That's exactly like saying that more resistors should mean more resistance, but when they are in parallel it is actually LESS resistance, it's only more resistance when they are in series. Similarly, capacitors in parallel means more capacitance and in series means less.matangi7 said:I understand algebraically that when capacitors are in series, the total capacitance is less than any individual capacitance, but I do not understand this intuitively. How can this be possible? Shouldn't more capacitors equal more capacitance?
Maybe the energy approach could make it intuitive for you. Compare the total energies stored in two capacitors in both series and parallel connections, keeping the source voltage constant. Which one gives more stored energy?matangi7 said:I understand algebraically that when capacitors are in series, the total capacitance is less than any individual capacitance, but I do not understand this intuitively.
A capacitor is an electronic component that stores electric charge. It is made up of two conductive plates separated by an insulating material, also known as a dielectric.
Capacitors work by accumulating electric charge on the plates when connected to a power source. When the power source is disconnected, the capacitor can release this stored charge in a controlled manner.
Connecting capacitors in series allows for an increase in the overall capacitance. This means that more charge can be stored on the combined capacitors, and they can also handle higher voltages.
When capacitors are connected in series, the total capacitance is equal to the reciprocal of the sum of the reciprocals of each individual capacitor's capacitance. This means that the total capacitance will be less than the capacitance of the individual capacitors.
Capacitors in series are commonly used in electronic circuits to filter out unwanted signals, stabilize power supplies, and store energy for a short period of time. They are also used in high-voltage applications such as power transmission and electric motors.