Integrating over the current gives the total magnetic field. An integration variable s is defined in the diagram below. We want to integrate over the infinitely long straight wire to determine the magnetic field at point P which is a distance R from the wire. Which statement below is true? HọI 27R ds s so B = J_ A R²(R²+s?)/² R+s? r = R and sin ø 1/2 ds R r = s and sin ø so B = [ -00 4T s2(R²+s²)/2 R²- 2nR HoI HoI so B = J_∞ A (R²+s²)°² ds s R² + s² and sin ø r = R²+s² 2TR V so B = J An R(R²+s²)/² R ds r = R and sin d VR R² 27R ts2 HọI ds R so B = J0 An (R²+s?)%/² R r = VR² + s² and sin ø R²+ +s² 3/2 2nR

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Integrating over the current gives the total magnetic field. An integration variable s is defined in the diagram below. We want to integrate over the infinitely long straight wire to determine the magnetic field at point P which is a distance R from the wire. Which statement below is true? ds P---- so B = [∞ H,I R²+s² ds s R and sin ø = r = 2TR ds R R so B = J_∞ 4n s²(R²+s²)/² r = s and sin ø R²+s² 2nR O HoI so B = J_∞ 4n (R²+s²)°/² ds s HoI r = VR? + s² and sin ø R²+s? 2TR R ds HI R and sin ø = So B R²+s² Lo AT R(R²+s²)'/² 2TR O HoI so B = J_∞ 4n (R²+s²)®/² R ds R r = R + s² and sin o R²+s² 2nR