2. Suppose we have a pn junction that is slightly asymmetric. The p-type Si is doped to 10" cm* while the n-type Si is doped to 5x 10" cm. All plots should assume the p-type is on the left side. (a) Plot depletion region charge densities. Label local extrema. Label the depletion region edges on the p side and the n side as x, and x, respectively. Try to drawx, and x, to scale relative to each other. n (cm³) x [um] (b) Plot electric field; positive values mean pointing to the right. Label local extrema. Label the depletion region edges on the p side and the n side as x, and xa, respectively. Try to draw x, and X, to scale relative to each other. E (V/cm] x (um) (c) Plot electric potential, assuming the p-type is grounded, not the n-type. Label local extrema. Label the depletion region edges on the p side and the n side as x, and xa, respectively. Try to draw x, and x. to scale relative to each other. V [V] x [um]

2. Suppose we have a pn junction that is slightly asymmetric. The p-type Si is doped to 10" cm* while the n-type Si is doped to 5x 10" cm. All plots should assume the p-type is on the left side. (a) Plot depletion region charge densities. Label local extrema. Label the depletion region edges on the p side and the n side as x, and x, respectively. Try to drawx, and x, to scale relative to each other. n (cm³) x [um] (b) Plot electric field; positive values mean pointing to the right. Label local extrema. Label the depletion region edges on the p side and the n side as x, and xa, respectively. Try to draw x, and X, to scale relative to each other. E (V/cm] x (um) (c) Plot electric potential, assuming the p-type is grounded, not the n-type. Label local extrema. Label the depletion region edges on the p side and the n side as x, and xa, respectively. Try to draw x, and x. to scale relative to each other. V [V] x [um]

Power System Analysis and Design (MindTap Course List)

6th Edition

ISBN:9781305632134

Author:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Publisher:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Chapter4: Transmission Line Parameters

Section: Chapter Questions

Problem 4.2P: The temperature dependence of resistance is also quantified by the relation R2=R1[ 1+(T2T1) ] where...

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