Please do P6.4.6 only please!

T(C) 65 P6.4.4* Consider a pressure control loop that exhibits underdamped behavior. The pressure control loop is tuned for 0.10 overshoot, and T=61.4C T=60.3C the time period for oscillations is 1 minute. The control loop is tuned properly so that after the process reaches steady-state operation, there is no noticeable offset between the setpoint and the measured value of 60 the pressure. Develop a second-order transfer function for this closed-loop system assuming that the input is the pressure setpoint and the output is the measured value of the process pressure. 55 P6.4.5* Consider a temperature control loop that exhibits underdamped second-order behavior. The temperature control loop is tuned for a 1/8 decay ratio and the time period for oscillations is 14 minutes. The control loop is tuned properly so that after the process 50 reaches steady-state operation, there is no noticeable offset between 0 20 40 60 80 the setpoint and the measured value of the temperature. Develop a second-order transfer function for this closed-loop system assuming Time (s) that the input is the temperature setpoint and the output is the measured value of the process temperature. Figure P6.4.6 The closed-loop response of the CST thermal mixer to a setpoint P6.4.6*** The closed-loop response shown in Figure P6.4.6 was change. generated using the CST thermal mixer simulation. Using these results, determine as many characteristics of a second-order response as you are able. Then compare and analyze these results