simulate-stochastic-process

pjt222

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À propos

Cette compétence simule des processus stochastiques tels que les chaînes de Markov, les EDS et les échantillonneurs MCMC, fournissant des trajectoires d'échantillonnage pour l'estimation et la prédiction. Elle inclut des fonctionnalités clés comme des diagnostics de convergence, la réduction de variance et des outils de visualisation. Utilisez-la lorsque les solutions analytiques sont inaccessibles, que vous avez besoin de méthodes de Monte Carlo avec garanties de convergence, ou que vous devez échantillonner des distributions a posteriori complexes.

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/simulate-stochastic-process

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

Documentation

Simulate Stochastic Process

Sample paths from stochastic processes — discrete Markov, continuous-time, SDEs, MCMC samplers — w/ convergence diagnostics, variance reduction, trajectory viz.

Use When

Generate sample paths for est/predict/viz
Analytical intractable, sim only feasible
MC est needing convergence guarantees + uncertainty quant
Validate analytical (stationary, hitting times) vs empirical
Sample complex posterior via MCMC
Prototype stochastic model before full analytical

In

Required

Input	Type	Description
`process_type`	string	`"dtmc"`, `"ctmc"`, `"random_walk"`, `"brownian_motion"`, `"sde"`, `"mcmc"`
`parameters`	dict	Process-specific (transition matrix, drift/diffusion, target density)
`n_paths`	integer	Independent paths to sim
`n_steps`	integer	Time steps per path (or total MCMC iters)

Optional

Input	Type	Default	Description
`initial_state`	scalar/vector	process-specific	Start state
`dt`	float	0.01	Time step → continuous discretization
`seed`	integer	random	Reproducibility
`burn_in`	integer	`n_steps / 10`	Initial discard (MCMC)
`thinning`	integer	1	Keep every k-th → reduce autocorr
`variance_reduction`	string	`"none"`	`"none"`, `"antithetic"`, `"stratified"`, `"control_variate"`
`target_function`	callable	none	Eval along paths → MC est

Do

Step 1: Define Process + Params

1.1. ID process type + gather params:

DTMC: Transition matrix P + state space. Validate row-stochastic.
CTMC: Rate matrix Q. Rows sum 0, off-diag non-neg.
Random walk: Step distrib (e.g. {-1, +1} equal prob), boundaries.
Brownian: Drift mu, vol sigma, dim d.
SDE (Ito): Drift a(x,t), diffusion b(x,t).
MCMC: Target log-density, proposal (RW Metropolis, HMC, Gibbs).

1.2. Validate consistency:

Matrix dims match state space size
SDE coefs satisfy growth + Lipschitz (informal min) for solver
MCMC proposal well-defined for target support

1.3. Set seed → reproducibility.

Got: Fully spec'd model w/ validated params + reproducible RNG state.

If err: Inconsistent params (e.g. non-stochastic matrix) → correct first. Pathological SDE coefs → diff discretization scheme.

Step 2: Select Sim Method

2.1. Choose algo per type:

Process	Method	Key Property
DTMC	Direct sampling from transition row	Exact
CTMC	Gillespie algorithm (SSA)	Exact, event-driven
CTMC (approx.)	Tau-leaping	Approximate, faster for high rates
Random walk	Direct sampling of increments	Exact
Brownian motion	Cumulative sum of Gaussian increments	Exact for fixed `dt`
SDE (general)	Euler-Maruyama	Order 0.5 strong, order 1.0 weak
SDE (higher order)	Milstein	Order 1.0 strong (scalar noise)
SDE (stiff)	Implicit Euler-Maruyama	Stable for stiff drift
MCMC (general)	Metropolis-Hastings	Asymptotically exact
MCMC (gradient)	Hamiltonian Monte Carlo (HMC)	Better mixing for high dimensions
MCMC (conditional)	Gibbs sampler	Exact conditionals when available

2.2. SDE → dt small enough for stability. Heuristic: start dt = 0.01, halve until results stabilize.

2.3. MCMC → tune proposal scale → acceptance ~:

23.4% → high-dim RW Metropolis
57.4% → 1D targets
65-90% → HMC (depends on trajectory length)

2.4. Variance reduction config:

Antithetic: Each path w/ Z → also sim w/ -Z
Stratified: Partition prob space, sample within strata
Control variates: Correlated quantity w/ known E → reduces var

Got: Algo matched to type w/ tuning params.

If err: Unstable (Euler-Maruyama diverging) → implicit method | reduce dt.

Step 3: Implement + Run

3.1. Allocate storage n_paths × n_steps (or dynamic for event-driven Gillespie).

3.2. Per path i = 1, ..., n_paths:

DTMC / Random Walk:

x[0] = initial_state
For t = 1..n_steps: sample x[t] from transition given x[t-1]

CTMC (Gillespie):

x[0] = initial_state, time = 0
While time < T_max:
- Total rate lambda = -Q[x, x]
- Holding time tau ~ Exp(lambda)
- Next state from probs Q[x, j] / lambda for j != x
- time += tau, record

SDE (Euler-Maruyama):

x[0] = initial_state
For t = 1..n_steps:
- dW = sqrt(dt) * N(0, I) (Wiener)
- x[t] = x[t-1] + a(x[t-1], t*dt) * dt + b(x[t-1], t*dt) * dW

MCMC (Metropolis-Hastings):

x[0] = initial_state
For t = 1..n_steps:
- Propose x' ~ q(x' | x[t-1])
- alpha = min(1, p(x') * q(x[t-1]|x') / (p(x[t-1]) * q(x'|x[t-1])))
- Accept w/ prob alpha: x[t] = x' if accepted, else x[t-1]
- Record decision

3.3. target_function provided → eval at each state, store.

3.4. Apply thinning: keep every thinning-th.

3.5. Discard burn_in from start (MCMC).

Got: n_paths complete trajectories in mem, optional fn evals. MCMC acceptance in target range.

If err: NaN/Inf → reduce dt (SDE) | check params. MCMC accept ~0% | ~100% → adjust proposal scale.

Step 4: Convergence Diagnostics

4.1. Trace plots: per-component over time, subset paths. Visual check stationarity (no trends, stable var).

4.2. Gelman-Rubin (R-hat) for multi-chain MCMC:

Within-chain W, between-chain B
R_hat = sqrt((n-1)/n + B/(n*W))
R_hat < 1.01 (strict) | < 1.1 (lenient) → convergence

4.3. Effective sample size (ESS):

Estimate autocorr at increasing lags
ESS = n_samples / (1 + 2 * sum(autocorr))
Rule: ESS > 400 for reliable posterior summaries

4.4. Geweke: cmp mean first 10% vs last 50%. Z-score in [-2, 2] → convergence.

4.5. Non-MCMC: time-avg stats (mean, var) stabilize as path length ↑. Plot running averages.

4.6. Summary table:

Diagnostic	Value	Threshold	Status
R-hat (max)	...	< 1.01	...
ESS (min)	...	> 400	...
Geweke z (max abs)	...	< 2.0	...
Acceptance rate	...	0.15-0.50	...

Got: All diagnostics pass thresholds. Trace shows stable, well-mixing chains.

If err: R-hat > 1.1 → run longer | improve proposal. ESS very low → ↑ thinning | better sampler (HMC). Geweke fails → extend burn-in.

Step 5: Summary Stats + CIs

5.1. Per quantity (state occupancy, fn E, hitting times):

Point est = sample mean across paths (post burn-in + thin)
SE via ESS: SE = SD / sqrt(ESS)

5.2. Build CIs:

Normal approx: est +/- z_{alpha/2} * SE
Skewed → percentile bootstrap | batch means

5.3. Variance reduction → VRF:

VRF = Var(naive) / Var(reduced)
Report effective speedup

5.4. MC integration: report est, SE, 95% CI, ESS, # fn evals.

5.5. Distribution est:

Empirical quantiles (median, 2.5th, 97.5th)
KDE for continuous

5.6. Tabulate all w/ uncertainties.

Got: Point ests + SEs + CIs. Variance reduction (if applied) → VRF > 1.

If err: CIs too wide → ↑ n_paths | n_steps. Var reduction worsens (VRF < 1) → disable; control variate | antithetic mismatched.

Step 6: Visualize

6.1. Trajectory plots: 5-20 paths over time. Use transparency for overlap.

6.2. Ensemble stats: overlay mean + pointwise 95% CI bands across paths.

6.3. Marginal distributions: at selected times, hist | density estimates of state across paths.

6.4. Stationary cmp: analytical avail → overlay on empirical hist (final time slice).

6.5. Autocorr plots (MCMC): ACF per component, reasonable lag.

6.6. Diagnostic dashboard: trace + ACF + running mean + marginal density → multi-panel.

6.7. Save figures vector (PDF/SVG) + raster (PNG) → docs.

Got: Pub-quality figures showing trajectory, distributional convergence, diagnostics. Analytical (where avail) matches empirical.

If err: Viz reveals non-stationarity | unexpected multimodality → revisit Steps 1-2 (param/method err). Cluttered plots → reduce paths shown | bigger figure.

Check

All trajectories in valid state space (no out-of-bounds, no NaN/Inf)
DTMC/CTMC: empirical stationary → analytical (within MC err)
SDE: halving dt doesn't qualitatively change → convergence order
MCMC: R-hat < 1.01, ESS > 400, Geweke z in [-2, 2]
CI widths shrink ∝ 1/sqrt(n_paths) (CLT)
Variance reduction → VRF > 1 (improves not worsens)
Reproducibility: same seed → identical results

Traps

Insufficient burn-in (MCMC): Poor initial state → long burn-in before samples represent target. Inspect trace + diagnostics, don't guess.
Euler-Maruyama instability (stiff SDE): Large drift gradients → explicit can diverge. Implicit | adaptive step.
Strong vs weak convergence (SDE): Strong = pathwise err (individual trajectories); weak = distributional (expectations). Euler-Maruyama: weak 1.0, strong 0.5.
PRNG quality: Long sims → low-quality RNGs → correlated samples. Mersenne Twister | PCG | Xoshiro. Verify independence.
Ignore autocorr (MCMC): Treating autocorr samples as independent underestimates uncertainty. Use ESS, not raw count.
Antithetic for non-monotone fns: Reduces var only for monotone fn of underlying uniforms. Non-monotone → can ↑ var.
Mem for large sims: All time steps of many long paths → mem exhaust. Online stats (running mean, var) when full trajectories not needed for viz.

→

Model Markov Chain — transition matrices + analytical sims validate
Fit Hidden Markov Model — sim from fitted HMMs → posterior predictive checking + synthetic data

Dépôt GitHub

pjt222/agent-almanac

Chemin: i18n/caveman-ultra/skills/simulate-stochastic-process

agentsagentskillsai-assisted-developmentclaude-codeskillsteams

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