For the capacitor system shown, C1=6.0 F, C2=2.0 F, and C3=10.0 F. (a) Find the equivalent capacitance. C1=6F V0 C2=2F C3=10F.

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Presentation transcript:

For the capacitor system shown, C1=6.0 F, C2=2.0 F, and C3=10.0 F. (a) Find the equivalent capacitance. C1=6F V0 C2=2F C3=10F

Don’t expect the equivalent capacitance to always be an integer! For the capacitor system shown, C1=6.0 F, C2=2.0 F, and C3=10.0 F. (a) Find the equivalent capacitance. C1=6F C23=12F V0 Don’t expect the equivalent capacitance to always be an integer!

There are several correct ways to solve this. Shown here is just one. For the capacitor system shown, C1=6.0 F, C2=2.0 F, and C3=10.0 F. (b) The charge on capacitor C3 is found to be 30.0 C. Find V0. C1=6F There are several correct ways to solve this. Shown here is just one. C3=10F Q3= 30C V3= ? C2=2F C3=10F V0

For the capacitor system shown, C1=6.0 F, C2=2.0 F, and C3=10.0 F. (b) The charge on capacitor C3 is found to be 30.0 C. Find V0. C1=6F C23=12F Q23= ? V23= 3V V0