Part A
Find the transfer function \(V_{o} / V_{i}\) for the circuit shown in (Figure 1).
Express your answer in terms of \(R_{1}, R_{2}, C_{1}, C_{2}\) and \(s\).
Part B
What is the gain of the circuit as \(\omega \rightarrow 0\) ?
Express your answer in terms of \(R_{1}, R_{2}, C_{1}\), and \(C_{2}\).
Part C
What is the gain of the circuit as \(\omega \rightarrow \infty\) ?
Express your answer in terms of \(R_{1}, R_{2}, C_{1}\), and \(C_{2}\).
Find the transfer function Vo / Vi for the circuit shown in (Figure 1).
Find the Equivalent ResistanceFour resistors are connected as shown in figure (a), below. (Let R=3.00 Ω.)The original network of resistors is reduced to a single equivalent resistance.(a) Find the equivalent resistance between points \(a\) and \(\mathrm{c}\).solutionConceptualize Imagine charges flowing into and through this combination from the left. All charges must pass from a to \(b\) through the first two resistors, but the charges split at \(b\) into Categorize Because of the simple nature of the combination of resistors in the...
Question 1 For the circuit shown in figure 1; i. Find the transfer impedance function, H(s) = Vds(s) Find the poles and zeros for this transfer function and plot them on the s - Find the magnitude of the transfer function in decibels. [10] s-plane [8] ii [3] 2H 20 20 2 H Figure Question 2 The hybrid parameters (h-parameters) for the two -port network circuit in figure 2 are; 5 h=2 0.05 Find the equivalent impedance parameters (z-parameters) Find...
Find the transfer function Vo(s)/V(s) for the circuit shown in the figure. 1. IH OO00 H w 0000 TH IF IF
Find the transfer function G(s)=Vo(s)/Vi(s) for the electrical network shown in the figure below. Express the transfer function G(s) as a ratio of polynomials.
Find the transfer function G(s)=Vo(s)/Vi(s) for the electrical network shown in the figure below. Express the transfer function G(s) as a ratio of polynomials.
Please answer number 1 1. Find the transfer function Voda)/Vin(a) for the circuit shown in Figure 1 of the lab (where complex frequency variable s jo can be substituted for ease of analysis.) Calculate values for R and C such that the phase shift between the output and input is zero for an input frequency of 10kHz. What is the amplitude ratio (gain) of the output to the input at this frequency. 2. The RC network in figure 3 of...
thx!!!! Question 3 (5.5 marks) a) Find the transfer function of the electrical circuit shown in Figure 1. What is the value of the steady state gain(s), if any? b) If R1 1, R2 = 2n, C\ = 2- 10-3F, C 1-10-3F, calculate the time constants of the system (if any). c) Find the initial and final values of the unit impulse response of the circuit d) Derive the time-domain expression of the output if the input is the function...
For the differential amplifier shown in Figure (2),assume \(\mathrm{VCC}=12 \mathrm{~V}, \mathrm{VEE}=-12 \mathrm{~V}, \mathrm{Rc}=2 \mathrm{k} \Omega\), and \(\beta=100\) for all transistors.For the current source circuit (Transistor \(\left.Q_{3}\right): R_{1}=4 k \Omega, R_{2}=4 k \Omega, R_{3}=3 \mathrm{k} \Omega\), and \(r_{0}=100 \mathrm{k} \Omega\).a) In differential amplifier circuits, what do "well-matched transistors" mean?b) Why it is important to use well-matched transistors in differential amplifier circuits?c) What are the operating \(Q\) point values \(\left(I_{c Q}\right.\) and \(\left.V_{C Q}\right)\) for the transistors \(Q_{1}\) and \(Q_{2}\) ?d) Draw...
\(R_{a}=\) armature winding resistence \(L_{a}=\) armature winding inductanc \(K_{b}=\) back \(-\) emf constant \(K_{t}=\) motor \(-\) torque constant \(J_{1}=\) moment of inertia of the totor of the motor \(b_{1}=\) viscous \(-\) friction coef ficient of the rotor of the motor \(J_{2}=\) moment of inertia of the load \(b_{2}=\) viscous \(-\) friction coef ficient of the load \(n=\) gear ratio \(=\frac{N_{1}}{N_{2}}\) 1a. Obtain the transfer function \(\frac{\theta_{2}(s)}{E_{a}(s)}\)1b. Obtain the steady state response \(\theta_{2 . s . s}=\lim _{t \rightarrow \infty} \theta_{2}(t)=\lim _{s...
Please help with this dynamics circuit analysis. Please show work and explain. Thank you!! 1. Consider the circuit shown below. Cl e, (0) c, e。(t) Find the transfer function below using time-domain and impedance methods. (a) Determine the differential equation for the relationship between eo(1) and e(1) (b) Find the transfer function E, (s)/E,(s) and determine the system time constant in terms of the circuit element values C, C, and R 17 2 (c) Find the transfer function E, (s)/E,...