Problem 6: These drawings illustrate various situations in which a magnetic field is directed out of the screen, and there is a corresponding magnetic flux through a single loop. In drawings (a) through (d), the magnetic field has a constant magnitude of B=51.2 mT. The radius and the resistance of the ring in drawings (c) and (e) are 7.8 cm and 7.6 2, respectively. In drawings (e) and (f), the rate at which the magnetic field is either increasing or decreasing has magnitude AB/At = 15 mT/s. * urrent. B increasing Part (c) In drawing (c), the circular conductive loop, which is in the plane of the screen, is entering the region of non-zero magnetic field with a speed of 0.50 m/s. Determine the magnitude, in milliamperes, of the average induced current during the interval from when the leading edge of the loop touches the boundary of that region until the entire ring is fully within it. Ic = 0.06 mA cos() sin() cotan() asin() tan() () 7 8 9 acos() ETA 4 5 6 atan() acotan() sinh) cosh() tanh() cotanh() Degrees O Radians /*123 0 + VO BACKSPACE Ie= mV cos() tan() asin() acos() E4 5 6 sinh() cotanh() sin() cotan atan() acotan()) cosh() tanh() Degrees Radians mA Part (d) If the speed of the moving conductive bar in drawing (d) is 1.2 m/s, and its length is 1.37 m, determine the magnitude, in millivolts, of the emf induced in the loop. /123 0 NO BACKSPACE (a) HOME (789 HOME (C) - END CLEAR END CLEAR (b) B (d) B decreasing Part (f) In drawing (e), the conductive loop is stationary, and the magnetic field is increasing. Determine the magnitude, in milliamperes, of the induced

I am needing help with c,d, anf f please

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# Problem 6 These drawings illustrate various situations in which a magnetic field is directed out of the screen and there is a corresponding magnetic flux through a single loop. In drawings (a) through (d), the magnetic field has a constant magnitude of \(B = 0.12 \, \text{T}\). The radius and the resistance of the ring in drawings (a) and (e) are \(7.8 \, \text{cm}\) and \(7.8 \, \Omega\), respectively. In drawings (c) and (f), the rate at which the magnetic field is either increasing or decreasing has magnitude \(\Delta B/\Delta t = 15 \, \text{mT/s}\). Figures: - **(a)** Circular loop with magnetic field directed through. - **(b)** Elliptical deformation of the loop. - **(c)** Rectangular loop with magnetic field through. - **(d)** Rectangular loop moving with velocity \(\vec{v}\). - **(e)** Circular loop with increasing magnetic field. - **(f)** Circular loop with decreasing magnetic field. ### Part (c) In drawing (c), the circular conductive loop, which is in the plane of the screen, is entering the region of non-zero magnetic field with a speed of \(0.50 \, \text{m/s}\). Determine the magnitude, in milliamperes, of the average induced current during the interval from when the leading edge of the loop touches the boundary of that region until the entire ring is fully within it. - **Induced Current, \(I_e\):** \(0.06 \, \text{mA}\). ### Part (d) If the speed of the moving conductive bar in drawing (d) is \(1.2 \, \text{m/s}\), and its length is \(1.37 \, \text{m}\), determine the magnitude, in millivolts, of the emf induced in the loop. - **Emf, \(e\):** ___________ mV (input required). ### Part (f) In drawing (e), the conductive loop is stationary, and the magnetic field is increasing. Determine the magnitude, in milliamperes, of the induced current. - **Induced Current, \(I_e\):** ___________ mA (input required).