Microelectronic Circuits (The Oxford Series in Electrical and Computer Engineering) 7th edition
7th Edition
ISBN: 9780199339136
Author: Adel S. Sedra, Kenneth C. Smith
Publisher: Oxford University Press
expand_more
expand_more
format_list_bulleted
Concept explainers
Question
Chapter 5, Problem 5.55P
a.
To determine
The labeled voltages in the given circuit diagrams.
b.
To determine
The values of replaced resistor in place of current source keeping the same current in the circuit.
Expert Solution & Answer
Trending nowThis is a popular solution!
Students have asked these similar questions
A 5-V, 10-MHz oscillator have a rise/falltime of 10ns and a 50% duty cycle is applied to a gate. Determine the value of the capacitance such that the 5th harmonic is reduced by 20 dB in the gate voltage Vg(t).
For many years, MOS devices were scaled tosmaller and smaller dimensions without changingthe power supply voltage. Suppose that the widthW, length L, and oxide thickness Tox of a MOS transistor are all reduced by a factor of 2. Assume thatVT N , vGS, and vDS remain the same. (a) Calculatethe ratio of the drain current of the scaled device tothat of the original device. (b) By what factor hasthe power dissipation changed? (c) By what factorhas the value of the total gate capacitance changed?(d) By what factor has the circuit delay Tchanged?
4) By drawing the small signal model of the circuit given below, we can determine the total voltage and current gain values of the circuit, without the bypass capacitor on and without the bypass capacitor.
Calculate separately for the two cases as it will be in the circuit (connected to the emitter end of the transistor).
(β = 100, rS = 600 Ω, R1 = 27 KΩ, R2 = 4.7 KΩ, RC = 3.3 KΩ, RE = 680 Ω, RL= 15 KΩ, VCC = 10 V)
Chapter 5 Solutions
Microelectronic Circuits (The Oxford Series in Electrical and Computer Engineering) 7th edition
Ch. 5.1 - Prob. 5.1ECh. 5.1 - Prob. 5.2ECh. 5.1 - Prob. D5.3ECh. 5.2 - Prob. 5.4ECh. 5.2 - Prob. 5.5ECh. 5.2 - Prob. 5.6ECh. 5.2 - Prob. 5.7ECh. 5.3 - Prob. D5.8ECh. 5.3 - Prob. D5.9ECh. 5.3 - Prob. D5.10E
Ch. 5.3 - Prob. 5.11ECh. 5.3 - Prob. 5.12ECh. 5.3 - Prob. D5.13ECh. 5.3 - Prob. D5.14ECh. 5.3 - Prob. 5.15ECh. 5.4 - Prob. 5.16ECh. 5.4 - Prob. 5.17ECh. 5 - Prob. 5.1PCh. 5 - Prob. 5.2PCh. 5 - Prob. 5.3PCh. 5 - Prob. 5.4PCh. 5 - Prob. D5.5PCh. 5 - Prob. 5.6PCh. 5 - Prob. D5.7PCh. 5 - Prob. 5.8PCh. 5 - Prob. 5.9PCh. 5 - Prob. 5.10PCh. 5 - Prob. 5.11PCh. 5 - Prob. 5.12PCh. 5 - Prob. 5.13PCh. 5 - Prob. 5.14PCh. 5 - Prob. 5.15PCh. 5 - Prob. 5.16PCh. 5 - Prob. 5.17PCh. 5 - Prob. 5.18PCh. 5 - Prob. 5.19PCh. 5 - Prob. D5.20PCh. 5 - Prob. 5.21PCh. 5 - Prob. 5.22PCh. 5 - Prob. 5.23PCh. 5 - Prob. 5.24PCh. 5 - Prob. 5.25PCh. 5 - Prob. 5.26PCh. 5 - Prob. 5.27PCh. 5 - Prob. 5.28PCh. 5 - Prob. 5.29PCh. 5 - Prob. 5.30PCh. 5 - Prob. 5.31PCh. 5 - Prob. D5.32PCh. 5 - Prob. D5.33PCh. 5 - Prob. 5.34PCh. 5 - Prob. 5.35PCh. 5 - Prob. D5.36PCh. 5 - Prob. 5.37PCh. 5 - Prob. 5.38PCh. 5 - Prob. 5.39PCh. 5 - Prob. 5.40PCh. 5 - Prob. 5.41PCh. 5 - Prob. 5.42PCh. 5 - Prob. 5.43PCh. 5 - Prob. D5.44PCh. 5 - Prob. 5.45PCh. 5 - Prob. D5.46PCh. 5 - Prob. 5.47PCh. 5 - Prob. D5.48PCh. 5 - Prob. D5.49PCh. 5 - Prob. D5.50PCh. 5 - Prob. D5.51PCh. 5 - Prob. 5.52PCh. 5 - Prob. D5.53PCh. 5 - Prob. 5.54PCh. 5 - Prob. 5.55PCh. 5 - Prob. 5.56PCh. 5 - Prob. 5.57PCh. 5 - Prob. 5.58PCh. 5 - Prob. 5.59PCh. 5 - Prob. 5.60PCh. 5 - Prob. 5.61PCh. 5 - Prob. 5.62PCh. 5 - Prob. 5.63PCh. 5 - Prob. 5.64PCh. 5 - Prob. 5.65PCh. 5 - Prob. 5.66PCh. 5 - Prob. 5.67P
Knowledge Booster
Learn more about
Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, electrical-engineering and related others by exploring similar questions and additional content below.Similar questions
- derive an expression for the voltage gain of a single stage ce transistor amplifier drived by a voltage source (don't use millers approximation)arrow_forwardIn the context of MOS devices, state briefly the advantages of:(a) constant field scaling(b) high-κ dielectrics(c) mid-gap metalsarrow_forwardConsider the transistor characteristics of Fig. 5.21. (a) Are these the characteristics of a JFET, d-mosfet, or e-mosfet? (b) Make a table of the given Vgs values and the corresponding Id(sat) values. Also include a column in the table giving Id(sat). (c) Make a plot of Id(sat) versus Vgs. Find the slope and y-intercept of the plot and use these to determine values for K and Vt in the model equation Eq. (5.3).ANSWER TO (c) MUST BE K = 1 mA/V2, Vt = −3 Varrow_forward
- In the circuit in the figure, VGSQ = 6.8 V, IDQ = 2.4 mA, VGS(Th) = 3.3 V, k = 0.4x10-3 A/V2, RD = 5.6 kΩ, RF = 2.2 MΩ and rd = 25 kΩ. Accordingly, when a RL = 0.1 kΩ load is connected to the output of the circuit, what will be the voltage gain of the circuit? NOTE: MOSFET output resistance must be taken into account in rd calculationsarrow_forwardQ 3 Bring out the advantages and disadvantages of microwave tube devices andsemiconductor devices.What are the most common types of microwave diodes and transistors in use give theirbasic features features and applications?What are the most common types of microwave ICs? Give details of the circuit elementsand applicationsarrow_forwardNorton's Theorem Compute for IN, RN and the current passing though the 50 ohmresistor, I’.arrow_forward
- For a mosfet amplifier circuit, how can I choose an input and output capacitor with poles at 10Hz and 100Hz? Where RC = 1/w.arrow_forward5. Choose the correct answer: a) The reason of high input resistance of the MOSFET is: 1. The insulator layer. 2. The reverse biasing. 3. The forward biasing. b) Which transistor has no Ipss parameter?. 1. JFET. 2. E-MOSFET. 3. D-MOSFET. ¢) For an n-channel D-MOSFET transistor, at what condition can gm be greater than gmo?. 1. Vs is positive. 2. Vgs is negative. 3. Vas =0. d) A certain amplifier has an Rp=1KQ. When a load resistance of 1KQ is capacitively coupled to the drain, the gain will reduce to the: 1. Half. 2. Quarter. 3. Not change.arrow_forwardGiven: Voltage Divider Bias Circuit Supply: 10Vdc to 24Vdc Load: 1000 ohms Voltage Gain: 80 to 400 Lower Cutt off Frequency: 100Hz Sinusoidal source (zero internal resistance): 50mVp-p Transistor: Si, beta=75 Base-Collector Capacitance= 8pF Base-Emitter Capacitance= 25pF Design a Single-stage Common Emitter Class A Amplifier and compute the following: a) dc load line b) hie c) midband gain d) Miller equivalent Capacitances e) upper cut off frequencyarrow_forward
- A. Design a fixed bias-transistor circuit using VBB = VCC = 10 V for a Q-point of IC = 5 mA and VCE_ 4 V. Assume βDC = 100.The design involves finding RB and RC. B. 4. Design an emitter bias network at Q-point ICQ = ½ ICsat and VCEQ = ½ VCC. Use VCC = 20 V, ICsat = 10 mA, β = 120, and RC = 4REarrow_forwardFor the transistor , IS = 4 × 10−16 μA,βF = 75, and βR = 4. (a) Label the collector, base,and emitter terminals of the transistor. (b) What isthe transistor type? (c) Label the emitter-base andcollector-base voltages, and label the normal direction for IE , IC, and IB. (d) Write the simplified formof the transport model equations that apply to thisparticular circuit configuration. Write an expressionfor IE /IB. Write an expression for IE /IC. (e) Findthe values of IE , IC, IB, VC B, and VE B.arrow_forwardGain of the amplifier falls of at high frequency due to internal capacitance of MOSFET. Determine the capacitances between different terminals of MOS transistor when it is operating in linear region at the drain to source voltage of 1 V. Device geometry and parasitic capacitances of MOSFET are: Gate oxide thickness 5 nm, channel length of 0.25 μm, width of the transistor 5 μm, gate overlap/lateral diffusion 10 % of channel length, junction capacitances at zero bias Csb0=Cdb0= 10 fF, built in potential of 0.4 V. Potential difference between source and bulk is 0.4 Varrow_forward
arrow_back_ios
SEE MORE QUESTIONS
arrow_forward_ios
Recommended textbooks for you
- Introductory Circuit Analysis (13th Edition)Electrical EngineeringISBN:9780133923605Author:Robert L. BoylestadPublisher:PEARSONDelmar's Standard Textbook Of ElectricityElectrical EngineeringISBN:9781337900348Author:Stephen L. HermanPublisher:Cengage LearningProgrammable Logic ControllersElectrical EngineeringISBN:9780073373843Author:Frank D. PetruzellaPublisher:McGraw-Hill Education
- Fundamentals of Electric CircuitsElectrical EngineeringISBN:9780078028229Author:Charles K Alexander, Matthew SadikuPublisher:McGraw-Hill EducationElectric Circuits. (11th Edition)Electrical EngineeringISBN:9780134746968Author:James W. Nilsson, Susan RiedelPublisher:PEARSONEngineering ElectromagneticsElectrical EngineeringISBN:9780078028151Author:Hayt, William H. (william Hart), Jr, BUCK, John A.Publisher:Mcgraw-hill Education,
Introductory Circuit Analysis (13th Edition)
Electrical Engineering
ISBN:9780133923605
Author:Robert L. Boylestad
Publisher:PEARSON
Delmar's Standard Textbook Of Electricity
Electrical Engineering
ISBN:9781337900348
Author:Stephen L. Herman
Publisher:Cengage Learning
Programmable Logic Controllers
Electrical Engineering
ISBN:9780073373843
Author:Frank D. Petruzella
Publisher:McGraw-Hill Education
Fundamentals of Electric Circuits
Electrical Engineering
ISBN:9780078028229
Author:Charles K Alexander, Matthew Sadiku
Publisher:McGraw-Hill Education
Electric Circuits. (11th Edition)
Electrical Engineering
ISBN:9780134746968
Author:James W. Nilsson, Susan Riedel
Publisher:PEARSON
Engineering Electromagnetics
Electrical Engineering
ISBN:9780078028151
Author:Hayt, William H. (william Hart), Jr, BUCK, John A.
Publisher:Mcgraw-hill Education,
NMOS vs PMOS and Enhancement vs Depletion Mode MOSFETs | Intermediate Electronics; Author: CircuitBread;https://www.youtube.com/watch?v=kY-ka0PriaE;License: Standard Youtube License