4. Three charged, concentric, partial-circle thin rings are placed with the origin of the coordinate system at a uniform linear charge density of 2j. The middle positively charged semi-circle thin ring (shown in blue has a radius R; and a uniform linear charge density of d2. The inner positively charged quarter-circle thin ring (shown in green) has a radius R1 and a uniform linear charge density of di. a. Calculate the total electric potential (i.e., voltage) at the "center" of the two rings. {Express your answer in terms of ,d2 , and 2.} YOU MUST SHOW ALL WORK AND CALCULATIONS TO GET CREDIT...NO EXCEPTIONS! leged at the center of the ring

How do we find for Q and please explain. I’m stuck on this homework problem and can’t figured out how to find for Q

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4. Three charged, concentric, partial-circle thin rings are placed with the origin of the coordinate system at a uniform linear charge density of i. The middle positively charged semi-circle thin ring (shown in blue) has a radius R2 and a uniform linear charge density of h2. The inner positively charged quarter-circle thin ring (shown in green) has a radius R1 and a uniform linear charge density of 2i. a. Calculate the total electric potential (i.e., voltage) at the “center" of the two rings. {Express your answer in terms of Ai, A2 , and A3.} YOU MUST SHOW ALL WORK AND CALCULATIONS TO GET CREDIT...NO EXCEPTIONS! b. If a positive point charge, q, is brought in from very far away and placed at the center of the ring, calculate the change in electric potential energy for the system. R2 X.