Let V and I be the readings of the voltmeter and the ammeter respectively as shown in the figure. Let `R_(V) " and "R_(A)` be their corresponding resistancce Therefore,

In the given circuit the readings of the voltmeter V_(1) and the ammeter A are .

Let V and I respresent, respectively, the readings of the voltmeter and ammetre shows in Fig. 6.34 , and let R_(V) and R_(V) be their equivalent resistances. Because of the resistances of the meters, the resistnce R is not simply equal to V//I . (a) When the circuit is connected as shows in Fig. 6.34 (a), shows that R = (V)/(I) - R_(A) Explain why the true resistance R is always less than V//I . (b) When the connections are as shows in Fig. 6.34 (b) Show that R = (V)/(I - (V//R_(V))) Explain why the true resistance R is always greater than V//I . (c ) Show that the power delivered to the resistor in part (i) is IV - I^(2) R_(A) and that in part (ii) is IV - (V^(2)//R_(V))

Resistance value of an unknown resistor is calculated using the formula R=V/I where V and I be the readings of the voltmeter and the ammeter respectively. Consider the circuits below. The internal resistances of the voltmeter and the ammeter ( R_v and R_G respectively ) are finite and non zero. Let R_v and R_G be the calculated values in the two cases A and B respectively. If the resistance of voltmeter is R_v=1kOmega and that of ammeter is R_G=1Omega the magnitude of the percentage error in the measurement of R (the value of R is nearly 10Omega ) is:

Resistance value of an unknown resistor is calculated using the formula R=V/I where V and I be the readings of the voltmeter and the ammeter respectively. Consider the circuits below. The internal resistances of the voltmeter and the ammeter ( R_v and R_G respectively ) are finite and non zero. Let R_v and R_G be the calculated values in the two cases A and B respectively. The relation between R_B and the actual value of R is:

Resistance value of an unknown resistor is calculated using the formula R=V/I where V and I be the readings of the voltmeter and the ammeter respectively. Consider the circuits below. The internal resistances of the voltmeter and the ammeter ( R_v and R_B respectively ) are finite and non zero. Let R_A and R_B be the calculated values in the two cases A and B respectively. The relation between R_A and the actual value R is

The value of resistance of an unknown resistor is calculated using the formula R = V//I where V and I are the readings of the voltmeter and the ammeter, respectivley. Consider the circuits below. The internal resistances of the voltmeter and the ammeter (R_V and R_G, respectively) are finite and nonzero. , Let R_(A) and R_(B) be the calculated values in the two cases A and B , respectively. If the resistance of voltmeter is R_(V) = 1k Omega and the percentage error in the measurement of R (the value of R is nearly 10 Omega )is

The value of resistance of an unknown resistor is calculated using the formula R = V//I where V and I are the readings of the voltmeter and the ammeter, respectivley. Consider the circuits below. The internal resistances of the voltmeter and the ammeter (R_V and R_G, respectively) are finite and nonzero. , Let R_(A) and R_(B) be the calculated values in the two cases A and B , respectively. The relation between R_A and the actual value of R is

Consider the two circuits P and Q, shown below, which are used 20 measure the unknown resistance R. In each case, the resistance is estimated by using Ohm's law R_("est" = V // I , Where V and I are the readings of the voltmeter and the ammeter respectively. The meter resistances, R_(v) and R_(A) are such that R_(A) ltlt R ltlt R_(v) . The internal resistance of the battery may be ignored. The absolute error in the estimate of the resistance is denoted by deltaR = |R = R_("est")| .

The actual value of resistance R, shown in the figure is 30 Omega . This is measured in an experiment as shown using the standard formula R = (V)/(I) , where V and I are the readings of the voltmeter and ammeter, respectively. If the measured value of R is 5% less, then the internal resistance of the voltmeter is