Ncert Solution Class 9 Maths Chapter 2 Exercise 2.2

\(P(x)=5 x-4 x^{2}+3\)
Now \(\mathrm{p}(a) \) will mean replacing the variable with the value that is put in the bracket.
\(\mathrm{p}(0)=5(0)-4(0)^{2}+3\)
\(\mathrm{p}(0)=0-0+3 \mathrm{p}(0)=3\)

\( P(x)=5 x-4 x^{2}+3 \)
Now \( \mathrm{p}(a) \) will mean replacing the variable with the value that is put in bracket.
\(\mathrm{p}(-1)=5(-1)-4(-1)^{2}+3\)
\(\mathrm{p}(-1)=-5-4+3\)
\(\mathrm{p}(-1)=-9+3\mathrm{p}(-1)=-6\)

\( \mathrm{p}(\mathrm{x})=5 \mathrm{x}-4 x^{2}+3 \)
Now \( \mathrm{p} (a)\) will mean replacing the variable with the value that is put in the bracket.
\(\mathrm{p}(2)=5(2)-4(2)^{2}+3 \)
\(\mathrm{p}(2)=10-16+3\)
\(\mathrm{p}(2)=-6+3 \mathrm{p}(2)=-3\)

\( \mathrm{p}(\mathrm{y})=y^{2}-y+1\)
\(\mathrm{P}(0)=(0)^{2}-(0)+1=1\)
\(\mathrm{P}(1)=(1)^{2}-(1)+1=1\)
\(\mathrm{P}(2)=(2)^{2}-(2)+1=3\)

\( p(t)=2+t+2 t^{2}-t^{3}\)
\(\mathrm{P}(0)=2+0+2(0)^{2}-(0)^{3}=2\)
\(\mathrm{P}(1)=2+(1)+2(1)^{2}-(1)^{3}\)
\(=2+1+2-1=4\)
\(\mathrm{P}(2)=2+2+2(2)^{2}-(2)^{3}\)
\(=2+2+8-8=4\)

\( \mathrm{p}(\mathrm{x})=x^{3} \)
\(\mathrm{p}(0)=(0)^{3}=0\)
\(\mathrm{p}(2)=(2)^{3}=8\)

\( \mathrm{p}(\mathrm{x})=(\mathrm{x}-1)(\mathrm{x}+1) \)
\(\mathrm{P}(0)=(0-1)(0+1)=(-1)(1)=-1\)
\(\mathrm{P}(1)=(1-1)(1+1)=0(2)=0\)
\(\mathrm{P}(2)=(2-1)(2+1)=1(3)=3\)

For any value of \( x \), say a, to be a zero of polynomial \(p(a)=0 \)
Keeping that in mind,
Here \( p(x)=3 x+1 \), for \( \mathrm{x}=-\frac{ 1 }{ 3 } \)
\(p\left(\frac{-1}{3}\right)=3 \times \frac{-1}{3}+1\)
\(p\left(\frac{-1}{3}\right)=-1+1\)
\(p\left(\frac{-1}{3}\right)=0\)
Therefore, \( x=-\frac{ 1 }{ 3 } \) is a zero of polynomial \( p(x)=3 x+1 \)

For any value of \( x \), say a, to be a zero of polynomial \(p(a)=0 \)
Keeping that in mind,
here \( p(x)=5 x-\pi \), for \(x=\frac{ 4 }{ 5 } \),
\(p\left(\frac{4}{5}\right)=5\left(\frac{4}{5}\right)-\pi=4-\pi\)
Since, \( p\left(\frac{4}{5}\right) \neq 0 \)
Therefore, \( \mathrm{x}=\frac{4}{5} \) is not a zero of polynomial \( \mathrm{p}(\mathrm{x})=5\mathrm{x}-\pi \)

For any value of \( x \), say a, to be a zero of polynomial \(p(a)=0 \)
Keeping that in mind,
If \( x=1 \) and \( x=-1 \) are zeros of polynomial \( p(x)=x^{2}-1 \) then \( p (1)\) and \( p(-1) \) should be 0
At, \( p(1)=(1)^{2}-1=0 \) and,
At, \( p(-1)=(-1)^{2}-1=0 \)
Hence, \( x=1 \) and \(-1\) are zeros of polynomial \( p(x)=x^{2}-1 \)

For any value of \( x \), say a, to be a zero of polynomial \(p(a)=0 \)
Keeping that in mind,
If \( x=-1 \) and \( x=2 \) are zeros of polynomial \( p(x)=(x+1)(x-2) \) then \( \mathrm{p}(-1) \) and \( \mathrm{p}(2) \) should be 0
At, \( p(-1)=(-1+1)(-1-2)=0(-3)=0 \) and,
At, \( p(2)=(2+1)(2-2)=3(0)=0 \)
Hence, \( x=-1 \) and \( x=2 \) are zeros of polynomial \( p(x)=(x+1)(x-2) \)

For any value of \( x \), say a, to be a zero of polynomial \(p(a)=0 \)
Keeping that in mind,
If \( x=0 \) is a zero of polynomial \( p(x)=x^{2} \)
Then, \( p(0) \) should be zero
Here, \( p(0)=(0)^{2}=0 \)
Hence, \( x=0 \) is the zero of the polynomial \( p(x)=x^{2} \)

For any value of \( x \), say a, to be a zero of polynomial \(p(a)=0 \)
Keeping that in mind,
If \( \mathrm{x}=\frac{-m}{l} \) is a zero of the polynomial \(\mathrm{p}(\mathrm{x})=l \mathrm{x}+\mathrm{m} \) then \( \mathrm{p}\left(\frac{-m}{l}\right) \)should be \(0\)
\(\mathrm{p}\left(\frac{-m}{l}\right) =l\left(\frac{-m}{l}\right)+\mathrm{m}\)
\(=-m+m\)
\(=0\)
Therefore, \( x=\frac{-m}{l} \) is the zero of the polynomial \( p(x)=1 \mathrm{x}+\mathrm{m}\).

For any value of \( x \), say a, to be a zero of polynomial \(p(a)=0 \)
Keeping that in mind,
If \( \mathrm{x}=\frac{-1}{\sqrt{3}} \) and \(\mathrm{x}=\frac{2}{\sqrt{3}} \) are zeros of the polynomial \( \mathrm{p}(\mathrm{x})=3 x^{2}-1\), then \( \mathrm{p}\left(\frac{-1}{\sqrt{3}}\right) \) and \(\mathrm{p}\left(\frac{2}{\sqrt{3}}\right) \) should be \(0\)
At, \(p\left(\frac{-1}{\sqrt{3}}\right)=3\left(\frac{-1}{\sqrt{3}}\right)^{2}-1\)
\(=3\left(\frac{1}{3}\right)-1\)
\(=1-1=0 \text { and, }\)
\(\text { At, } p\left(\frac{2}{\sqrt{3}}\right)=3\left(\frac{2}{\sqrt{3}}\right)^{2}-1\)
\(=3\left(\frac{4}{3}\right)-1\)
\(=4-1=3\)
Therefore \( \mathrm{x}=\left(\frac{-1}{\sqrt{3}}\right) \) is a zero of the polynomial \(\mathrm{p}(\mathrm{x})=3 x^{2}+1 \)But, \( x=\frac{2}{\sqrt{3}} \) is not a zero of the polynomial.

For any value of \( x \), say a, to be a zero of polynomial \(p(a)=0 \)
Keeping that in mind,
If \( \mathrm{x}=\frac{1}{2} \) is a zero of polynomial \(\mathrm{p}(\mathrm{x})=2 \mathrm{x}+1 \) then \( \mathrm{p}(\frac{ 1 }{ 2 }) \) should be zero
\(\text { At, } p\left(\frac{1}{2}\right)=2\left(\frac{1}{2}\right)+1\)
\(=1+1=2\)
Therefore, \( \mathrm{x}=\frac{1}{2} \) is not a zero of given polynomial \(\mathrm{p}(\mathrm{x})=2 \mathrm{x}+1 \)

Zero of a polynomial means the value of the variable at which the polynomial becomes zero.
For example for a polynomial \( f(x) \), zeroes of \( f(x) \) means the values of \( x \) at which \( f(x)=0 \)
Let \( f(x)=x+2 \), so it can clearly be seen that if you put \( x= -2\), then \( f(x)=0\)
\(\mathrm{p}(\mathrm{x})=\mathrm{x}+5\)
\(\mathrm{p}(\mathrm{x})=0\)
\(\mathrm{x}+5=0\)
\(\mathrm{x}=-5\)
Therefore, \( \mathrm{x}=-5 \) is a zero of the polynomial \( \mathrm{p(x)=x}+5 \)

Zero of a polynomial means the value of the variable at which the polynomial becomes zero.
For example for a polynomial \( f(x) \), zeroes of \( f(x) \) means the values of \( x \) at which \( f(x)=0 \)
Let \( f(x)=x+2 \), so it can clearly be seen that if you put \( x= \) \(-2\), then \( f(x)=0 \)
\( p(x)=x-5 \)
\(p(x)=0\)
\(x-5=0\)
\(x=5\)
Therefore, \( x=5 \) is a zero of the polynomial \( p(x)=x-5 \)

Zero of a polynomial means the value of the variable at which the polynomial becomes zero.
For example for a polynomial \( f(x) \), zeroes of \( f(x) \) means the values of \( x \) at which \( f(x)=0 \)
Let \( f(x)=x+2 \), so it can clearly be seen that if you put \( x= -2\), then \( f(x)=0 \)
\( p(x)=2 x+5\)
\(p(x)=0\)
\(2 x+5=0\)
\(2 x=-5\)
\(x=\frac{-5}{2}\)
Therefore, \( x=\frac{-5}{2} \) is a zero of the polynomial \( p(x)=2 x+5\)

Zero of a polynomial means the value of the variable at which the polynomial becomes zero.
For example for a polynomial \( f(x) \), zeroes of \( f(x) \) means the values of \( x \) at
which \( f(x)=0 \)
Let \( f(x)=x+2 \), so it can clearly be seen that if you put \( x= -2\), then \( f(x)=0 \)
\( \mathrm{p}(\mathrm{x})=3 \mathrm{x}-2\)
\(\mathrm{p}(\mathrm{x})=0\)
\(3 \mathrm{x}-2=0\)
\(\mathrm{x}=\frac{2}{3}\)
Therefore, \( x=\frac{2}{3} \) is a zero of the polynomial \( p(x)=3 x-2 \)

Zero of a polynomial means the value of the variable at which the
polynomial becomes zero.
For example for a polynomial \( f(x) \), zeroes of \( f(x) \) means the values of \( x \) at which \( f(x)=0 \)
Let \( f(x)=x+2 \), so it can clearly be seen that if you put \( x= -2\), then \( f(x)=0 \)
\(p(x)=3 x\)
\(p(x)=0\)
\(3 x=0\)
\(x=0\)
Therefore, \( \mathrm{x}=0 \) is a zero of the polynomial \( \mathrm{p}(\mathrm{x})=3
\mathrm{x} \)

Zero of a polynomial means the value of the variable at which the polynomial becomes zero.
For example for a polynomial \( f(x) \), zeroes of \( f(x) \) means the values of \( x \) at which \( f(x)=0 \)
Let \( f(x)=x+2 \), so it can clearly be seen that if you put \( x= -2\), then \( f(x)=0 \)
\(p(x)=a x\)
\(p(x)=0\)
\(a x=0\)
\(x=0\)
Therefore, \( x=0 \) is a zero of the polynomial \( p(x)=a x \)

Zero of a polynomial means the value of the variable at which the polynomial becomes zero.
For example for a polynomial \( f(x) \), zeroes of \( f(x) \) means the values of \( x \) at which \( f(x)=0 \)
Let \( f(x)=x+2 \), so it can clearly be seen that if you put \( x= -2\), then \( f(x)=0 \)
\( \mathrm{p}(\mathrm{x})=\mathrm{cx}+\mathrm{d}\)
\(\mathrm{p}(\mathrm{x})=0\)
\(\mathrm{cx}+\mathrm{d}=0\)
\(\mathrm{x}=-\frac{d}{c}\)
Therefore, \( \mathrm{x}=-\frac{d}{c} \) is a zero of polynomial \(\mathrm{p}(\mathrm{x})=\mathrm{cx}+\mathrm{d} \)