Vin R arcuit: If we apply a sinusoidal input voltage, V₁, the Vout output voltage, VIN, will be sinusoidal as well. The frequency of Vour and VN will be identical, but the amplitude and phase angle of Vour will vary from as described by: If VIN = A sin(wt) then VouT= A, sin(wt + p) The frequency response plot is a plot of A, /A, versus w. The ratio of A/A is referre to as a "transfer function" (how much of the amplitude of the input is "transferred" to

 

 

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20 230 40 50 Vin H=- My R If VIN = A sin(wt) then Vour = A, sin(wt + p) The frequency response plot is a plot of A, / A versus w. The ratio of A, / A is referred to as a "transfer function" (how much of the amplitude of the input is "transferred" to the output). It is usually plotted on semi-log paper. In ENGR 204 and ENGR 251 the equation that describes the transfer function is: where H = the ratio of A./A √1 + (RC)² Usually His expressed in decibels as Hoe = 20 log₁0 (H) = 20 log₁0 Low PRCF Tunction O The phase angle, D, can be expressed as = -tan¹ (RCw) Write a MATLAB script that will ask the user for the following information: a. The resistance R (in ohms) b. The capacitance (in far ads) c. The starting frequency (w) in radians/sec d. The ending frequency (w₂) in radians/sec Low PRCF Phase Angle 16² Phase -10- 1. (is) 1Tits) The circuit shown below is an RC circuit: 30- If we apply a sinusoidal input voltage, V, the out output voltage, VIN will be sinusoidal as well. The frequency of Vour and VN will be identical, but the amplitude and phase angle of Vour will vary from VIN as described by: -30 -20 1+ (RC) After the user enters the above data use the subplot command to plot two charts: the transfer function Hoe and the phase angle up as functions of w on semilog graphs. For R = 10KS2, C = 0.1μF, ₁-1 rad/sec, and w₂1 Mrad/sec you should generate the plots to the left. Make sure your plots have the same overall title and x/y-axis titles as the graphs to the left for full credit