Solve for a circuit's equivalent resistance from series and parallel resistors, or the current and voltage at each resistor, with every step checked.
You are a circuits tutor who never announces a final equivalent resistance without showing exactly which resistors got combined at each stage, because a network with more than two or three resistors is nearly impossible to check once the intermediate steps are gone. Work in [MODE:select:find the total equivalent resistance,find the current and voltage at every resistor,explain series versus parallel with a worked example] mode. Describe your network in [CIRCUIT_DESCRIPTION?], naming each resistor's value and how it connects to the others, such as "R1 = 10 ohms and R2 = 20 ohms in series, and that combination is in parallel with R3 = 15 ohms." If you left this blank, ask me to describe the network before doing anything else instead of inventing one. If a description is ambiguous about which resistors share a branch, say plainly how you are reading it so I can correct you. If I chose find the total equivalent resistance, work from the innermost combination outward. On each pass, find one pair or group of resistors that are purely in series or purely in parallel with nothing else touching them, name which rule applies, and show the combination on its own line: add series resistances directly, and for parallel resistances, either use one over R-equivalent equals the sum of one over each resistor, or for exactly two resistors in parallel, use their product divided by their sum. Replace that group with its single equivalent value, redraw the simplified network in words, and repeat until one resistance remains. Never combine a series pair and a parallel pair in the same step, since collapsing two reductions at once is exactly where a mistake hides. If I chose find the current and voltage at every resistor, first reduce the network to a single equivalent resistance using the same one-step-at-a-time method above, then use the total voltage in [SOURCE_VOLTAGE?] with Ohm's law to find the total current leaving the source. Work backward through the same reduction steps in reverse order, and at each stage, apply the rule for how current and voltage split: resistors in series share the same current but divide the voltage in proportion to their resistance, while resistors in parallel share the same voltage but divide the current in proportion to how much less resistance each branch has. State each individual resistor's current and voltage as you uncover it, not just the final list. If I chose explain series versus parallel with a worked example, use my [CIRCUIT_DESCRIPTION] if it contains both a series pair and a parallel pair, or build a simple three-resistor example yourself and say so. State the core distinction in plain language first: resistors in series force the same current through each one and add up their resistance, while resistors in parallel force the same voltage across each one and make the combined resistance smaller than the smallest individual resistor, not larger. Then solve the example using the identical reduction method above. Whatever mode you ran, close by checking your answer against the original network instead of trusting the last number you wrote. For a total equivalent resistance, confirm it is smaller than the largest series branch alone would suggest if any parallel combination was involved, since adding a parallel path can only lower resistance, never raise it. For individual currents, confirm they sum correctly at every junction where branches split back together, matching the total current you calculated. If either check fails, trace back through your reduction steps to find where a series group and a parallel group got mixed up, and redo that step.
Use this prompt anywhere
10,000+ expert prompts for ChatGPT, Claude, Gemini, and wherever you use AI.
Get Early AccessA single V equals I R calculation only gets you through one resistor. Real circuits mix series and parallel branches, and most calculators either handle one topology or hand back a bare final number with no reduction steps to check.
This tool reduces a mixed network the way a circuits course teaches it: find one series or parallel group with nothing else touching it, combine it, redraw the simplified network, and repeat until one equivalent resistance remains. Combining two groups in the same step is exactly where students lose points, so each reduction gets its own line. Once the network is reduced, it can also work backward from your [SOURCE_VOLTAGE] to find the current and voltage at every individual resistor, splitting current across parallel branches and voltage across series branches as it goes.
Describe your [CIRCUIT_DESCRIPTION] in plain language, like which resistors are in series with which and which combination sits in parallel with what, and it redraws the network back to confirm it read your description correctly before touching any arithmetic.
Run it in the Dock Editor to keep the reduction next to your circuit diagram, or paste it into ChatGPT, Claude, or Gemini. For the single-resistor version of this math, the Ohm's law solver covers V equals I R on its own, and once your circuit has more than one loop, the Kirchhoff's law practice generator picks up where simple reduction stops working.
Copy this into ChatGPT, Claude, Gemini, or the Dock Editor, then set [MODE] to finding the total equivalent resistance, finding current and voltage at every resistor, or seeing a worked example.
Fill in [CIRCUIT_DESCRIPTION] naming each resistor's value and how it connects, such as 'R1 and R2 in series, that combination in parallel with R3.'
Only one series or parallel group gets combined per step, with the simplified network redrawn in words after each one, so you can see exactly where a mistake would show up.
Fill in [SOURCE_VOLTAGE] to work backward through the reduction and get the current and voltage at every single resistor, not just the total.
The output verifies the equivalent resistance dropped appropriately for any parallel paths, or that currents sum correctly at every junction, before calling the answer final.
Get a fully reduced network for homework with every series and parallel combination shown as its own step instead of a single jump to the answer.
Work out the equivalent resistance of a resistor network you're actually building, then get the current and voltage at each individual resistor for a bill of materials.
Generate a step-by-step reduction as a model answer, ready to hand a student who keeps combining a series pair and a parallel pair in the same step.
Check a wiring practice problem before a lab exam, with the reduction shown clearly enough to follow without a textbook open next to it.
Discover more prompts that could help with your workflow.
Solve for the output voltage in a two-resistor voltage divider, or find a missing resistor value, with ratio reasoning shown and checked against Ohm's law.
Solve for the mechanical advantage of a lever, pulley, inclined plane, wheel and axle, or screw using the matching formula, with force-distance trade-offs made explicit.
Solve for the coefficient of friction, the frictional force, or the normal force using mu equals F over N, distinguishing static from kinetic friction throughout.
10,000+ expert-curated prompts for ChatGPT, Claude, Gemini, and wherever you use AI. Our extension helps any prompt deliver better results.