Difference between revisions of "EE 220"

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references and translinear circuits. Discrete-time signals. Switched-capacitor circuits. Co-req: CoE 143 or equiv. 6h (3 lec, 3 lab) 4 u.
 
references and translinear circuits. Discrete-time signals. Switched-capacitor circuits. Co-req: CoE 143 or equiv. 6h (3 lec, 3 lab) 4 u.
  
== Content ==
+
== Syllabus ==
  
 
{| class="wikitable"
 
{| class="wikitable"
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! scope="col"| Activities
 
! scope="col"| Activities
 
|-
 
|-
| 1
+
| style="text-align:center;" | 1
 
|  
 
|  
CMOS Technology and Fabrication
+
[[CMOS Technology and Fabrication]]
 
* Deep submicron issues
 
* Deep submicron issues
 
* Process variations
 
* Process variations
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* Perform simple circuit simulations using a ''ngspice''.
 
* Perform simple circuit simulations using a ''ngspice''.
 
|  
 
|  
* Video: Silicon Run I (1996) ([https://www.youtube.com/watch?v=3XTWXRj24GM Youtube link])
+
* Video: Silicon Run I (1996) [https://www.youtube.com/watch?v=3XTWXRj24GM Youtube link]
* ''ngspice'' Tutorial
+
* [[ngspice Tutorial]]
 
|
 
|
 +
* [[220-A1.1]]: IC fabrication
 +
* [[220-A1.2]]: A Wideband Voltage Divider Circuit
 
|-
 
|-
| 2
+
| style="text-align:center;" | 2
| Passive CMOS Devices
+
|  
 +
[[Passive CMOS Devices]]
 
* Resistors
 
* Resistors
 
* Capacitors
 
* Capacitors
Line 40: Line 43:
 
* Verify these effects via circuit simulation.
 
* Verify these effects via circuit simulation.
 
|
 
|
 +
* Spyder IDE [https://www.spyder-ide.org/ website]
 +
* [[Using Python with ngspice]]
 
|
 
|
 +
* [[220-A2.1]]: Integrated Resistors and Capacitors
 
|-
 
|-
| 3
+
| style="text-align:center;" | 3
 
|  
 
|  
MOS Transistors
+
[[MOS Transistors]]
* Analog vs. Digital
 
 
* Transistor Models
 
* Transistor Models
 +
* Short-Channel Effects
 
|  
 
|  
 
* Identify, model, and analyze the effects of CMOS process parameters on the characteristics of MOS transistors.
 
* Identify, model, and analyze the effects of CMOS process parameters on the characteristics of MOS transistors.
 
* Verify these effects via circuit simulation.
 
* Verify these effects via circuit simulation.
 
|
 
|
* Arizona State University Predictive Technology Models (PTM) [http://ptm.asu.edu/ website].
+
* Arizona State University Predictive Technology Models (PTM) [http://ptm.asu.edu/ website]
 +
* SkyWater [[SKY130 Models]] (130nm CMOS)
 
|
 
|
 +
* [[220-A3.1]]: MOS characteristic curves simulation
 +
* [[220-A3.2]]: Extracting MOS small-signal parameters
 +
* [[220-A3.3]]: The MOS transition frequency
 
|-
 
|-
| 4
+
| style="text-align:center;" | 4
 
|  
 
|  
Model-Based Design
+
[[Model-Based Analog Circuit Design]]
 +
* Small-Signal Model
 +
* <math>\tfrac{g_m}{I_D}</math> and <math>V^*</math>
 
|  
 
|  
* Design simple single-transistor amplifiers using SPICE models as a replacement for closed-form models.
+
* Design simple single-transistor amplifiers using SPICE models as an alternative to closed-form models.
 
* Verify these designs via circuit simulation.
 
* Verify these designs via circuit simulation.
 
|
 
|
 
|
 
|
 +
* [[220-A4.1]]: MOS Intrinsic Gain
 +
* [[220-A4.2]]: Simulating <math>\tfrac{g_m}{I_D}</math>
 +
* [[220-A4.3]]: Design of a Simple Common-Source Amplifier
 
|-
 
|-
| 5
+
| style="text-align:center;" | 5
 
|  
 
|  
Electronic Noise
+
[[Electronic Noise]]
* Thermal Noise
+
* [[Resistor Noise]]
* Shot Noise
+
* [[Diode and Transistor Noise]]
* Flicker Noise
+
* [[EE 220 Noise Analysis | Noise Analysis]]
* Noise Analysis
 
 
|  
 
|  
 
* Identify the fundamental types of electronic noise and differentiate one noise type from another.
 
* Identify the fundamental types of electronic noise and differentiate one noise type from another.
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|
 
|
 
|
 
|
 +
* [[220-A5.1]]: Device noise power-spectral density and total integrated device noise
 +
* [[220-A5.2]]: Amplifier output noise and input-referred noise
 
|-
 
|-
| 6
+
| style="text-align:center;" | 6
| Noise and Feedback
 
 
|  
 
|  
 +
[[Operational Transconductance Amplifiers (OTAs)]]
 +
* Op-Amps vs. OTAs
 +
* Switched-Capacitor Feedback
 +
|
 +
* Differentiate between operational amplifiers (Op-Amps) and operational transconductance amplifiers (OTAs).
 +
* Analyze OTA circuits with capacitive feedback.
 +
* Verify the behavior of these circuits via simulation.
 
|
 
|
 
|
 
|
 +
* [[220-A6.1]]: Transient response of an OTA with capacitive feedback
 
|-
 
|-
| 7
+
| style="text-align:center;" | 7
| Operational Transconductance Amplifiers (OTA)
 
 
|  
 
|  
 +
[[Differential Circuits]]
 +
* Differential-Mode
 +
* Common-Mode
 +
* CMRR, PSRR
 +
* Baluns
 
|
 
|
 +
* Differentiate and identify the advantages/disadvantages and cost-benefit trade-offs between fully-differential circuits vis-a-vis single-ended circuits.
 +
* Model and analyze the behavior of fully-differential circuits.
 +
* Verify the behavior of these circuits via simulation.
 
|
 
|
 +
|
 +
* [[220-A7.1]]: Differential-mode amplifier gains
 +
* [[220-A7.2]]: Common-mode Rejection Ratio
 +
* [[220-A7.3]]: Input-referred offset
 
|-
 
|-
| 8
+
| style="text-align:center;" | 8
| Differential Amplifiers
 
 
|  
 
|  
 +
[[Current Mirrors]]
 +
* Cascoding
 +
* Common-Mode Feedback
 +
|
 +
* Model, analyze, and design current mirror circuits for biasing fully-differential and single-ended OTAs.
 +
* Model, analyze, and design common-mode feedback (CMFB) circuits in differential OTAs.
 +
* Verify the behavior of these circuits via simulation.
 
|
 
|
 
|
 
|
 +
* [[220-A8.1]]: Amplifier output swing
 +
* [[220-A8.2]]: Gain-boosted current mirror frequency response
 +
* [[220-A8.3]]: Basic common-mode feedback circuits
 
|-
 
|-
| 9
+
| style="text-align:center;" | 9
| The Folded-Cascode OTA
+
|  
 +
[[The Folded-Cascode OTA]]
 +
* DC Characteristics
 +
* Small-signal Characteristics
 +
* Noise
 
|  
 
|  
 +
* Identify the advantages and disadvantages of a folded-cascode OTA.
 +
* Model and analyze the DC and small-signal characteristics of a folded-cascode OTA.
 +
* Verify the behavior of these characteristics via simulation.
 
|
 
|
 
|
 
|
 +
* [[220-A9.1]]: Biasing the folded-cascode OTA
 +
* [[220-A9.2]]: Folded-cascode small- and large-signal gain
 
|-
 
|-
| 10
+
| style="text-align:center;" | 10
| Feedback and Stability
+
|  
 +
[[Feedback and Stability]]
 +
* Loop Gain
 +
* Phase and Gain Margins
 +
* Compensation
 
|  
 
|  
 +
* Model and analyze the DC and small-signal characteristics of a folded-cascode OTA with feedback.
 +
* Verify the behavior of these characteristics via simulation.
 
|
 
|
 
|
 
|
 +
* [[220-A10.1]]: Folded-cascode OTA loop gain
 
|-
 
|-
| 11
+
| style="text-align:center;" | 11
| Amplifier Settling
 
 
|  
 
|  
 +
[[Amplifier Settling]]
 +
* Linear settling
 +
* Slewing
 +
|
 +
* Model and analyze the noise and settling characteristics of a folded-cascode OTA with feedback.
 +
* Verify the behavior of these characteristics via simulation.
 
|
 
|
 
|
 
|
 +
* [[220-A11.1]]: Folded-cascode OTA noise analysis
 +
* [[220-A11.2]]: Folded-cascode OTA linear and non-linear settling
 
|-
 
|-
| 12
+
| style="text-align:center;" | 12
| Common-Mode Feedback
 
 
|  
 
|  
 +
[[An Amplifier Design Example]]
 +
|
 +
* Design a fully-differential OTA with capacitive feedback.
 +
* Verify the OTA characteristics via simulation.
 
|
 
|
 
|
 
|
 +
* [[220-A12.1]]: Folded-cascode OTA design mini-project
 
|-
 
|-
| 13
+
| style="text-align:center;" | 13
| Multi-Stage Amplifiers
 
 
|  
 
|  
 +
[[EE 220 Project]]
 +
* Halfway Consultations
 +
|
 +
* Design a fully-differential OTA with capacitive feedback.
 +
* Verify the OTA characteristics via simulation.
 
|
 
|
 
|
 
|
 +
* [[220-A13.1]]: Design project specifications
 
|-
 
|-
| 14
+
| style="text-align:center;" | 14
| Biasing and Reference Circuits
+
|  
 +
[[EE 220 Project]]
 +
* Submissions
 
|  
 
|  
 +
* Design a fully-differential OTA with capacitive feedback.
 +
* Verify the OTA characteristics via simulation.
 
|
 
|
 
|
 
|

Latest revision as of 11:20, 11 October 2021

  • Analog Integrated Circuits
  • Semester Offered: 1st semester
  • Course Credit: Lecture: 4 units (3 units lecture, 1 unit lab)

Catalog Description

Integrated circuit devices and modeling. Noise analysis and modeling. Review of basic operational amplifier design and compensation. Advanced current mirrors and operational amplifiers. Operational transconductance amplifiers. Common-mode feedback circuits. Comparators. Sample and holds. Voltage references and translinear circuits. Discrete-time signals. Switched-capacitor circuits. Co-req: CoE 143 or equiv. 6h (3 lec, 3 lab) 4 u.

Syllabus

Module Topics Outcomes Resources Activities
1

CMOS Technology and Fabrication

  • Deep submicron issues
  • Process variations
  • Identify the key characteristics and non-idealities of a CMOS fabrication process.
  • Analyze how these key characteristics and non-idealities change the characteristics of the devices that will be built on it.
  • Perform simple circuit simulations using a ngspice.
2

Passive CMOS Devices

  • Resistors
  • Capacitors
  • Inductors
  • Identify, model, and analyze the effects of CMOS process parameters on the characteristics of integrated resistors, capacitors, and inductors.
  • Verify these effects via circuit simulation.
  • 220-A2.1: Integrated Resistors and Capacitors
3

MOS Transistors

  • Transistor Models
  • Short-Channel Effects
  • Identify, model, and analyze the effects of CMOS process parameters on the characteristics of MOS transistors.
  • Verify these effects via circuit simulation.
  • Arizona State University Predictive Technology Models (PTM) website
  • SkyWater SKY130 Models (130nm CMOS)
  • 220-A3.1: MOS characteristic curves simulation
  • 220-A3.2: Extracting MOS small-signal parameters
  • 220-A3.3: The MOS transition frequency
4

Model-Based Analog Circuit Design

  • Small-Signal Model
  • and
  • Design simple single-transistor amplifiers using SPICE models as an alternative to closed-form models.
  • Verify these designs via circuit simulation.
  • 220-A4.1: MOS Intrinsic Gain
  • 220-A4.2: Simulating
  • 220-A4.3: Design of a Simple Common-Source Amplifier
5

Electronic Noise

  • Identify the fundamental types of electronic noise and differentiate one noise type from another.
  • Model and analyze the effects and implications of electronic noise in semiconductor devices and circuits.
  • Model and analyze the effects and implications of electronic noise in feedback circuits.
  • Verify these effects via circuit simulation.
  • 220-A5.1: Device noise power-spectral density and total integrated device noise
  • 220-A5.2: Amplifier output noise and input-referred noise
6

Operational Transconductance Amplifiers (OTAs)

  • Op-Amps vs. OTAs
  • Switched-Capacitor Feedback
  • Differentiate between operational amplifiers (Op-Amps) and operational transconductance amplifiers (OTAs).
  • Analyze OTA circuits with capacitive feedback.
  • Verify the behavior of these circuits via simulation.
  • 220-A6.1: Transient response of an OTA with capacitive feedback
7

Differential Circuits

  • Differential-Mode
  • Common-Mode
  • CMRR, PSRR
  • Baluns
  • Differentiate and identify the advantages/disadvantages and cost-benefit trade-offs between fully-differential circuits vis-a-vis single-ended circuits.
  • Model and analyze the behavior of fully-differential circuits.
  • Verify the behavior of these circuits via simulation.
8

Current Mirrors

  • Cascoding
  • Common-Mode Feedback
  • Model, analyze, and design current mirror circuits for biasing fully-differential and single-ended OTAs.
  • Model, analyze, and design common-mode feedback (CMFB) circuits in differential OTAs.
  • Verify the behavior of these circuits via simulation.
  • 220-A8.1: Amplifier output swing
  • 220-A8.2: Gain-boosted current mirror frequency response
  • 220-A8.3: Basic common-mode feedback circuits
9

The Folded-Cascode OTA

  • DC Characteristics
  • Small-signal Characteristics
  • Noise
  • Identify the advantages and disadvantages of a folded-cascode OTA.
  • Model and analyze the DC and small-signal characteristics of a folded-cascode OTA.
  • Verify the behavior of these characteristics via simulation.
  • 220-A9.1: Biasing the folded-cascode OTA
  • 220-A9.2: Folded-cascode small- and large-signal gain
10

Feedback and Stability

  • Loop Gain
  • Phase and Gain Margins
  • Compensation
  • Model and analyze the DC and small-signal characteristics of a folded-cascode OTA with feedback.
  • Verify the behavior of these characteristics via simulation.
11

Amplifier Settling

  • Linear settling
  • Slewing
  • Model and analyze the noise and settling characteristics of a folded-cascode OTA with feedback.
  • Verify the behavior of these characteristics via simulation.
  • 220-A11.1: Folded-cascode OTA noise analysis
  • 220-A11.2: Folded-cascode OTA linear and non-linear settling
12

An Amplifier Design Example

  • Design a fully-differential OTA with capacitive feedback.
  • Verify the OTA characteristics via simulation.
  • 220-A12.1: Folded-cascode OTA design mini-project
13

EE 220 Project

  • Halfway Consultations
  • Design a fully-differential OTA with capacitive feedback.
  • Verify the OTA characteristics via simulation.
14

EE 220 Project

  • Submissions
  • Design a fully-differential OTA with capacitive feedback.
  • Verify the OTA characteristics via simulation.

References

  • Gray, Hurst, Lewis, Meyer, Analysis & Design of Analog Integrated Circuits, Wiley 2001.
  • Johns, Martin, Analog Integrated Circuit Design, Wiley 1997.
  • Design of Analog CMOS Integrated Circuits, Behzad Razavi, McGraw-Hill, 2000.
  • The Design of CMOS Radio-Frequency Integrated Circuits, Thomas H. Lee, 2nd Ed., Cambridge University Press, 2003.
  • The Designers Guide to SPICE & SPECTRE, K. S. Kundert, Kluwer Academic Press, 1995.
  • Operation and Modeling of the MOS Transistor, Y. Tsividis, McGraw-Hill, 2nd Edition, 1999.