The discussion revolves around deriving a circuit equation related to the voltage across a capacitor over time, specifically focusing on the equation Vc(t) = A + Be^(-t/τ). Participants explore relationships between various parameters (n, m, p) and their connection to the voltage equation, while attempting to clarify their understanding of the problem presented in a homework context.
Participants do not reach a consensus on the relationships between the parameters or the correct approach to derive the circuit equation. Multiple competing views and uncertainties remain throughout the discussion.
Participants note the complexity of the diagram and the potential for misinterpretation, which may affect their understanding of the relationships between the variables. There are also unresolved mathematical steps in deriving the ratios.
monahanj09 said:Homework Statement
Question is here
Homework Equations
Shown in the image, but just to restate:
Vc(t) = A+Be^(-t/τ)
n/m=e^-1
OR
p/m=1-e^-1
The Attempt at a Solution
First thing I tried to do was solve the Vc(t) equation for e, which comes out to e=(-A/B)^(-τ/t). I'm not even sure if that's relevant, though, or where to take it from there if it is. I'm a little lost on how to proceed with this.
berkeman said:The key is to use the equation for the V(t), and compare V(t) to V(t+τ)...
monahanj09 said:So try setting V(t) equal to V(t+τ), which would be A+Be^(-t/τ)=A+Be^(-t+τ/τ)? That still doesn't relate n, m, and p to each other, though. From looking at the graph, it looks like there's some sort of relationship between m/n/p and A or A+B, but I can't quite tell what it is.
berkeman said:No, don't set them equal because they are not.
The key in the figure (it is small and hard to see on the figure) is that the two vertical lines are a time τ apart...
monahanj09 said:I see that the m line is time τ apart from the n/p line. I also see that m is the difference between A (the maximum possible voltage) at time t and V(t), and that n is the difference between A and V(t+τ), and that p is the difference between m and n. I can't quite tell how to relate them though. Maybe...A+Be^(-t/τ)+m=A+Be^(-t+τ/τ)+n?
EDIT: Wait, no. m=A-(A+Be^(-t/τ)) and n=A-(A+Be^(-t+τ/τ)), but I'm still not sure how to relate them.
berkeman said:Now that I look closer at the diagram, it is pretty confusing. It's like they drew it upside down, with A+B at the bottom, and A at the top of the vertical axis. Weird.
Try this as a first way to prove the ratios, and then you can see if you can prove it for this upside down version.
Flip the drawing about its middle horizontal axis, so A is at the bottom, and A+B is at the top. Now set A=0, so the waveform starts with initial value B and decays exponentially to zero. Now since A=0, the equation for the waveform becomes V(t) = B e^-t/τ
Now take the ratio of V(t+τ) / V(t), and see what you get...
EDIT -- I fixed the V(t) equation -- I had left out the minus sign in the exponent.
monahanj09 said:So in that case V(t+τ) = A+Be^(-t+τ/τ). I put that over the equation you gave me for V(t), but I'm not sure what it represents or what it's equivalent to. I assume it's equivalent to one of the ratios it shows in the problem statement, I just can't tell which or how to prove it.
berkeman said:Did you miss where I said to set A=0?