Module
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Topics
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Outcomes
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External Resources
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Activities
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1
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CMOS Technology and Fabrication
- Deep submicron issues
- Process variations
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- 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.
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- 220-A1.1: IC Fabrication video reaction
- 220-A1.2: Simulating simple RLC circuits
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2
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Passive CMOS Devices
- Resistors
- Capacitors
- Inductors
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- 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.
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3
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MOS Transistors
- Analog vs. Digital
- Transistor Models
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- Identify, model, and analyze the effects of CMOS process parameters on the characteristics of MOS transistors.
- Verify these effects via circuit simulation.
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- Arizona State University Predictive Technology Models (PTM) website.
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- 220-A3.1: MOS characteristic curves simulation
- 220-A3.2: MOS Frequency response simulation
- 220-A3.3: Extracting MOS small-signal parameters
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4
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Model-Based Design
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- Design simple single-transistor amplifiers using SPICE models as a replacement for closed-form models.
- Verify these designs via circuit simulation.
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- 220-A4.1: Design a simple single-stage MOS amplifier
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5
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Electronic Noise
- Thermal Noise
- Shot Noise
- Flicker Noise
- Noise Analysis
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- 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.
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- 220-A5.1: Simulating the device noise power-spectral density and deriving the total integrated device noise
- 220-A5.2: Obtaining the amplifier output noise and input-referred noise and verifying these results via simulation
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6
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Operational Transconductance Amplifiers (OTAs)
- Op-Amps vs. OTAs
- Switched-Capacitor Feedback
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- 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.
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7
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Differential Circuits
- Differential-Mode
- Common-Mode
- CMRR, PSRR
- Baluns
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- 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.
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8
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Current Mirrors
- Cascoding
- Common-Mode Feedback
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- 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.
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9
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The Folded-Cascode OTA
- DC Characteristics
- Small-signal Characteristics
- Noise
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- 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.
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10
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Feedback and Stability
- Loop Gain
- Phase and Gain Margins
- Compensation
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- Model and analyze the DC and small-signal characteristics of a folded-cascode OTA with feedback.
- Verify the behavior of these characteristics via simulation.
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11
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Amplifier Settling
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- Model and analyze the noise and settling characteristics of a folded-cascode OTA with feedback.
- Verify the behavior of these characteristics via simulation.
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12
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An Amplifier Design Example
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- Design a fully-differential OTA with capacitive feedback.
- Verify the OTA characteristics via simulation.
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13
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EE 220 Project
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- Design a fully-differential OTA with capacitive feedback.
- Verify the OTA characteristics via simulation.
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14
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EE 220 Project
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- Design a fully-differential OTA with capacitive feedback.
- Verify the OTA characteristics via simulation.
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