| name | ieee-experiments |
| description | Design and audit IEEE communications simulation and numerical-results sections for JSAC, TWC, TCOM, WCL, and CL. Covers benchmark schemes, Monte-Carlo protocol, BER/SER/outage/rate/EE metrics, SNR/antenna/user sweeps, analysis-vs-simulation validation, convergence and complexity, learning-based evaluation, ISAC rate-CRB/detection tradeoffs, robustness, and empirical/ray-tracing/testbed evidence. Use for planning or checking results: benchmark selection, simulation setup, Monte-Carlo validation, neural-network evaluation, CRB/ISAC tradeoffs, fairness boundaries, or reviewer-risk audits. |
IEEE Communications — Simulation and Numerical Results
Use this skill to make the evidence earn the claims in a PHY/network communications paper. Every
contribution in the Introduction must have a result that could falsify it; for analytical papers,
every derived expression must be validated by Monte-Carlo simulation; every figure answers one
question.
Core stance
- Results test claims, not showcase wins. Map each contribution to the curve/table that
supports it before running anything.
- Validate analysis with simulation. If the paper derives a closed-form expression (outage,
BER, rate, coverage), Monte-Carlo markers must sit on the analytical curve — that agreement is
the proof the derivation is correct. Note asymptotic slope (diversity order) where claimed.
- Fairness is declared, not assumed. State the comparison's boundary: same power budget, same
CSI assumption, same bandwidth/antennas, same channel realizations across schemes.
- No fabrication. Do not invent curves, gains, benchmark numbers, or "matching" between theory
and simulation. Use
[PLACEHOLDER] for results not yet run and list what the user must produce.
When to open extra files
| File | Open when |
|---|
| references/experiment-design.md | Choosing the system/channel setup, benchmark schemes, communications metrics, Monte-Carlo protocol, convergence/complexity, learning-based evaluation (NMSE/generalization/inference cost), ISAC dual metrics (CRB/detection + rate–CRB tradeoff), and robustness (imperfect CSI/hardware) tests |
| references/tables-and-claims.md | Structuring result tables, mapping each table/figure to a claim, table/prose division of labour, and IEEE table conventions |
The evidence ladder (design in this order)
1. Validation do Monte-Carlo markers match the analysis (curves), and is the
asymptotic slope (diversity order / DoF) as claimed? [analytical papers]
2. Performance does the scheme beat conventional and prior-art schemes on the key
metric (sum rate, BER, outage, EE, ...)?
3. Operating regimes behaviour swept across SNR, #antennas, #users, power, blocklength, K-factor
4. Design analysis is each design choice necessary (compare reduced "w/o" variants)?
5. Convergence & cost does the iterative algorithm converge; complexity order vs benchmarks
6. Robustness graceful degradation under imperfect CSI, hardware impairments, mismatch
Not every paper needs all six. An optimization paper centres on rungs 2–5; an analytical paper
must clear rung 1 first. A method paper that stops at rung 2 is usually under-evaluated; a letter
(WCL/CL) may show only rungs 1–3 for space — see the ieee-letter skill.
Workflow
- List the contributions (from the Introduction). For each, write the single result that
would convince a skeptic and the one that could falsify it.
- Choose benchmark schemes across categories (see experiment-design.md): proposed,
conventional/heuristic, prior-art (same setting), an upper bound (relaxed/genie/perfect-CSI),
and a lower bound (random/equal-power/no-optimization). Label each category. For a learning-based
paper, always include the model-based method it replaces (LS/MMSE/WMMSE) and, for deep
unfolding, the parent iterative algorithm at full and at matched
L iterations.
- Choose metrics that match the claim — not just the headline. Add a tail/distributional
metric (outage, CDF, worst-user rate) for stability claims, and a cost metric (complexity
order, runtime, energy efficiency) for efficiency claims.
- Plan parameter sweeps: which quantity on the x-axis (usually SNR/transmit power), what is
swept as curve families (#antennas, #users, K-factor), and the regime that exposes the claim.
- Set the Monte-Carlo protocol: number of independent channel realizations, what is averaged,
confidence/smoothness, and the same channel seeds across all schemes for paired comparison.
- Plan analysis-vs-simulation validation (analytical papers): which expressions get a
simulation overlay, and the asymptotic check.
- Plan convergence/complexity for any iterative algorithm (SCA/ADMM/AO/fractional
programming): objective-vs-iteration curve plus per-iteration complexity order.
- Declare the fairness boundary in words (see below).
- Map every planned figure/table to one claim; drop anything that answers no question.
- Return the design as a claim→result→metric→figure matrix, plus a gap list.
Declare the fairness boundary
When no standard public benchmark exactly matches the setting:
Since no existing scheme fully matches the considered setup, representative implementable schemes
are adopted under the same power budget, CSI assumption, and bandwidth.
Then classify each scheme (proposed / conventional / prior-art / upper bound / lower bound) and
state the shared resource constraint. This single move pre-empts the most common reviewer
objection ("the comparison is unfair").
Output format
Claim–result matrix: Contribution → Result (curve/table) → Metric(s) → Fig/Table → Status.
Benchmark schemes: grouped by category, each labelled with its role and shared constraint.
Simulation setup: channel/system model, swept parameters, Monte-Carlo realizations.
Validation plan: which expressions get a simulation overlay; asymptotic-slope check.
Convergence/complexity: iteration behaviour + complexity order vs benchmarks.
Gaps: curves or numbers the user still needs to produce.