| name | spectral-topology-preflight |
| description | Before dispatching a multi-agent team, run a spectral diagnostic on the proposed communication graph and emit a (ρ, Δ, κ) coordination signature plus a pass/fail verdict against per-task-class thresholds. Builds the row-stochastic operator P from the team graph, computes the successor representation M = (I − γP)⁻¹, and ranks the topology for robustness (κ, condition number), consensus (Δ, spectral gap), and drift (ρ, spectral radius). Per Parks & Alharthi (arxiv 2605.11453), rank order on (κ, Δ, ρ) predicts coordination quality pre-execution with rank correlations of 1.0 / 0.5 / −1.0. Triggers: "dispatch the team", "team topology check", "before running the agents", "is this team configuration OK", "team pre-flight".
|
| user-invocable | true |
| version | 1.0.1 |
| format | "2025-10-02T00:00:00.000Z" |
| triggers | ["team pre-flight","topology check","before dispatching the team","is this team configuration OK","coordination signature"] |
| updated | "2026-05-16T00:00:00.000Z" |
| status | ACTIVE |
| source | arxiv 2605.11453 (Parks & Alharthi), 2605.05657 (RGAO budget algebra) |
Spectral Topology Pre-flight
Why
Production multi-agent LLM systems fail at 41-87% rates from coordination defects, not from capability (Nechepurenko & Shuvalov, arxiv 2605.03310). Parks & Alharthi (arxiv 2605.11453) provide the first pre-inference diagnostic: spectral analysis of the team's communication operator predicts robustness (perfect rank correlation r_s = 1.0), consensus (r_s = 0.5), and drift (r_s = −1.0, inverted) before any agent runs. Cheap to compute, large effect on dispatch quality.
How
Given a proposed team graph (agents = nodes, communication paths = edges):
- Build P — the row-stochastic communication operator. Edge weights normalised so each row sums to 1.
- Compute M = (I − γP)⁻¹ — the successor representation. Use γ = 0.9 (standard).
- Extract three diagnostics:
- κ (condition number of M) — robustness signal. Lower = more robust.
- Δ (spectral gap of P) — consensus signal. Larger = faster consensus.
- ρ (spectral radius of P) — drift signal. Smaller = less drift (inverted from κ).
- Compare against per-task-class thresholds:
- For "deep-reason" tasks: prefer small κ, large Δ — robustness matters
- For "exploration" tasks: prefer larger ρ — drift is exploration, not failure
- For "consensus" tasks: prefer large Δ above all else
- Emit the signature —
coordination_signature: { rho, delta, kappa, verdict, recommendation? }. Verdict is pass / warn / fail. On fail, recommendation suggests a topology edit (drop/add edge, switch chain↔star↔mesh).
Platform-constraint check (added v1.0.1)
Before recommending a topology change, verify the runtime can actually instantiate it. Spawn-only runtimes (Claude Code subagents, some serverless dispatch pools) cannot implement ring, mesh, or critique-route between workers — those runtimes only support star (one parent dispatches to N children; children return-result without inter-peer messaging). In a spawn-only runtime, the spectral menu collapses: ring/mesh/critique-route can only be simulated by the parent brokering messages between rounds, not wired directly between workers.
If the dispatcher is spawn-only, the skill's recommendation must describe what the parent brokers between rounds, not what edges to wire between workers. Concretely, when recommending against a star topology in a spawn-only runtime:
- "Switch to mesh" → "Broker mesh through parent: dispatch round 1 as star fan-out, parent gathers, dispatches round 2 with peers' draft outputs in each child's brief."
- "Switch to ring" → "Broker ring through parent: dispatch sequentially with each child receiving the prior child's output. (Loses parallelism.)"
- "Switch to critique-route" → "Broker critique loop through parent: dispatch a critic agent per round whose verdict shapes the next dispatch."
When the runtime supports inter-agent messaging (MCP servers with peer routing, custom orchestration), the spectral recommendations apply directly. Always check the runtime before recommending.
Output schema
{
"topology": "chain|star|mesh|fully-connected|pipeline|leader-worker|hierarchical-fast-slow",
"agent_count": 4,
"coordination_signature": {
"rho": 0.87,
"delta": 0.42,
"kappa": 12.3
},
"task_class": "deep-reason",
"verdict": "warn",
"recommendation": "drop the leader-to-worker-4 edge; the redundancy is uncalled-for and inflates κ"
}
When to skip
- Single-agent dispatch (no graph to analyse).
- Team has already been pre-flighted in this session and topology hasn't changed.
- Team is fixed by external constraints and the pre-flight result can't be acted on.
Integration
- Output should be emitted into the generated
TEAM.md frontmatter as coordination_signature: … per arxiv 2605.11453 — so the team file carries its own diagnostic identity.
sc-dev-team, mayor-coordinator, sling-dispatch — invoke before launching the team.team-control, uc-lab — long-running missions should re-run pre-flight when topology evolves.
Cross-references
- Rosetta concept #8 (Constraint Drift) — pre-flight is the upstream check against coordination drift
- College:
agent-systems / multi-agent-orchestration / agent-spectral-topology
- Related skills:
mayor-coordinator (consumer of the verdict), sling-dispatch (consumer)
