s−a)(s−b)(s−c)}/ _{(s−a)(s−b)(s−c)}

= ^{[a(s-b)(s-c)+b(s-a)(s-c) +c(s-a)(s-b)+2(s-a)(s-b)(s-c)]} /_{(s−a )(s−b)(S−c)}

=[a(s²−bs−cs+bc) +b(s²−as−cs+ac) +c(s²−as−bs+ab) +2(s²−as−bs+ab)(s−c)] /_{(s−a)(s−b)(S−c)}

= [as²−abs−acs+abc+bs²−abc−bcs+abc) +cs²−acs−bcs+abc+2(s³−as²−bs²+abs −cs²+acs+bcs−abc] /_{(s−a)(s−b)(s−c)}

= [s²(a+b+c) − 2abc −2acs − 2bcs − 3abc + 2s³−2as²− 2bs² + 2abs−2cs²+ 2acs+2bcs−2abc] /_{(s−a)(s−b)(s−c)}

=  [s²(2s) + abc+2s³−2s² (a+b+c)]/_{(s−a)(s−b)(S−c)}

=[2s³+ abc+2s³−2s²(2s)]/_{(s−a) s−b (S−c)}

=[4s³+ abc−4s³]/_{(s−a)(s−b)(S−c)}

= ^abc/_{(s−a)(s−b)(S−c)}

= R.H.S.

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6. If a + b + c = 0, prove that a² – bc = b² – ca = c² – ab = (𝐚^𝟐 + 𝐛^𝟐+𝐜^𝟐)/_𝟐

We have a + b + c = 0

Squaring will get

(a + b + c)² = 0

a² + b² + c² + 2ab + 2bc + 2ca = 0

a² + b² + c² + 2b (a + c) + 2ca = 0

a² + b² + c² + 2b (-b) + 2ca = 0

a² + b² + c² = 2b² – 2ca                 (hint: a + c = -b)

a² + b² + c² = 2 (b² – ca)

a² + b² + c² = b² – ca ……… (1)

IIIly (a + b + c)² = 0

a² + b² + c² + 2ab + 2bc + 2ca = 0

a² + b² + c² + 2ab + 2c (b + a) = 0

a² + b² + c² + 2ab + 2c (-c) = 0 (a + c = -c)

a² + b² + c² = 2 (c² – ab)

[a² + b² + c²]/₂ = (c² – ab)……………(2)

Also a² + b² + c² + 2ab + 2bc + 2ca = 0

a² + b² + c² + 2a (b + c) + 2bc = 0

a² + b² + c² + 2a (-a) + 2bc = 0

a² + b² + c² = 2 (a² – bc) ……..(3)

From (1), (2) and (3) we get,

a² – bc = b² – ca = c² – ab = [a² + b² + c²]/₂

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7. If 2(a² + b²) = (a + b)², prove that a = b.

2a² + 2b² = a² + b² + 2ab

2a² + 2b² – a² – b² – 2ab = 0

a² + b² – 2ab = 0

(a – b)² = 0

a – b =0

a = b

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8. If x² – 3x + 1 = 0, prove that x² + ^𝟏/𝐱^𝟐 = 7.

Given x² – 3x + 1 = 0

x² + 1 = 3x

x + ¹/_x = 3 (dividing both sides by x)

Squaring both sides we get

(x + ¹/_x )² = 3² = x² + ¹/_x ² + 2x. ¹/_x = 9

x² + ¹/_x ² + 2 = 9

x² + ¹/_x ² = 9 – 2 = 7

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