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Transcript
Name ______________________________ ES 330 Electronics II Homework # 5 (Fall 2016 – Due Monday, October 17, 2016) Problem 1 (20 points) Consider the NMOS transistor “current source” schematic circuit: [Note: This is more appropriately called a “current sink.” Why?] For VDD = 1.3 volts and using I REF = 100 A (microampreres), the design requirement for the circuit cazlls for the output current IO to be nominally around 100 A. Transistors Q1 and Q2 are geometry matched in layout and both have gate length L = 0.5 m and gate width W = 5 m. The transistor parameters are as follows: the threshold voltage Vt = 0.4 volt and k’n = 500 A/V2. Page 1 (a) Find the value of resistor R that gives IO = 100 A. (b) In addition, the Early voltage V’A of the NMOS transistors is V’A = 5 V/A. Find the NMOS transistor’s output resistance ro. Problem 2 (20 points) You are presented with the current steering circuit shown schematically below: Page 2 Find the value of current IO in terms of I REF and the device (W/L) ratios. For Q1 and Q2 denote the gate width-to-length ratios as (W/L)1 and (W/L)2 ; for Q3 and Q4 denote the gate width-to-length ratios as (W/L)3 and (W/L)4. Problem 3 (20 points) Consider the basic “current mirror” in Figure 8.7 of Sedra & Smith. (a) Suppose transistor Q2 has m times larger emitter area than that of transistor Q1. [Note: This means that mI REF = IO, where m is the current transfer ratio.] Show that the current transfer ratio (show the derivation of the equation) can be expressed as: IO m I REF 1 m 1 Page 3 (b) If is specified to be a minimum of 120, what is the largest current transfer ratio m if the error between I REF and IO is less than or equal to 10% at most? Problem 4 (20 points) The two NMOS transistors in the “current mirror” below have equal channel lengths of L = 0.5 m, W1 = 10 m, W2 = 50 m, nCox = 500 A/V2 and an Early voltage V’A = 10 V/m. The input bias current ID1 = 100 A. [Note: The gate-to-source voltage vgs, and currents ii and io are all small-signal quantities.] Page 4 Derive expressions for the input resistance Rin, the current transfer ratio Ais and output resistance Ro. Problem 5 (20 points) Fiind the intriinsic gain of an NMOS transistor fabricated with a process for which k’n = 400 A/V2 and an Early voltage V’A = 10 V/m. The transistor process has a gate length L = 0.5 m and is operated at VOV = 0. 2 volt. Suppose we require a transconductance gm = 2 mA/V, what must (a) the drain current ID and (b) the gate width W be to meet this requirement? Page 5 What is the physical significance of the intrinsic gain of an active device?
