2. Assume a large signal input, VIN = 10V and a small signal input, vin = 0.05 sin(@t). The resistor, R1 = 1 kN, and the Zener diode is characterized by the i-v relation shown in Figure 1. Numerically evaluate the analytical expression for the output voltage from Pre-lab question 1. Note that the polarity of vout is such that a positive output voltage will result in a negative (reverse-biased) diode voltage.

hi there i am looking for a solution to part 1 please

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iz iz (mA) 8 4+ -4 -2 Vz (V) 2 -4 Zener voltage (Vz) Depletion region voltage drop -8 Figure 1.The voltage-current characteristics of a typical Zener diode.

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R1 Vin t VOUT VIN Figure 2. A simple voltage regulator using a Zener diode. 1. For the linear regulator shown in Figure 2, and assuming the slopes (in mA/V) from Figure 1 indicated in the introduction, write an analytical expression (i.e., in terms of Vz, Vin and VIN as well as the resistors R1 and the diode resistance) for the output voltage, VOUT, which includes both large (DC) and small (sinusoidal) signal components when the Zener diode is that characterized by the i-v relationship shown in Figure 1. 0.05 sin(@t). 2. Assume a large signal input, VIN = 10V and a small signal input, Vin = The resistor, R, = 1 k2, and the Zener diode is characterized by the i-v relation shown in Figure 1. Numerically evaluate the analytical expression for the output voltage from Pre-lab question 1. Note that the polarity of VOUT is such that a positive output voltage will result in a negative (reverse-biased) diode voltage.