Polynomials

Given one side is smaller than the other by 1 cm.

∴ The two adjacent sides of the triangle are x, x + 1.

(i) perimeter p(x) = 2 × [(x) + (x + 1)]

⇒ p(x) = 4x + 2 – (1)

(ii) Area a(x) = (x) × (x + 1)

⇒ a(x) = x² + x – (2)

(iii) by (1)

p(1) = 4 × 1 + 2 = 6

p(2) = 4 × 2 + 2 = 10

p(3) = 4 × 3 + 2 = 14

p(4) = 4 × 4 + 2 = 18

p(5) = 4 × 5 + 2 = 22

Here the difference between a number and its successor is always 4.

We can see that they are in Arithmetic Progression (AP) with a common difference of 4.

(iv) by (2)

a(1) = 1² + 1 = 2

a(2) = 2² + 2 = 6

a(3) = 3² + 3 = 12

a(4) = 4² + 4 = 20

a(5) = 5² + 5 = 30

Here the difference between a number and its previous number is increasing by 2.

a(2) – a(1) = 4

a(3) – a(2) = 6

a(4) – a(3) = 8

a(5) – a(4) = 10

∴ Their common difference is in AP.

(i) The side of the square = x

⇒ The dimensions of the box are

L = 7 – 2x

B = 5 – 2x

H = x

(ii) v(x) = L × B × H

⇒ v(x) = (7 - 2x) × (5 – 2x) × (x)

⇒ v(x) = (35 + 4x² -24x) × (x)

⇒ v(x) = 4x³ – 24x² + 35x – (1)

(iii) by (1)

⇒

⇒

Similarly,

v(1) = 4(1)³ – 24(1)² + 35(1)

⇒ v(1) = 15

And

⇒

According to the question the perimeter of the rectangle must be always equal to 100 cm.

Now, let one side be x cm and other adjacent side be y cm.

⇒ P = 2 × [x + y]

⇒ 100 = 2x + 2y

⇒ y = 50 – x – (1)

(i) a(x) = (50-x) × (x) – (by (1))

a(x) = 50x – x²

(ii) a(10) = 50 × (10) – (10)² = 400

a(40) = 50 × (40) – (40)² = 400

Now if a side a is 10 cm, then the other side

P = (10 + y) × 2

P = 100

⇒ 50 – 10 = y

⇒ y = 40 cm

∴ the in case of x = 10 cm y = 40 cm, and in case of x = 40 cm y = 10 cm. So, in both cases we have same rectangle hence the area is same.

Let the side of the ground be a.

The width of the path is 1 m.

⇒ Length of one side of the path is a + 2 m.

⇒ Area of the path = (a + 2)² – (a)²

Now, Area of the path is a is defined p(a)

⇒ p(a) = (a + 2)² – (a)²

⇒ p(a) = 4 + 4 × a

A liquid is 7 litres water and 18 litres acid.

Let x litres acid is added to this liquid.

Now,

The liquid is 7 litres water and (18 + x) litres acid.

Now,

Initial percentage of acid =

⇒ Initial percentage of acid = 72% -- (1)

Final percentage of acid = – (2)

Let change in percentage of the acid be R

⇒

Let the distance of the point on ground be x m from the 3 m pole.

⇒ This distance of the point on ground from 4 m pole is (5-x) m. (∵ the distance between the poles is 5 m.)

Now the length of the rope is AB + BC.

By Pythagoras Theorem

AB² = AD² + DB²

⇒ AB² = 3² + x²

⇒

Similarly,

Now, let the length of rope be a R

⇒ R = AB + BC

⇒

(i) Let the number be x.

So its reciprocal is

⇒

It is not a polynomial as it has a negative power of x, but for a polynomial all the powers should be positive integers.

(ii) Let the number be x.

So its square root is √x

Sum = x + √x

It is not a polynomial as it has square root which is fractional exponent, but to be a polynomial it should only have positive integer exponents.

(iii) Let sum of number and its square root be a.

⇒ a = x + √x

Let difference be b.

⇒ b = x - √x

Product of a and b.

⇒ a × b = (x + √x) × ( x - √x)

⇒ a × b = x² – x

It’s a Polynomial as all the exponents of x are positive integer.

let the polynomial be p(x)

p(x) = ax + b (where a and b are constants)

p(1) = a + b = 1 – (1) (given in the question)

p(2) = 2a + b = 3 – (2) (given in the question)

by (1) and (2)

a = 2, b = -1

⇒ p(x) = 2x – 1

Let the polynomial be p(x)

⇒ p(x) = ax + b

⇒ p(-1) = -a + b = -1 – (1)

⇒ p(-2) = -2a + b = 3 – (2)

By (1) and (2)

a = -4, b = -5

⇒ p(x) = -4x -5

Let the polynomial be p(x)

p(x) = ax² + bx + c (a,b,c are constants)

⇒ p(0) = c = 0

⇒ p(1) = a + b = 2 – (1)(∵ c = 0)

⇒ p(2) = 4a + 2b = 6 – (2)

By (1) and (2)

a = 1, b = 1

⇒ p(x) = x² + x

Let an arbitrary polynomial be p(x)

p(x) = ax² + bx + c

⇒ p(0) = c = 0

⇒ p(1) = a + b = 1

⇒ p(x) = ax² + bx (where a + b = 1)

There could be infinite number of such polynomials but we have to find only 3.

They are any three possible polynomials.

(i) p(10)

p(x) = 2x² + 3x + 5

p(10) = 2(10)² + 3(10) + 5

p(10) = 235 – (1)

(ii) q(10)

q(x) = x² + 4x + 1

q(10) = (10)² + 4(10) + 1

q(10) = 141 – (1)

(iii) s(x) = p(x) + q(x)

s(x) = 2x² + 3x + 5 + x² + 4x + 1

s(x) = 3x² + 7x + 6

s(10) = 3(10)² + 7(10) + 6

s(10) = 376

(iv) p(10) + q(10)

by (1) and (2)

p(10) + q(10) = 235 + 141

p(10) + q(10) = 376

This is the same result as (iii)

⇒ Polynomials have Commutative Property of Addition.

Let the required polynomial p(x)

Now, according to the question

x² + 4x – 5 + p(x) = 2x² – 3x + 1

⇒ p(x) = 2x² – 3x + 1 - x² - 4x + 5

⇒ p(x) = x² - 7x + 6

Let the required polynomial p(x)

Now, according to the question

x² + 4x – 5 – p(x) = 2x² – 3x + 1

⇒ p(x) = x² + 4x – 5 - 2x² + 3x – 1

⇒ p(x) = -x² + 7x – 6

p(x) + q(x) = x² – 4x + 1 – (1)

p(x) – q(x) = x² + 5x –2 – (2)

by adding (1) and (2)

2 × p(x) = 2x² + x –1

⇒

by (1)

q(x) = x² – 4x + 1 – p(x)

⇒

⇒

(i) p(x) = 3x² – 2x + 4

Now,

(x + 1) p(x) + (x – 1) p(x)

taking p(x) common

⇒ p(x)[x + 1 + x-1]

⇒ 2x × p(x)

⇒ 2x × (3x² – 2x + 4)

⇒ 6x³ – 4x² + 8x

(ii) p(x) = 3x² – 2x + 4

Now,

(x + 1) p(x) - (x – 1) p(x)

taking p(x) common

⇒ p(x)[x + 1-x + 1]

⇒ 2 × p(x)

⇒ 2 × (3x² – 2x + 4)

⇒ 6x² – 4x + 8

(iii) p(x) = 3x² – 2x + 4

Now,

taking p(x) common

⇒

⇒ p(x)

⇒ 3x² – 2x + 4