Question

Notify Me Bookmark

In the circuits below, NMOS transistors are defined by Vtn = 1.5 V, k′n = 0.5 mA/V2, W = 1.2 μm, L = 200 nm, and λ = 0. And PMOS transistor has Vtp = −2.0 V, kp = 0.1 mA/V2, W = 1.0 μm, L = 200 nm, and λ = 0. Analyze the circuit below to find all node voltages and branch currents. Hint: First convert the input part to its Thevenin equivalent circuit.

In the circuits below, NMOS transistors are defined by Vtn = 1.5 V, k′n = 0.5 mA/V2, W = 1.2 μm, L = 200 nm, and λ = 0. And PMOS transistor has Vtp = −2.0 V, kp = 0.1 mA/V2, W = 1.0 μm, L = 200 nm, and λ = 0. Analyze the circuit below to find all node voltages and branch currents. Hint: First convert the input part to its Thevenin equivalent circuit.

Image text
In the circuits below, NMOS transistors are defined by V t n = 1.5 V , k n = 0.5 m A / V 2 , W = 1.2 μ m , L = 200 n m , and λ = 0 . And PMOS transistor has V t p = 2.0 V , k p = 0.1 m A / V 2 , W = 1.0 μ m , L = 200 n m , and λ = 0 .
Analyze the circuit below to find all node voltages and branch currents. Hint: First convert the input part to its Thevenin equivalent circuit.

Detailed Answer

0 0

Please enter your email here. You will get email when this question is answered by our tutor.

Doubtrix Logo

Problem is not yet solved!

Click on Notify me to get email when question is answered.

Join Doubtrix with 7-days free trial

  • Icon Correct & Verified Answers
  • Icon No AI-Generated Answers
  • Icon Video Solution for Difficult Questions
  • Icon Work With Experts to Reach at Correct Answers
Login Sign Up

Similar/Related Questions

For the circuit shown below, the NMOS transistor has Vtn = 0.5 V, kn = 1 mA/V2 and λn = 0, and the PMOS transistor has Vtp = −0.5 V, kp = 12.5 mA/V2, and |λp| = 0. Analyze the circuit to determine the currents in all branches and the voltages at all nodes. Note that the NMOS transistor (Q1) and its surrounding resistors are the same as the circuit you analyzed in Question 5. You may use the results found in Question 4 here.
Solution
0 0

Please design the differential amplifier shown in Fig. P3 to meet the following specifications: (1) Two NMOS transistors are matched: μnCox = 400 μA/V2, Vtn = 0.8 V, λn = 0.02 V−1, Wn = 4⋅Wp, L = 0.2μm. Please short the BODY to the SOURCE. (2) Two PMOS transistors are matched: μpCox = 200 μA/V2, Vtp = −0.8 V, λp = 0.04 V−1, Wp = TBD, L = 0.2 μm. Please short the BODY to the SOURCE. (3) ISS = 2 mA. (4) VS ≈ 0.3 V (5) The DC voltages of both vOP and vON ≈ 3.5 V. (6) The small-signal gain Av=(vop − von)/(vip − vin) ≈ 10. (7) The differential AC sinusoidal signal, vi = (vip−vin), has 100mV amplitude and 1kHz frequency. (8) VDD = 5 V. Design procedure: (a) Design Wp, Wn(= 4⋅Wp), VB, and RD by hand-calculations. Please round the resolution of Wp and Wn to 0.1μm. (Hint: λn and λp could be zero for your hand-calculations.) (b) Verify your design by a .OP simulation. Please report DC voltages of vS, vG, vOP and vON. (c) Verify your design by a .TRAN simulation. Please find Av and attach the waveforms of vIP, vIN, vOP, and vON in the same plot.
Solution
0 0

An NMOS amplifier is shown in Figure 1. Transistor M1 is biased in the saturation region for an amplifier application. The circuit is biased with a resistive voltage divider consisting of R1 and R2, a source degeneration resistor RS, and a load resistor RD. The drain bias current for the design is ID = 500 μA and VDS is 1.625 V. The device parameters are: L = 0.5 μm, W = 10 μm, kn’ = 200 μA/V2, Vtn = 0.5 V, and λn = 0. analyze the frequency response of the amplifier. a) Draw a midband small signal ac equivalent circuit model for the amplifier. For midband you can assume the reactance of Cin is sufficiently low that it is a short circuit. b) Derive an expression for the midband voltage gain transfer function Vout /Vsig. The amplified output signal is taken from the drain terminal and Vout = Vd. Write your gain function in terms of variables only. c) Evaluate the midband gain and calculate a value both in V/V and dB. d) Analyze the frequency response of the input network including the capacitor Cin. Find an expression for the transfer function H1(jω) = Vg/Vsig. e) Evaluate H1(jω) = Vg/Vsig and make a Bode plot of the magnitude of H1(jω). The x-axis is ω (log scale) and the y-axis is the magnitude in dB. f) Use the LTSPICE circuit template and verify the frequency response of the amplifier circuit. Include a copy of the schematic and the frequency response plot. Use 20 points per decade and a frequency span of 0.1 Hz to 100 Hz.
Solution
0 0