Please provide MATLAB code and screenshot(s) of outputs Problem 3 (40 points): Now consider the clipper circuit below (assume R1 2R2). Unlike the half- and full-wave rectifiers you simulated before, the diode in this circuit does not simply turn on when Vin exceeds 0.7 V. Read the following properties of this circuit and develop an algorithm to plot the output waveform when the input is Vin (t) 5 cos(wt) When the input voltage is below the diode's forward built-in voltage (assume this to be 0.7 V), the diode is clearly OFF. The output voltage is determined by voltage division across the two resistors. This voltage is less than the input voltage When the input voltage is gradually increased and exceeds 0.7 V, the output voltage does not necessarily reach 0.7 V right away (due to voltage division); the diode can still remain OFF Only when vin is high enough to allow at least 0.7 V across R1, the diode turns ON. For any Vin above this value, Vout remains constant at 0.7 V Vin Please provide MATLAB code and screenshot(s) of outputs Problem 3 (40 points): Now consider the clipper circuit below (assume R1 2R2). Unlike the half- and full-wave rectifiers you simulated before, the diode in this circuit does not simply turn on when Vin exceeds 0.7 V. Read the following properties of this circuit and develop an algorithm to plot the output waveform when the input is Vin (t) 5 cos(wt) When the input voltage is below the diode's forward built-in voltage (assume this to be 0.7 V), the diode is clearly OFF. The output voltage is determined by voltage division across the two resistors. This voltage is less than the input voltage When the input voltage is gradually increased and exceeds 0.7 V, the output voltage does not necessarily reach 0.7 V right away (due to voltage division); the diode can still remain OFF Only when vin is high enough to allow at least 0.7 V across R1, the diode turns ON. For any Vin above this value, Vout remains constant at 0.7 V Vin