268098
The equivalent capacity between the points ' \(A\) ' and ' \(B\) ' in the following figure will be
1 \(3 C\)
2 \(C / 3\)
3 \(3 / C\)
4 \(1 / 3 C\)
Explanation:
Capacitors are in parallel
Electrostatic Potentials and Capacitance
268099
Two capacitors with capacitances \(C_{1}\) and \(C_{2}\) are charged to potentials \(V_{1}\) and \(V_{2}\) respectively. When they are connected in parallel the ratio of their respective charges is
1 \(\frac{C_{1}}{C_{2}}\)
2 \(\frac{V_{1}}{V_{2}}\)
3 \(\frac{V_{1}^{2}}{V_{2}^{2}}\)
4 \(\frac{C_{1}^{2}}{C_{2}^{2}}\)
Explanation:
Parallel potential constant and \(Q \alpha C\)
Electrostatic Potentials and Capacitance
268100
The equivalent capacitance between \(\mathbf{P}\) and \(Q\) of the given figure is (the capacitance of each capacitor is \(1 \mu F\) )
268098
The equivalent capacity between the points ' \(A\) ' and ' \(B\) ' in the following figure will be
1 \(3 C\)
2 \(C / 3\)
3 \(3 / C\)
4 \(1 / 3 C\)
Explanation:
Capacitors are in parallel
Electrostatic Potentials and Capacitance
268099
Two capacitors with capacitances \(C_{1}\) and \(C_{2}\) are charged to potentials \(V_{1}\) and \(V_{2}\) respectively. When they are connected in parallel the ratio of their respective charges is
1 \(\frac{C_{1}}{C_{2}}\)
2 \(\frac{V_{1}}{V_{2}}\)
3 \(\frac{V_{1}^{2}}{V_{2}^{2}}\)
4 \(\frac{C_{1}^{2}}{C_{2}^{2}}\)
Explanation:
Parallel potential constant and \(Q \alpha C\)
Electrostatic Potentials and Capacitance
268100
The equivalent capacitance between \(\mathbf{P}\) and \(Q\) of the given figure is (the capacitance of each capacitor is \(1 \mu F\) )
268098
The equivalent capacity between the points ' \(A\) ' and ' \(B\) ' in the following figure will be
1 \(3 C\)
2 \(C / 3\)
3 \(3 / C\)
4 \(1 / 3 C\)
Explanation:
Capacitors are in parallel
Electrostatic Potentials and Capacitance
268099
Two capacitors with capacitances \(C_{1}\) and \(C_{2}\) are charged to potentials \(V_{1}\) and \(V_{2}\) respectively. When they are connected in parallel the ratio of their respective charges is
1 \(\frac{C_{1}}{C_{2}}\)
2 \(\frac{V_{1}}{V_{2}}\)
3 \(\frac{V_{1}^{2}}{V_{2}^{2}}\)
4 \(\frac{C_{1}^{2}}{C_{2}^{2}}\)
Explanation:
Parallel potential constant and \(Q \alpha C\)
Electrostatic Potentials and Capacitance
268100
The equivalent capacitance between \(\mathbf{P}\) and \(Q\) of the given figure is (the capacitance of each capacitor is \(1 \mu F\) )
268098
The equivalent capacity between the points ' \(A\) ' and ' \(B\) ' in the following figure will be
1 \(3 C\)
2 \(C / 3\)
3 \(3 / C\)
4 \(1 / 3 C\)
Explanation:
Capacitors are in parallel
Electrostatic Potentials and Capacitance
268099
Two capacitors with capacitances \(C_{1}\) and \(C_{2}\) are charged to potentials \(V_{1}\) and \(V_{2}\) respectively. When they are connected in parallel the ratio of their respective charges is
1 \(\frac{C_{1}}{C_{2}}\)
2 \(\frac{V_{1}}{V_{2}}\)
3 \(\frac{V_{1}^{2}}{V_{2}^{2}}\)
4 \(\frac{C_{1}^{2}}{C_{2}^{2}}\)
Explanation:
Parallel potential constant and \(Q \alpha C\)
Electrostatic Potentials and Capacitance
268100
The equivalent capacitance between \(\mathbf{P}\) and \(Q\) of the given figure is (the capacitance of each capacitor is \(1 \mu F\) )
