build-sequential-circuit

pjt222

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À propos

Cette compétence permet aux développeurs de concevoir des circuits numériques à mémoire vive tels que des registres, des compteurs et des machines à états finis en utilisant des éléments de mémoire fondamentaux. Elle couvre la mise en œuvre des verrous, des bascules, ainsi que la conception de machines de Mealy/Moore, incluant l'analyse du signal d'horloge et de la temporisation. Utilisez-la lorsque votre circuit doit mémoriser des entrées passées, compter des événements ou exécuter une séquence de contrôle dépendante de l'état.

Installation rapide

Claude Code

Recommandé

Principal

npx skills add pjt222/agent-almanac -a claude-code

Commande PluginAlternatif

/plugin add https://github.com/pjt222/agent-almanac

Git CloneAlternatif

git clone https://github.com/pjt222/agent-almanac.git ~/.claude/skills/build-sequential-circuit

Copiez et collez cette commande dans Claude Code pour installer cette compétence

Documentation

Build Sequential Circuit

Sequential logic circuit design → ID memory + state type, construct state diagram + transition table, derive excitation equations for flip-flop type, impl at gate level w/ flip-flops + combinational logic, verify via timing diagram + state sequence sim.

Use When

Circuit must remember past in or maintain internal state across clock cycles
Designing counters (binary, BCD, ring, Johnson), shift registers, sequence detectors
Impl FSM (Mealy or Moore) from state diagram or regex
Add clocked storage to combinational datapath (registers, pipeline stages)
Prep stateful components for simulate-cpu-architecture (register file, PC, control FSM)

In

Required: Behavioral spec — state diagram, state table, timing diagram, regex to detect, or verbal desc of desired behavior
Required: Clock characteristics — edge-triggered (rise/fall) or level-sensitive; single or multi-phase
Optional: Flip-flop type pref (D, JK, T, SR)
Optional: Reset type — sync, async, none
Optional: Max state count or bit width constraint
Optional: Timing constraints (setup time, hold time, max clock freq)

Do

Step 1: ID Memory + State Reqs

What circuit remembers + how many states:

State enumeration: List all distinct states. Sequence detector: each state = progress through target. Counter: each state = count val.
State encoding: Binary encoding for states.
- Binary: ceil(log2(N)) flip-flops for N states. Min flip-flop count
- One-hot: N flip-flops, one per state. Simpler next-state logic at cost of more flip-flops
- Gray code: Adjacent states differ in 1 bit. Min transient glitches
In/out classification: ID primary ins (external), primary outs, internal state vars (flip-flop outs). Mealy: outs depend on state + in. Moore: outs depend only on state.
Flip-flop type selection:
- D: Simplest — next state = D in. Best default
- JK: Most flexible — J=K=1 toggles. Good for counters
- T: Toggle type — changes state when T=1. Natural for binary counters
- SR: Set-Reset — avoid S=R=1. Rarely preferred for new designs

## State Requirements
- **Number of states**: [N]
- **State encoding**: [binary / one-hot / Gray]
- **Flip-flops needed**: [count and type]
- **Machine type**: [Mealy / Moore]
- **Inputs**: [list with descriptions]
- **Outputs**: [list with descriptions]
- **Reset behavior**: [synchronous / asynchronous / none]

→ Complete state inventory w/ encoding, flip-flop type, machine classified as Mealy or Moore.

If err: State count unclear → enumerate by tracing all possible in sequences up to memory depth. Exceeds practical (>16 states manual) → decompose into smaller interacting FSMs.

Step 2: State Diagram + Transition Table

Formalize behavior:

State diagram: Directed graph:
- Each node = state, labeled w/ name + (Moore) out val
- Each edge = transition, labeled w/ in condition + (Mealy) out val
- Every state must have outgoing edge for every in combination — no implicit "stay"
Transition table: Convert diagram to table w/ cols: present state, in(s), next state, out(s).
Reachability check: From initial/reset, verify all states reachable via some in sequence. Unreachable = design err or treat as don't-cares.
State minimization (optional): Check equivalent states — same out for every in + transition to equivalent next. Merge equivalent → reduce flip-flop count.

## State Transition Table
| Present State | Input | Next State | Output |
|--------------|-------|------------|--------|
| S0           | 0     | S0         | 0      |
| S0           | 1     | S1         | 0      |
| S1           | 0     | S0         | 0      |
| S1           | 1     | S2         | 0      |
| ...          | ...   | ...        | ...    |

- **Unreachable states**: [list, or "none"]
- **Equivalent state pairs**: [list, or "none"]

→ Complete transition table covering every present-state/in combo, all states reachable from initial.

If err: Missing entries → spec incomplete. Return to reqs, resolve ambiguity. Unreachable states → add transitions to reach or remove + reduce encoding.

Step 3: Derive Excitation Equations

Flip-flop in equations from transition table:

Encode states: Replace names w/ binary encoding. Each bit pos = one flip-flop.
Per-flip-flop truth table: Each flip-flop → truth table w/ present-state bits + ins as in cols, required flip-flop in as out col.
- D: D = next state bit (simplest)
- JK: Use excitation table: 0→0 J=0,K=X; 0→1 J=1,K=X; 1→0 J=X,K=1; 1→1 J=X,K=0
- T: T = present XOR next (T=1 when bit changes)
Minimize each eq: Use evaluate-boolean-expression (K-map or algebraic simplify) on each flip-flop in fn. Don't-cares from unreachable states + JK X-entries reduce significantly.
Derive out eqs: Moore: each out = fn of present state bits only. Mealy: each out = fn of present state bits + ins.

## Excitation Equations
- **Flip-flop type**: [D / JK / T]
- **State encoding**: [binary assignment table]

| Flip-Flop | Excitation Equation          |
|-----------|------------------------------|
| Q1        | D1 = [minimized expression]  |
| Q0        | D0 = [minimized expression]  |

## Output Equations
| Output | Equation                     |
|--------|------------------------------|
| Y      | [minimized expression]       |

→ Minimized excitation eqs per flip-flop + out eqs per primary out, all don't-cares exploited.

If err: Eqs overly complex → reconsider encoding. Diff encoding (binary → one-hot, or reassigning codes) can dramatically simplify. Try ≥2 encodings, compare literal counts.

Step 4: Impl at Gate Level

Build circuit from flip-flops + combinational gates:

Place flip-flops: One per state bit. Connect all clock ins to system clock. Connect reset ins if spec'd (async reset → directly to CLR/PRE pin; sync reset part of excitation logic).
Build excitation logic: Impl each eq as combinational circuit via design-logic-circuit. Ins = present-state flip-flop outs (Q, Q') + primary ins.
Build out logic: Impl each out eq as combinational. Moore: only state bits. Mealy: state bits + primary ins.
Connect: Wire excitation outs → flip-flop D/JK/T ins. Wire out logic → primary outs.
Init: Circuit reaches known initial state on power-up. Typically async reset forcing all flip-flops to 0 (or encoded initial).

## Circuit Implementation
- **Flip-flops**: [count] x [type], [edge type]-triggered
- **Combinational gates for excitation**: [count and types]
- **Combinational gates for output**: [count and types]
- **Total gate count**: [flip-flops + combinational gates]
- **Reset mechanism**: [asynchronous CLR / synchronous mux / none]

→ Complete gate-level netlist w/ flip-flops, excitation logic, out logic, clock distribution, reset. Every signal has exactly 1 driver.

If err: Feedback outside flip-flops → combinational loop introduced. All feedback in sync circuit must pass through flip-flop. Trace offending path, reroute through register.

Step 5: Verify via Timing + State Sim

Confirm circuit correct across clock cycles:

Test sequence: In sequence exercising every transition ≥1. Sequence detectors: target, partial matches, overlapping, non-matching.
Timing diagram: Each cycle record:
- Clock edge (rise/fall)
- Primary in values (sampled at active edge)
- Present state (flip-flop outs before edge)
- Next state (flip-flop outs after edge)
- Out values (valid after out logic settles)
Trace state sequence: Verify matches state diagram Step 2. Every transition follows edge in diagram.
Timing constraints:
- Setup time: Ins stable ≥ t_setup before active edge
- Hold time: Ins stable ≥ t_hold after active edge
- Clock-to-out delay: Outs settle w/in clock period minus setup of downstream
Reset verify: Reset drives circuit to initial regardless of current.

## Timing Verification
| Cycle | Clock | Input | Present State | Next State | Output |
|-------|-------|-------|---------------|------------|--------|
| 0     | rst   | -     | -             | S0         | 0      |
| 1     | rise  | 1     | S0            | S1         | 0      |
| 2     | rise  | 1     | S1            | S2         | 0      |
| ...   | ...   | ...   | ...           | ...        | ...    |

- **All transitions match state diagram**: [Yes / No]
- **Setup/hold violations**: [None / list]
- **Reset verified**: [Yes / No]

→ Every cycle matches transition table, outs correct every cycle, no timing violations.

If err: Transition wrong → trace excitation logic for that present-state + in combo. Outs wrong but transitions correct → err in out logic. Circuit enters unintended state → check incomplete reset or missing transitions from unused codes.

Check

Traps

Incomplete transitions: Forget to spec what happens for every in in every state → circuit enters undefined/unintended. Always define behavior for all in combos
Unused state codes: N flip-flops → 2^N codes but maybe fewer valid states. Noise/power-on → unused code → lock up. Add transitions from unused → reset or prove unreachable
Mealy vs Moore confusion: Mealy: outs change immediately when ins change (combinational path in→out). Moore: outs change only on clock edges. Mixing → timing hazards
Async ins to sync circuit: External signals not sync'd to clock → violate setup/hold → metastability. Always pass async ins through 2-flip-flop synchronizer
SR S=R=1 hazard: Both Set + Reset high simultaneously → SR latch undefined. Using SR → add logic to guarantee combo never occurs, or switch to D/JK
Clock skew multi-flip-flop: Clock arrives at diff flip-flops at diff times → sample stale data. Intro designs: assume 0 skew; real HW: use clock tree synthesis

→

design-logic-circuit — design combinational excitation + out logic blocks
simulate-cpu-architecture — use sequential blocks (registers, counters, control FSMs) in CPU datapath
model-markov-chain — FSMs share formal framework of discrete-time Markov chains

Dépôt GitHub

pjt222/agent-almanac

Chemin: i18n/caveman-ultra/skills/build-sequential-circuit

agentsagentskillsai-assisted-developmentclaude-codeskillsteams

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