We measure the period of oscillation of a simple pendulum. In successive measurements, the readings turn out to be 2.63 s, 2.56 s, 2.42 s, 2.71 s, and 2.80 s. The average absolute error and percentage error, respectively, are:
1. 0.22 s and 4%
2. 0.11 s and 4%
3. 4 s and 0.11%
4. 5 s and 0.22%
The temperatures of two bodies measured by a thermometer are \(t_1=20^\circ \text{C}\pm0.5^\circ \text{C}\) and \(t_2=50^\circ \text{C}\pm0.5^\circ \text{C}.\) The temperature difference with permissible error is:
1. \(31^\circ \text{C}\pm0.5^\circ \text{C}\)
2. \(30^\circ \text{C}\pm1.0^\circ \text{C}\)
3. \(30^\circ \text{C}\pm0.0^\circ \text{C}\)
4. \(30^\circ \text{C}\pm1.5^\circ \text{C}\)
The resistance \(R=\frac{V}{I}\) where \(V=(100 \pm 5) ~V\) and \(I=(10 \pm 0.2)~ A\). The percentage error in \(R\) is:
1. \(5\%\)
2. \(2\%\)
3. \(7\%\)
4. \(3\%\)
Two resistors of resistances ohm and ohm are connected in series, the equivalent resistance of the series combination is:
1. (300 ± 7) ohm
2. (300 ± 1) ohm
3. (300 ± 0) ohm
4. (100 ± 1) ohm
Two resistors of resistances ohm and ohm are connected in parallel. The equivalent resistance of the parallel combination is:
1. (300 ± 7) ohm
2. (66.7 ± 7) ohm
3. (66.7 ± 1.8) ohm
4. (100 ± 1) ohm
The relative error in \(Z,\) if \(Z=\frac{A^{4}B^{1/3}}{CD^{3/2}}\) is:
1. \(\frac{\Delta A}{A}+\frac{\Delta B}{B}+\frac{\Delta C}{C}+\frac{\Delta D}{D}\)
2. \(4\frac{\Delta A}{A}+\frac{1}{3}\frac{\Delta B}{B}-\frac{\Delta C}{C}- \frac{3}{2}\frac{\Delta D}{D}\)
3. \(4\frac{\Delta A}{A}+\frac{1}{3}\frac{\Delta B}{B}+\frac{\Delta C}{C}+\frac{2}{3}\frac{\Delta D}{D}\)
4. \(4\frac{\Delta A}{A}+\frac{1}{3}\frac{\Delta B}{B}+\frac{\Delta C}{C}+\frac{3}{2}\frac{\Delta D}{D}\)
The period of oscillation of a simple pendulum is . Measured value of L is 20.0 cm known to 1 mm accuracy and time for 100 oscillations of the pendulum is found to be 90 s using a wrist watch of 1 s resolution. The percentage error in g is:
1.
2.
3.
4.
Each side of a cube is measured to be \(7.203~\text{m}\). What are the total surface area and the volume respectively of the cube to appropriate significant figures?
1. | \(373.7~\text{m}^2\) and \(311.3~\text{m}^3\) |
2. | \(311.3~\text{m}^2\) and \(373.7~\text{m}^3\) |
3. | \(311.2992~\text{m}^2\) and \(373.7147~\text{m}^3\) |
4. | \(373.7147~\mathrm{m^2}\) and \(311.2992~\text{m}^3\) |
\(5.74\) g of a substance occupies \(1.2~\text{cm}^3\). Its density by keeping the significant figures in view is:
1. \(4.7333~\text{g/cm}^3\)
2. \(3.8~\text{g/cm}^3\)
3. \(4.8~\text{g/cm}^3\)
4. \(3.7833~\text{g/cm}^3\)
The SI unit of energy is \(\mathrm{J = \text{kg}\left(m\right)^{2} s^{- 2}}\); that of speed \(v\) is \(\text{ms}^{- 1}\) and of acceleration \(a\) is \(\text{ms}^{- 2}\). Which of the formula for kinetic energy (\(K\)) given below can you rule out on the basis of dimensional arguments (m stands for the mass of the body)?
(a) | \(K={m^{2} v^{3}}\) |
(b) | \(K=\dfrac{1}{2}mv^{2}\) |
(c) | \(K= ma\) |
(d) | \(K =\dfrac{3}{16}mv^{2}\) |
(e) | \(K = \dfrac{1}{2}mv^2+ ma\) |
Choose the correct option:
1. | (a), (c) & (d) |
2. | (b) & (d) |
3. | (a), (c), (d) & (e) |
4. | (a), (c) & (e) |