Figure 1-26.—The loading effect.

1-26 Figure 1-26.—The loading effect. In figure 1-26(A), a series circuit is shown with R₁ equaling 15 ohms and R₂ equaling 10 ohms. The voltage across R₂ (E_R2) equals 10 volts. If a meter (represented by R₃) with a resistance of 10 ohms is connected in parallel with R₂, as in figure 1-26(B), the combined resistance of R₂ and R₃ (R_n) is equal to 5 ohms. The voltage across R₂ and R₃ is now 6.25 volts, and that is what the meter will indicate. Notice that the voltage across R₁ and the circuit current have both increased. The addition of the meter (R₃) has loaded the circuit. In figure 1-26(C), the low-resistance meter (R₃) is replaced by a higher resistance meter (R ₄) with a resistance of 10 kilohms. The combined resistance of R₂ and R₄ (R_n) is equal to 9.99 ohms. The voltage across R₂ and R 4 is now 9.99 volts, the value that will be indicated on the meter. This is much closer to the voltage across R₂, with no meter (R₃ or R₄) in the circuit. Notice that the voltage across R, and the circuit current in figure 1-26(C) are much closer to the values in 1-26(A). The current (I_R4) through the meter (R₄) in figure 1-26(C) is also very small compared to the current (I_R2) through R ₂. In figure 1-26(C) the meter (R₄) has much less effect on the circuit and does not load the circuit as much. Therefore, a voltmeter should have a high resistance compared to the circuit being measured, to minimize the loading effect.