Four capacitors each of capacitance are connected as shown in the figure. The capacitance between points A and B is: _____ (in ).

Four capacitors each of capacitance are connected as shown in the figure. The capacitance between points A and B is: _____ (in ).

Correct answer:64
Standard Method
Given: Each capacitor has capacitance .
Find: The equivalent capacitance between points and .
Concept Used: If all capacitors are connected across the same two nodes, they are in parallel, and their equivalent capacitance is the sum of individual capacitances.
Shorted or directly connected points are at the same potential and can be treated as a single node.
Step 1: The top rail is a single conductor and finally goes down to point . Hence every point on the top rail is at the potential of .
Step 2: The lower rectangular wire connects the two midpoints and drops to . Therefore the entire lower rectangular path is at the potential of .
Step 3: With these node identifications, each of the four capacitors is connected directly between the same two nodes and . Therefore, all four capacitors are in parallel.
Step 4: Add the capacitances in parallel.
Therefore, the equivalent capacitance between and is .
Direct Node Inspection
Given: Four identical capacitors, each of capacitance .
Find: Equivalent capacitance between and .
Instead of reducing the circuit branch by branch, inspect the nodes. The upper conductor is one common node ending at , and the lower conductor is one common node ending at . Since every capacitor has one plate on the upper node and the other plate on the lower node, all capacitors are in parallel.
Therefore, the correct numerical answer is 64.
Mistake: Treating the arrangement as a series combination by looking only at the drawing shape. Why it is wrong: series connection requires capacitors to share intermediate isolated nodes, which is not the case here. What to do instead: first identify equipotential points connected by ideal wires and then decide the combination.
Mistake: Ignoring that the top rail is a single conductor connected to and the lower rail is a single conductor connected to . Why it is wrong: this hides the fact that all capacitors are across the same two nodes. What to do instead: merge all directly connected wire segments into common nodes before calculating equivalent capacitance.
Mistake: Adding only two or three capacitors in parallel and missing one branch. Why it is wrong: all four capacitors connect between the same pair of nodes after node identification. What to do instead: check each capacitor plate-by-plate to confirm whether it lies across and .
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