P9:Consider this non-linear electrical circuit with R-64 4 and constant V (a) Derive the mathemat...
2. (a) Derive the mathematical model for the system shown; no need to simplify. (b) Draw the electrical circuit analogous to this system. 2 2. Circuit with Voltage Source Inductance (L) Capacitance (1/C) Resistance (R) Charge (4) Voltage (v) Current (i) Mechanical System Mass (m) Stiffness (k) Viscous damper (c) Displacement (x) Force () Velocity (ä)
Consider an RC circuit with E = 12.0 V ,R = 180 Ω , and C = 45.8 μF . (a) Find the time constant for the circuit. (b) Find the maximum charge on the capacitor. (c) Find the initial current in the circuit.
Problem 3 Consider the non-constant variance linear model Y, =Be + B111,1 + B,1,2 + ... + Bp-111.-1+€, (1) with G N(0,0?), i=1,..., 7. Define the reciprocal of the variance of as the weight w, and let w 0 0 W OW... 0... 02. We can estimate the non-constant variance model by minimizing the objective function w (9-Bo-Buca -.- Bp-111p-1) Task: Derive the weighted least squares equation (3) Bu = (XWX)-{XWY
Consider an RC circuit with E = 9.00 V, R = 165 ohms, and C = 55.7 uF. A) Find the time constant for the circuit. (in m/s) B) Find the maximum charge on the capacitor. (in uC) C) Find the initial current in the circuit. (in mA)
Consider an RC circuit with E = 12.0 V ,R = 165 Ω , and C = 45.8 μF . A) Find the time constant for the circuit. (units = ms) B) Find the maximum charge on the capacitor. (units = μC ) C) Find the initial current in the circuit. (unit = mA)
Consider a Sinusoidally Driven LC Electrical Circuit, which Contains an Electric Potential Oscillator, E E, cos(or), an Inductor, L, and a Capacitor, C. Note that an Oscillating Charge,g).Forms on the Capacitor Plates, as well as an Oscillating Current, I(). throughout the Circuit, which is Associated with the Driven Frequency, ω , as Shown. 1. 1(6) gt) E(r) Recall that the Electric Potential Over an Inductor is Given by E , and the dl dr Electric Potential Over a Capacitor is...
Consider a series RC circuit as in the figure below for which R 5.00 MO, C-8.00 μF. and ε 26.0 V. (a) Find the time constant of the circuit (b) What is the maximum charge on the capacitor after the switch is thrown closed? 208 (c) Find the current in the resistor 10.0 s after the switch is closed. what mathematical function describes the time dependence of the current in an RC circuit? ㎂
Problem 4 (50 pts): Consider the electrical circuit represented in figure, with R = 102, C = 1 F and L=1 H. Assume V (t) as input and i(t) as output E ER V.(t) a) (5 pts) Determine the differential equation of the system b) (5 pts) Find the transfer function of the system c) (20 pts) Write the symbolic expressions of magnitude and phase of the transfer function d) (20 pts) Determine the expression of steady-state response of the...
c. Your geeky electrical engineering friend has designed a new non-linear device called the terpistor. She has measured the i-v curve (below left) and placed it in a circuit (below right). Calculate V, and I, for the terpistor in the circuit using load line analysis. (10 pts) 6 4 4 92 0 10 v (volts) 20 0 0 30 Answer 6 operating 20 30 v (volts
c. Your geeky electrical engineering friend has designed a new non-linear device called the...
2. Consider the parallel RLC circuit mentioned in class, with C = 1, L = 4, and R = 1 (a) Derive the iin-to v transfer function, i.e., the circuit's impedance (b) Compute and plot the step response (c) Plot the magnitude of the frequency response function, G(jw) as a function of Compute, via analysis, the frequency wmar Wwhere maximum gain |G(jw)| is w. maximized (d) Verify your results using MATLAB: Plot the system's response to a step, and to...