Power dissipated in capacitor

In summary, when you charge up a capacitor, you are storing energy in the charge separation, and the amount of energy is related to the capacitor voltage. So when the energy is half of the initial value, the power dissipated in the resistor is just 1/2(1/2 CV^2). So if you want to know the capacitance of the capacitor, you just need to divide the voltage by the power dissipated.
  • #1
indigojoker
246
0
a charged capacitor has capacitance C and charge Q. a resistor R is then connected what is the power dissipated right after the connection?

V=Q/C
so P=V^2/R=Q^2/(RC^2)
is this right?

what is the power dissipated in the resistor when the energy stored in the capacitor has decreased to half the initial value?

Using P=V^2/R, we need to find V when U=1/2U_o

This means, U=(1/4)Q^2/C

I'm not actually sure of how to get the voltage, to get the power dissipated. any ideas?
 
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  • #2
The first part looks correct, but remember that the power is dissipated in the resistor, not in the capacitor. The energy comes from the stored charge in the capacitor.

The equation that you need to add for the 2nd part is the energy stored on the capacitor, E = 1/2 CV^2. Does that help?
 
  • #3
do you mean:

(1/4)Q^2/C=1/2 CV^2

and then solve for V?
 
  • #4
berkeman said:
The first part looks correct, but remember that the power is dissipated in the resistor, not in the capacitor. The energy comes from the stored charge in the capacitor.

The equation that you need to add for the 2nd part is the energy stored on the capacitor, E = 1/2 CV^2. Does that help?

i'm not sure how he stored energy in a capacitor helps on the second part.
 
  • #5
indigojoker said:
i'm not sure how he stored energy in a capacitor helps on the second part.

When you charge up a capacitor, you are storing energy in the charge separation, and the amount of energy is related to the capacitor voltage.
 
  • #6
so the power dissipated in the resistor when the energy stored in the capacitor has decreased to half the initial value is just 1/2(1/2 CV^2)?
 
  • #7
indigojoker said:
so the power dissipated in the resistor when the energy stored in the capacitor has decreased to half the initial value is just 1/2(1/2 CV^2)?

Just subtract the final energy from the initial energy, and divide that by the time it takes for the energy change to happen. Can you show us that equation?
 
  • #8
well, i am looknig for the the power dissipated in the resistor at the instant when the energy stored int he capacitor has decreased to half the initial value.

I was thinking something like this.

U_o=0.5 Q^2/C and we know that since C stays the same, then when the energy is half of original energy, we get Q-> Q/Sqrt(2) to get 0.5U_o

So if Q-> Q/Sqrt(2), then plugging into C=Q/V, we get that V=> V/Sqrt(2) in order to get the capacitance to not change.

thus, we get that P=V^2/R --> P=1/2 (V^2/R) when using the new V

ideas?
 

What is power dissipated in a capacitor?

Power dissipated in a capacitor refers to the amount of energy that is lost or converted into heat due to internal resistance in the capacitor. It is a measure of how much energy is wasted in the form of heat instead of being used for its intended purpose.

How is power dissipated in a capacitor calculated?

The power dissipated in a capacitor can be calculated using the formula P = VI, where P is power, V is the voltage across the capacitor, and I is the current flowing through it. It can also be calculated using the formula P = V^2/R, where R is the equivalent series resistance of the capacitor.

What factors affect the power dissipated in a capacitor?

The power dissipated in a capacitor is affected by its capacitance, voltage, and equivalent series resistance. Higher capacitance and voltage will result in higher power dissipation, while a lower equivalent series resistance will result in lower power dissipation.

Why is power dissipated in a capacitor important?

The power dissipated in a capacitor is important because it can affect the performance and lifespan of the capacitor. Excessive power dissipation can cause overheating and damage to the capacitor, leading to malfunctions or failure of the circuit it is a part of.

How can the power dissipated in a capacitor be reduced?

The power dissipated in a capacitor can be reduced by using a capacitor with a lower equivalent series resistance, or by using a capacitor with a higher voltage or capacitance rating. It can also be reduced by minimizing the amount of current flowing through the capacitor, either by using a smaller load or by using a capacitor with a higher capacitance value.

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