184_notes:examples:week8_charge_discharge_caps_resistors

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184_notes:examples:week8_charge_discharge_caps_resistors [2021/07/05 21:14] schram45184_notes:examples:week8_charge_discharge_caps_resistors [2021/07/05 21:15] (current) schram45
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 ===Approximations & Assumptions=== ===Approximations & Assumptions===
-  * The wire has very very small resistance when compared to the other resistors in the circuit: This allows there to be no energy loss across the wires and no potential difference across them either simplifying down the model.+  * The wire has very very small resistance when compared to the other resistors in the circuit: This allows there to be no energy loss across the wires and no potential difference across them eithersimplifying down the model.
   * The resistors in the circuit are made of Ohmic materials: Ohmic materials have a linear relationship between voltage and current, this allows us to use ohms law.   * The resistors in the circuit are made of Ohmic materials: Ohmic materials have a linear relationship between voltage and current, this allows us to use ohms law.
   * Practically speaking, the capacitors becomes "fully charged" (with respect to the potential differences in the circuit) at some finite time: Making this assumption means we are dealing with perfect capacitors that will not lose charge and will reach a peak charge in a finite time.   * Practically speaking, the capacitors becomes "fully charged" (with respect to the potential differences in the circuit) at some finite time: Making this assumption means we are dealing with perfect capacitors that will not lose charge and will reach a peak charge in a finite time.
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