PARAGRAPH If the measurement errors in all the independent quantities are known- then it is possible to determine the error in any dependent quantity- This is done by the use of series expansion and truncating the expansion at the first power of the error- For example- consider the relation z - x - y- If the errors in x - y and Z are - x - - y and - z- respectively- then z - z - x - x - y - y - x - y 1 - x - x 1 - y - y -1The series expansion for 1 - y-y-1- to first power in - y - y is 1 - y - y- The relative errors in independent variables are always added- So the error in Z will be - z - z - x - x - y - y The above derivation makes the assumption that - x - x - 1- - y - y - 1- Therefore- the higher powers of these quantities are neglected-In an experiment the initial number of radioactive nuclei is 3000 - It is found that 1000 - 40 nuclei decayed in the 1-0 s- For - x -1- ln 1- x-x up to first power in x- The error - in the determination of the decay constant - in s -1 isA- 0-04B- 0-03C- 0-02D- 0-01

N = N_o e ^ λ t ln N = lnN_o λ t dNN = λ t Converting to error Δ NN = Δλ t Δλ = 402000 × t = 0.02 ...

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Standard XII

Physics

Finding Average Velocity

PARAGRAPH If ...

Question

PARAGRAPH
If the measurement errors in all the independent quantities are known, then it is possible to determine the error in any dependent quantity. This is done by the use of series expansion and truncating the expansion at the first power of the error. For example, consider the relation $z = x / y$ . If the errors in $x, y$ and $z$ are $Δ x, Δ y$ and $Δ z$ , respectively, then
$z \pm Δ z = \frac{x \pm Δ x}{y \pm Δ y} = \frac{x}{y} (1 \pm \frac{Δ x}{x}) {(1 \pm \frac{Δ y}{y})}^{- 1}$ .
The series expansion for ${(1 \pm \frac{Δ y}{y})}^{- 1}$ , to first power in $Δ y / y$ is $1 \mp (Δ y / y)$ . The relative errors in independent variables are always added. So the error in $z$ will be
$Δ z = z (\frac{Δ x}{x} + \frac{Δ y}{y})$ .
The above derivation makes the assumption that $Δ x / x ≪ 1, Δ y / y ≪ 1$ . Therefore, the higher powers of these quantities are neglected.

In an experiment the initial number of radioactive nuclei is $3000$ . It is found that $1000 \pm 40$ nuclei decayed in the $1.0 s$ . For $| x | << 1, ln (1 + x) = x$ up to first power in $x$ . The error $Δ λ$ , in the determination of the decay constant $λ$ , in $s^{- 1}$ is

0.04

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0.03

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0.02

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0.01

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Solution

The correct option is C $0.02$

$N = N_{o} e^{- λ t}$
$l n N = l n N_{o} - λ t$
$\frac{d N}{N} = - λ t$
Converting to error $\frac{Δ N}{N} = Δ λ t$ $Δ λ = \frac{40}{2000 \times t}$ = 0.02

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Similar questions

Q. PARAGRAPH
If the measurement errors in all the independent quantities are known, then it is possible to determine the error in any dependent quantity. This is done by the use of series expansion and truncating the expansion at the first power of the error. For example, consider the relation

z = x / y

. If the errors in

x, y

and

z

are

Δ x, Δ y

and

Δ z

, respectively, then

z \pm Δ z = \frac{x \pm Δ x}{y \pm Δ y} = \frac{x}{y} (1 \pm \frac{Δ x}{x}) {(1 \pm \frac{Δ y}{y})}^{- 1}

.
The series expansion for

{(1 \pm \frac{Δ y}{y})}^{- 1}

, to first power in

Δ y / y

. is

1 \mp (Δ y / y)

. The relative errors in independent variables are always added. So the error in

z

will be

Δ z = z (\frac{Δ x}{x} + \frac{Δ y}{y})

.
The above derivation makes the assumption that

Δ x / x ≪ 1, Δ y / y ≪ 1

. Therefore, the higher powers of these quantities are neglected.

Consider the ratio

r = \frac{(1 - a)}{(1 + a)}

to be determined by measuring a dimensionless quantity

a

. If the error in the measurement of a is

Δ a (\frac{Δ a}{a} << 1)

, then what is the error

Δ r

in determining

r

z = x / y

. If the errors in

x, y

and

z

are

Δ x, Δ y

and

Δ z

, respectively, then

z \pm Δ z = \frac{x \pm Δ x}{y \pm Δ y} = \frac{x}{y} (1 \pm \frac{Δ x}{x}) {(1 \pm \frac{Δ y}{y})}^{- 1}

.
The series expansion for

{(1 \pm \frac{Δ y}{y})}^{- 1}

, to first power in

Δ y / y

1 \mp (Δ y / y)

. The relative errors in independent variables are always added. So the error in

z

will be

Δ z = z (\frac{Δ x}{x} + \frac{Δ y}{y})

.
The above derivation makes the assumption that

Δ x / x ≪ 1, Δ y / y ≪ 1

. Therefore, the higher powers of these quantities are neglected.

In an experiment the initial number of radioactive nuclei is

3000

. It is found that

1000 \pm 40

nuclei decayed in the

1.0 s

. For

| x | << 1, ln (1 + x) = x

up to first power in

x

. The error

Δ λ

, in the determination of the decay constant

λ

, in

s^{- 1}

Q. PARAGRAPH
If the measurement errors in all the independent quantities are known, then it is possible to determine the error in any dependent quantity. This is done by the use of series expansion and truncating the expansion at the first power of the error. For example, consider the relation

z = x / y

. If the errors in

x, y

and

z

are

Δ x, Δ y

and

Δ z

, respectively, then

z \pm Δ z = \frac{x \pm Δ x}{y \pm Δ y} = \frac{x}{y} (1 \pm \frac{Δ x}{x}) {(1 \pm \frac{Δ y}{y})}^{- 1}

.
The series expansion for

{(1 \pm \frac{Δ y}{y})}^{- 1}

, to first power in

Δ y / y

. is

1 \mp (Δ y / y)

. The relative errors in independent variables are always added. So the error in

z

will be

Δ z = z (\frac{Δ x}{x} + \frac{Δ y}{y})

.
The above derivation makes the assumption that

Δ x / x ≪ 1, Δ y / y ≪ 1

. Therefore, the higher powers of these quantities are neglected.

Consider the ratio

r = \frac{(1 - a)}{(1 + a)}

to be determined by measuring a dimensionless quantity

a

. If the error in the measurement of a is

Δ a (\frac{Δ a}{a} << 1)

, then what is the error

Δ r

in determining

r

Q. If

y = 2 x^{3} - 2 x^{2} + 3 x - 5

, then for

x = 2

and

Δ x = 0.1

value of

Δ y

Q. In an experiment the initial number of radioactive nuclei is

3000

. It is found that

1000 \pm 40

nuclei decayed in the

1.0 s

. For

| x | << 1, ln (1 + x) = x

up to first power in

x

. The error

Δ λ

, in the determination of the decay constant

λ

, is

s^{- 1}

, is

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The correct option is C 0.02 N=Noe−λt lnN=lnNo−λt dNN=−λt Converting to error ΔNN=Δλt Δλ=402000×t = 0.02

The correct option is C $0.02$

$N = N_{o} e^{- λ t}$
$l n N = l n N_{o} - λ t$
$\frac{d N}{N} = - λ t$
Converting to error $\frac{Δ N}{N} = Δ λ t$ $Δ λ = \frac{40}{2000 \times t}$ = 0.02