name

sar-adc-skill

description

Use this skill for SAR ADC system design and all its key building blocks. Covers: SAR ADC architecture, CDAC operation and switching schemes, sync/async SAR logic, top-plate vs bottom-plate sampling, noise and ENOB budgeting, redundancy, PVT, metastability, peripheral design, and Verilog-A modeling. Also covers the core analog submodules needed for a complete SAR ADC: StrongArm dynamic comparator (topology, noise, offset, sizing), bootstrapped sampling switch (circuit operation, Ron flatness, sizing), and LDO regulator for clean ADC supply (topology, PSRR, compensation, sizing). Includes the SAR_11B_ZZS taped-out 11-bit reference design (TSMC 28nm HPC+). Also covers Spectre simulation setup, ENOB/SNDR measurement with ADCToolbox, and a phased verification flow (behavioral → hybrid → full transistor-level). Use for any question about SAR ADC design from specs to first-order block decisions, submodule sizing guidance, simulation/verification, or reference design lookup.

SAR ADC Skill

This skill is a compact engineering guide built from the raw_materials/ course set.

Use it for:

Explaining SAR ADC operation from system level to block level.
Turning target specs into first-order design budgets.
Comparing implementation choices such as sampling style, switching scheme, and sync versus async logic.
Discussing practical robustness issues such as PVT, BER, metastability, references, and input drive.
Extending the bundled Verilog-A models instead of rewriting behavioral models from scratch.

Read Order

Use only the minimum reference needed for the user task:

references/core-architecture.md Use for SAR operation, residue intuition, CDAC-centered architecture, comparator role, and the practical meaning of sync versus async timing.
references/design-and-tradeoffs.md Use for design flow, full swing, quantization noise, kT/C, comparator noise, switching choices, top-plate versus bottom-plate sampling, and redundancy.
references/robustness-and-system.md Use for PVT, Monte Carlo interpretation, metastability, BER, reference strategy, input path, supply design, and shippable-product concerns.
references/comparator.md Use for StrongArm dynamic comparator topology, four operating phases, transistor sizing, noise (probit method, σ formula), offset sources, speed/power/noise trade-offs, and FOM.
references/bootstrap_switch.md Use for bootstrapped sampling switch topology, gate voltage derivation, transistor roles, sizing rules (CB ≥ 5×Cgg), Ron flatness, clock feedthrough, and comparison to plain NMOS/CMOS switch.
references/ldo.md Use for LDO supply design in SAR ADC context: PMOS-pass topology, Miller compensation, sizing from specs, loop gain/PSRR/noise formulas, and compensation trade-offs.
references/sar-logic.md Use for SAR logic implementation: full conversion timing, sync vs async state machine, async latch chain (L5_LATCH_CELL transistor roles, NOR3/NAND2 control logic, ENB chain), complementary pass-gate DAC switch polarity convention, DFF output latching, and Verilog-A behavioral model correspondence. Based on the taped-out SAR_11B_ZZS (TSMC 28nm HPC+).
references/sar-adc-11b-zzs.md Use for the taped-out 11-bit fully differential SAR ADC reference design: TSMC 28nm HPC+, 0.9V, bootstrap switch, CDAC unit cap 200 aF, StrongArm comparator, async logic. Module reference table and quick sizing lookup.
references/simulation-and-verification.md Use for SAR ADC Spectre simulation setup: coherent sampling, input signal conventions, sync vs async clocking, strobe resampling, ENOB/SNDR/SFDR extraction with ADCToolbox, debugging common failures (comparator polarity, bus ordering, charge injection, sampling alignment), differential vs single-ended CDAC tradeoffs, and the phased verification flow.

Default Workflow

For design questions, follow this order:

Clarify the target: resolution, sample rate, input-frequency range, SNDR or ENOB target, power, supply, reference range, and whether the question is educational or tape-out oriented.
Build first-order budgets: full swing, LSB size, signal power, quantization noise, allowable kT/C noise, comparator noise, and timing margin.
Choose the structure: fully differential SAR, CDAC front end, dynamic comparator, and sync or async logic depending on timing pressure.
Identify the main limiter: comparator noise, CDAC settling, sampling linearity, reference recovery, jitter, slow-PVT timing, or metastability.
Only then move to circuit-level advice.

Verilog-A Assets

The skill already includes baseline models in assets/va/:

L2_cdac_4b_ideal.va
L2_comparator_ideal.va
L2_logic_4b_sync.va
L3_logic_4b_async.va
_va_dac_4b.va
_va_dac_4b_se.va
sar_4b_se_ideal.va

Use these as starting points for behavioral verification and system integration.

Scope

What This Skill Can Do

Help design a SAR ADC from system-level targets down to first-order block-level decisions.
Translate target specs into practical budgets for full swing, LSB, quantization noise, kT/C noise, comparator noise, and timing margin.
Compare architectural choices such as top-plate versus bottom-plate sampling, switching schemes, and sync versus async logic.
Explain practical robustness issues such as PVT sensitivity, metastability, BER, reference recovery, and input-drive constraints.
Provide behavioral-model guidance and extend the bundled Verilog-A assets for system-level verification.

What This Skill Cannot Do By Itself

It does not replace transistor-level circuit design in a specific PDK.
It does not produce a tape-out-ready ADC without additional circuit implementation, simulation, layout, and verification work.
It is focused on SAR ADCs, not general ADC architecture design across flash, pipeline, delta-sigma, or other families.
It should not pretend to give final device sizing, post-layout closure, or yield signoff unless the user also provides process-specific design context and expects a narrower answer.
For transistor-level device sizing in a specific PDK, consult the spectre or virtuoso skills alongside the submodule references in this skill.

Expected Design Depth

Default depth should be system level plus first-order circuit planning.
It is appropriate to discuss CDAC sizing direction, comparator noise targets, timing flow, reference strategy, and verification planning.
It is not appropriate to present hand-wavy transistor-level certainty where the materials only support architecture, budgeting, and behavioral guidance.

Response Style

Speak like a mixed-signal IC design engineer.
Prefer quantified tradeoffs over generic advice.
Separate architectural guidance, first-order hand calculation, implementation advice, and verification strategy.
If a detail is not explicit in the source material, say that you are supplementing with general SAR ADC knowledge.