A current carying wire(wire-1) with é = 10 Amperes is placed at the origin on the Y-Z plane. Another current carrying wire(wire-2) with iz = 12 Amperes is placed l=8m distance apart on the Y-axis. The point Pa is ly = 6m from the wire-1. P, (0, 6, 6). P, (0,6,0) and the point P3 (0, 6, 7) are on the same line. The direction of the current is given in the figure. Step 1: Consider a wire-1 only. ) Calculate magnetic field at P1 (x. y and z component) ) Calculate the magnetic field at P2 (x. y and z component)

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Use the following constants if necessary. Coulomb constant, k = 8.987 x 10° N - m? /C. Vacuum permitivity, co = 8.854 x 10 13 F/m. Magnetic Permeability of vacuum, Ho = 12.5663706144 x 10 H/m. Magnitude of the Charge of one electron, e = -1.60217662 x 10 19 C. Mass of one electron, 7y = 9.10938356 x 10 31 kg. Unless specified otherwise, each symbol carries their usual meaning. For example, µC means micro coulomb dz wire Y wire 2 de K-- l, - K.- 1,- A current carying wire(wire-1) with é = 10 Amperes is placed at the origin on the Y-Z plane. Another current camying wire(wire-2) with iz = 12 Amperes is placed l= 8 m distance apart on the Y-axis. The point Pa is l1 = 6m from the wire-1. P (0, 6, 6). P, (0,6, 0) and the point P3 (0,6, 7) are on the same line. The direction of the current is given in the figure. Step 1: Consider a wire-1 only. i) Calculate magnetic field at P1 (x. y and z component) ii) Calculate the magnetic field at P2 (x. y and z component)