+4V PMOS (WL)2-8 -0.03 V-1 NMOS: (WL)s-2 =0.02 V-1 Re 50 Ω Consider the circuit shown...
Problem #5. Consider the amplifier circuit below. The NMOS has Vi-1.2V and (1/2)kn'(WL)-12.5 mA/V2, Cgs-15pF. Cgd-9pF The PNP has β-150. C,-25pF, and dju 11pF (a) Find the DC drain and collector currents. b) Find the midband gain Vout/ Vs of the entire circuit (c) Estimate the lower 3 dB point of the amplifier (d) Estimate the upper 3 dB point of the amplifier 47uF 300 Rs10K 0.22uF 6.8K Q2 Vin 47K 2.2uF 1.0K 6V Problem #5. Consider the amplifier circuit...
The circu with (WL)1-4 50/0.5 and Iss 21 0.5 mA. (a) Calculate the small-signal voltage gain. (b) Determine the maximum output voltage swing if the input CM level is 1.3 V. Figure 5.23 (a) Differential pair with current-source load; (b) circuit for calculation of Gmi (c) circuit for calculation of Rout uit of Fig. 5.23(a) is designed VDD M3 M4 Vout Vin Iss The circu with (WL)1-4 50/0.5 and Iss 21 0.5 mA. (a) Calculate the small-signal voltage gain. (b)...
Please answer the question showing all the work step by step. Thank you 5 V 1. CMOS Inverter: Consider a CMOS inverter shown on the right. 2-1 For PMOS: ZIL-10, μ,-400 cm"V"s", Vr--1V; for NMOS: ZL=5, μ,-1000 cm2V'sı, VT-1 V, and the oxide capacitance are the same for both devices. Using the square law model: a) Calculate the input voltage when both transistors are in O Vout saturatiorn b) Calculate Vout at Vin-2V 5 V 1. CMOS Inverter: Consider a...
Consider the circuit shown in (Figure 1). The batteries have emfs of ε1 = 9.0 V and ε2 = 12.0 V and the resistors have values of R1 = 27Ω, R2 = 60 Ω, and R3 = 33 Ω. Determine the magnitudes of the currents in each resistor shown in the figure. Ignore internal resistance of the batteries. Determine the directions of the currents in each resistor. Ignore internal resistance of the batteries.
1. Consider NMOS transistor in the circuit that has u.Cox = 0.4 mA/V?, W/L = 25, and V.=0.4V. (20 pts) (a) Find the value of Vas that results in saturation mode operation with a lp current of 0.1 mA. Neglect the Early effect. (2.5 pts) +1.5 V in BRD (b) Find the value of Rp that results in a de drain voltage of 0.5V. (2.5 pts) = = = (e) Find gw and r, at the de operating point specified...
Answers labeled clearly please Consider the circuit shown in the figure below. (Let R-6.20 Ω and Δν-22.0 V.) 2.40 2 ΔΙ. 9.00 Ω (a) Find the equivalent resistance of the circuit in the figure above. (b) Find the potential difference across each resistor. AVce - AVcd AVfd (c) Find each current indicated in the figure above. (d) Find the power delivered to each resistor. ac ce cd ed Consider the circuit shown in the figure below. (Let R-6.20 Ω and...
1 bias V. out 2 2:1 mirror 6:52 PMw Variahle 2:1 mirror S Transistor PMOS Transistor Variable NMO 1 00 0.5 0.10 35 0.5 0.20 VT (V) A (1M) L (um) Vdd is 3V The bias current is 40μΑ the bias voltage at the rot. Vin-is2.8V, and thie voltage ut port a is O.7V. The load capacitance (CL) is Sp The NMOS current mirror is 2:1 NOTE: All 3 devices are NMOS above Include proper units for full credit and...
2.A common-emitter circuit with an emitter bypass capacitor is shown in Figure 2(a) and its small-signal equivalent is as in Figure 2(b). Let V' = 10 V, V-=-10 V, RE-4 kQ. Re 2 kQ, CE 50 μF, VED(0) 0.7 V, β 100, VT 0.026 V and VA- Prove that the voltage gain transfer function of the circuit is given by: a) b) Find the values of the time constants τΑ and t, and the corresponding corner frequencies fa and fa....
Problem#1 Consider the circuit. The circuit parameters are Vpp = 3.3 V, RD = 8 k1, R, = 240 k12, R2 = 60 k22, and Rs = 2 k12. The transistor parameters are Vrn = 0.4 V, k', = 100 MA/V?, W/L = 80, and 1= 0.02 V!. (a) Determine the quiescent values Ipo and Vpsp. Ans: 0.27 mA; 1.14 V. (b) Find the small-signal parameters g.m and ro. Ans: 2.078 mA/V; 185 62. (e) Determine the small-signal voltage gain...
IX With reference to the transistor amplifier shown in Figure QB4 below d For the bipolar transistor circuit of Figure QB4 the following DC bias conditions were measured: VB made. 1.6 V and VBE =0.6 V. Detemine the value for RA, stating any assumptions e) Using these same conditions, calculate the current in Re and deduce the current in Rc, stating any assumptions made. Hence find the voltage across Rc and explain whether this voltage is suitable for this amplifier...