2013
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The capacitors are switched in series and I wanted to determine the total capacity to come up with the extra capacity over the load.
How do I do that then?
How do I do that then?
2013 said:The capacitors are switched in series and I wanted to determine the total capacity to come up with the extra capacity over the load.
How do I do that then?
2013 said:To your question: No, we have not yet worked on the topic in our course.
C1 and C2 are switched in series so:
C = 1 / ((1/C1) + (1/C2))
C = 1,107 * 10^-11 As/V
Cc = V * (C/Vc) - C = 12V * (1,107 * 10^-11 As/V / 0,15V) - 1,107 * 10^-11 As/V = 8,74 * 10^-10 As/V
Is it right?
I`m so sorry but our prof never speak with us about circuit analysis, he expects that we can solve the problem that way. As a final test, so to say.
2013 said:Node rule:
-Q1-Q2+Q3 = 0
Mesh rule:
1) Q1/C1 - Q2/C2 - Q2/C3 = -U1 - U2
2) Q2/C2 + Q2/C3 + Q3/C4 = U2+U3
Is it right? How should I go on? Could you give me a formula as a tip?
2013 said:Is it right? Can I go on with the node and mesh rule?
How can I set it up?
Why do you assume that the potentials on the capacitors are both 12V?2013 said:C1 = 2,01*10^-11 As/V
C2 = 2,46*10^-11 As/V
Q = C * U U=12V
Q1 = 2,01*10^-11 As/V * 12V = 2,41*10^-10 As
Q2 = 2,46*10^-11 As/V * 12V = 2,95*10^-10 As
That looks okay, being based upon KCL applied at the common node.Uc=0,15V Cc=?
-Q1+Q2+Qc=0
No. But you're applying more thought to the problem, which is good. Write the KVL equations for the loops. Use Q1/C1, Q2/C2, Qc/Cc, for the potentials on the capacitors to begin with, then substitute for them from other known relationships (such as your KCL equation above, and Qc/Cc = Uc, for examples).-2,41*10^-10 As + 2,95*10^-10 As + Qc = 0
Qc = 5,4*10^-11 As
Cc = Qc/Uc = 5,4*10^-11 As / 0,15 V = 3,6*10^-10 As/V
Is it right? Is that the additional capacitance?
I believe that the wavy line is meant to represent a flexible connection to the moving plate. It has no electrical significance.I have got another question:
I first viewed on the drawing, the three panels, the middle plate moves around to the left or right and thus the capacitance of the two capacitors changes. A is increased, the other decreases. I have calculated. What's with the wavy line under the middle plate and the capacitor underneath? Can you explain to me how this relates? I think that's the reason why I do not get ahead.
Thank you for all your help and your patience with me.
2013 said:I used before U=V for the voltage.
I really don`t have any good ideas anymore.
maybe it is:
- Q1/C1 + Q2/C2 + Qc/Cc = - V1 + V2 + Vc
Can you show me your formula for this. So I have a chance to continue, this would be very nice.
You don't know the charges, they're unknowns. But you do know that Uc = Qc/Cc, and you are given the value of Uc. That leaves you with unknowns Q1, Q2, and Cc.2013 said:1.Q1/C1+Qc/Cc=12V
2.Q1/C1+Q2/C2=24V
3.-q1 + qc + q2 = 0 => Qc=Q1-Q2
in 1.
Q1/C1 + (Q1-Q2)/Cc=12V
How can I replace Q1 and Q2? Or do I already know the charge?
2013 said:1. Q1 = (12V - Vc) * C1 = (12V - 0,15V) * 2,01*10^-11As = 2,38 * 10^-10 As
V1 = Q1/C1 = 11,85V
2. V2 = 24V - V1 = 24V - 11,85V = 12,15V
Q2 = V2 * C2 = 12,15V * 2,46*10^-11As/V = 2,99*10^-10As
3. Cc = (Q1-Q2)/Vc = ( 2,38 * 10^-10 As - 2,99*10^-10As) / 0,15V = -4,047*10^-10As/V
Is this right?
2013 said:CC= (2,99*10^-10As - 2,38 * 10^-10 As) / 0,15V = 4,07*10^-10As/V
Alternative:
Cc = (Q1-Q2)/Vc = ( 2,38 * 10^-10 As - 2,99*10^-10As) / (-0,15)V = 4,07*10^-10As/V
Is this right? Did I make the right moves? Did you figure out the same thing?
Oops. My mistake. I copied the wrong value for Q2 (I used my value for Q1 by mistake). Take a look at my edit of my previous post.2013 said:Qc = Q1 - Q2 = 2.915 x 10-10 C - 2.915 x 10-10 C = 0
Cc = Qc/Vc = 0/0,15V = 0
I don´t think that this is right. I do not think that the extra capacity is not zero, right?
2013 said:Qc = Q1 - Q2 = 2.915 x 10^-10 C - 2.445 x 10^-10 C = 4,7*10^-11As
Cc = 4,7*10^-11As / 0,15V = 3,33*10^-10As/v
Have you got the same additional capacitance?
2013 said:Thank you very much.
Can you also explain me the second method?
How can I apply the voltage divider method?
gneill said:$$V_{C1} = V \frac{C}{C1 + C}$$