danesabo/PWR-HYBRID-3
1
0
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity
PWR-HYBRID-3/code/scripts/reach_heatup_pj.jl
Dane Sabo 645f2d8d27 prompt-jump model + app v2 + overnight journal entry (in progress) 
Singular-perturbation reduction of the PKE+T/H system: set dn/dt=0,
solve algebraically n = Λ·Σλ_i·C_i / (β-ρ). State drops 10 -> 9 (no
n), removes Λ⁻¹ stiffness. Validated against full state on the heatup
scenario:

  t [s]    |Δn|/n_full   T_c err [K]
  60       3.7e-5        4e-6
  300      3.8e-4        1.9e-4
  1200     1.0e-3        2.2e-3
  3000     5.0e-4        7.2e-3

Maximum relative error 0.1% on n, peak 7 mK on temperatures over
50 minutes.  PJ approximation is excellent for slow heatup transients
(sub-prompt-critical regime).

Files:
  - code/src/pke_th_rhs_pj.jl: reduced 9-state RHS
  - code/scripts/validate_pj.jl: side-by-side sim
  - code/scripts/reach_heatup_pj.jl: TMJets reach with PJ model
    (probing T = 60, 300, 1800, 5400 s)

App v2 (Pluto):
  - §9b: live ingestion of reach_operation_result.mat with per-
    halfspace margins computed from JSON-defined inv2_holds.
  - §9c: 2D projection chooser (n, T_f, T_c, T_cold) with reach
    tube envelope overlay.
  - §9d: PJ heatup reach summary (placeholder until first run lands).

Journal:
  - Added 2026-04-20-overnight-prompt-jump.tex with PJ derivation,
    validation table, soundness ledger update.  apass markers for
    the in-progress reach results.

This commit captures state mid-run; next commit will add the
populated reach results once TMJets returns.

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
2026-04-20 22:45:24 -04:00

219 lines
8.6 KiB
Julia
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

#!/usr/bin/env julia
#
# reach_heatup_pj.jl — nonlinear reach on heatup, prompt-jump model.
#
# Reduced from 10-state to 9-state (n is algebraic). Removes the
# Λ⁻¹ stiffness that capped the full-state reach at ~10 s. We push
# horizons up: 60 s, 300 s, 1800 s, 5400 s, full T_max = 18000 s (5 hr).
#
# State (10D with augmented time):
# x[1..6] = C_1..C_6 (delayed-neutron precursors)
# x[7] = T_f
# x[8] = T_c
# x[9] = T_cold
# x[10] = t (augmented time, dt/dt = 1)
#
# n is algebraic: n = Λ · Σ λ_i C_i / (β - ρ), ρ = K_p · (T_ref - T_c).
using Pkg
Pkg.activate(joinpath(@__DIR__, ".."))
using LinearAlgebra
using ReachabilityAnalysis, LazySets
using JSON
using MAT
# --- Inlined plant constants (must match pke_params) ---
const LAMBDA = 1e-4
const BETA_1, BETA_2, BETA_3, BETA_4, BETA_5, BETA_6 =
0.000215, 0.001424, 0.001274, 0.002568, 0.000748, 0.000273
const BETA = BETA_1 + BETA_2 + BETA_3 + BETA_4 + BETA_5 + BETA_6
const LAM_1, LAM_2, LAM_3, LAM_4, LAM_5, LAM_6 =
0.0124, 0.0305, 0.111, 0.301, 1.14, 3.01
const P0 = 1e9
const M_F, C_F, M_C, C_C, HA, W_M, M_SG =
50000.0, 300.0, 20000.0, 5450.0, 5e7, 5000.0, 30000.0
# Note: feedback-linearization in ctrl_heatup_unsat cancels the alpha
# terms exactly, so under closed-loop the effective rho is just Kp·e.
# We don't need ALPHA_F, ALPHA_C in the reach RHS as a result.
const T_COLD0 = 290.0
const DT_CORE = P0 / (W_M * C_C)
const T_HOT0 = T_COLD0 + DT_CORE
const T_C0 = (T_HOT0 + T_COLD0) / 2
const T_F0 = T_C0 + P0 / HA
const T_STANDBY = T_C0 - 33.333333
const RAMP_RATE_CS = 28.0 / 3600
const KP_HEATUP = 1e-4
# --- Taylorized PJ heatup RHS, 10D with augmented time ---
@taylorize function rhs_heatup_pj_taylor!(dx, x, p, t)
# rho_total under closed-loop feedback linearization = Kp · (T_ref - T_c).
rho = KP_HEATUP * (T_STANDBY + RAMP_RATE_CS * x[10] - x[8])
# Algebraic prompt-jump n.
sum_lam_C = LAM_1*x[1] + LAM_2*x[2] + LAM_3*x[3] +
LAM_4*x[4] + LAM_5*x[5] + LAM_6*x[6]
denom = BETA - rho
n = LAMBDA * sum_lam_C / denom
inv_factor = sum_lam_C / denom
# Precursor balance under PJ.
dx[1] = BETA_1 * inv_factor - LAM_1 * x[1]
dx[2] = BETA_2 * inv_factor - LAM_2 * x[2]
dx[3] = BETA_3 * inv_factor - LAM_3 * x[3]
dx[4] = BETA_4 * inv_factor - LAM_4 * x[4]
dx[5] = BETA_5 * inv_factor - LAM_5 * x[5]
dx[6] = BETA_6 * inv_factor - LAM_6 * x[6]
# Thermal — n appears algebraically in fuel eq.
dx[7] = (P0 * n - HA * (x[7] - x[8])) / (M_F * C_F)
dx[8] = (HA * (x[7] - x[8]) - 2 * W_M * C_C * (x[8] - x[9])) / (M_C * C_C)
dx[9] = (2 * W_M * C_C * (x[8] - x[9])) / (M_SG * C_C)
# Augmented time.
dx[10] = one(x[1])
return nothing
end
# --- Build X_entry (PJ form: no n) from predicates.json ---
pred_path = joinpath(@__DIR__, "..", "..", "reachability", "predicates.json")
pred_raw = JSON.parsefile(pred_path)
entry = pred_raw["mode_boundaries"]["q_heatup"]["X_entry_polytope"]
n_lo, n_hi = entry["n_range"]
T_f_lo, T_f_hi = entry["T_f_range_C"]
T_c_lo, T_c_hi = entry["T_c_range_C"]
T_cold_lo, T_cold_hi = entry["T_cold_range_C"]
n_mid = 0.5 * (n_lo + n_hi)
C_mid_1 = (BETA_1 / (LAM_1 * LAMBDA)) * n_mid
C_mid_2 = (BETA_2 / (LAM_2 * LAMBDA)) * n_mid
C_mid_3 = (BETA_3 / (LAM_3 * LAMBDA)) * n_mid
C_mid_4 = (BETA_4 / (LAM_4 * LAMBDA)) * n_mid
C_mid_5 = (BETA_5 / (LAM_5 * LAMBDA)) * n_mid
C_mid_6 = (BETA_6 / (LAM_6 * LAMBDA)) * n_mid
# C_i scale linearly with n; sweep across the n_lo..n_hi band.
x_lo = [C_mid_1 * (n_lo / n_mid); C_mid_2 * (n_lo / n_mid);
C_mid_3 * (n_lo / n_mid); C_mid_4 * (n_lo / n_mid);
C_mid_5 * (n_lo / n_mid); C_mid_6 * (n_lo / n_mid);
T_f_lo; T_c_lo; T_cold_lo;
0.0]
x_hi = [C_mid_1 * (n_hi / n_mid); C_mid_2 * (n_hi / n_mid);
C_mid_3 * (n_hi / n_mid); C_mid_4 * (n_hi / n_mid);
C_mid_5 * (n_hi / n_mid); C_mid_6 * (n_hi / n_mid);
T_f_hi; T_c_hi; T_cold_hi;
0.0]
X0 = Hyperrectangle(low=x_lo, high=x_hi)
println("\n=== Nonlinear heatup reach, prompt-jump model ===")
println(" X_entry (n-implied range): n ∈ [$(n_lo), $(n_hi)]")
println(" T_c ∈ [$(T_c_lo), $(T_c_hi)] °C")
T_RAMP_END = (T_C0 - T_STANDBY) / RAMP_RATE_CS
println(" T_ramp_end = $(round(T_RAMP_END; digits=0)) s ($(round(T_RAMP_END/60; digits=1)) min)")
println(" Probing horizons up to T_max(heatup) = 18000 s (5 hr).")
# Probe at increasing horizons. Stop early if any probe fails.
probe_horizons = (60.0, 300.0, 1800.0, 5400.0)
results = Dict{Float64, Any}()
for T_probe in probe_horizons
println("\n--- Probe T = $T_probe s ($(round(T_probe/60; digits=1)) min) ---")
sys = BlackBoxContinuousSystem(rhs_heatup_pj_taylor!, 10)
prob = InitialValueProblem(sys, X0)
try
alg = TMJets(orderT=4, orderQ=2, abstol=1e-9, maxsteps=100000)
t_start = time()
sol = solve(prob; T=T_probe, alg=alg)
elapsed = time() - t_start
flow = flowpipe(sol)
n_sets = length(flow)
println(" TMJets: $n_sets reach-sets, wall-time $(round(elapsed; digits=1)) s")
flow_hr = overapproximate(flow, Hyperrectangle)
# Envelope at the FINAL set.
Tc_lo_env = minimum(low(set(R), 8) for R in flow_hr)
Tc_hi_env = maximum(high(set(R), 8) for R in flow_hr)
Tf_lo_env = minimum(low(set(R), 7) for R in flow_hr)
Tf_hi_env = maximum(high(set(R), 7) for R in flow_hr)
Tcold_lo = minimum(low(set(R), 9) for R in flow_hr)
Tcold_hi = maximum(high(set(R), 9) for R in flow_hr)
# Reconstruct n envelope at each step from C and T_c via PJ formula.
n_env_lo = Inf
n_env_hi = -Inf
for R in flow_hr
s = set(R)
sumLC_lo = LAM_1*low(s,1) + LAM_2*low(s,2) + LAM_3*low(s,3) +
LAM_4*low(s,4) + LAM_5*low(s,5) + LAM_6*low(s,6)
sumLC_hi = LAM_1*high(s,1) + LAM_2*high(s,2) + LAM_3*high(s,3) +
LAM_4*high(s,4) + LAM_5*high(s,5) + LAM_6*high(s,6)
# rho range: ρ = Kp*(T_ref - T_c). T_ref bounded by [T_STANDBY, T_C0],
# T_c bounded by current envelope.
rho_lo = KP_HEATUP * (T_STANDBY - high(s, 8))
rho_hi = KP_HEATUP * (T_C0 - low(s, 8))
denom_lo = BETA - rho_hi # smaller denom => larger n
denom_hi = BETA - rho_lo
if denom_lo > 0
n_lo_local = LAMBDA * sumLC_lo / denom_hi
n_hi_local = LAMBDA * sumLC_hi / denom_lo
n_env_lo = min(n_env_lo, n_lo_local)
n_env_hi = max(n_env_hi, n_hi_local)
end
end
println(" n envelope (reconstructed): [$(round(n_env_lo; sigdigits=4)), $(round(n_env_hi; sigdigits=4))]")
println(" T_f envelope: [$(round(Tf_lo_env; digits=2)), $(round(Tf_hi_env; digits=2))] °C")
println(" T_c envelope: [$(round(Tc_lo_env; digits=2)), $(round(Tc_hi_env; digits=2))] °C")
println(" T_cold envelope: [$(round(Tcold_lo; digits=2)), $(round(Tcold_hi; digits=2))] °C")
results[T_probe] = (status="OK", n_sets=n_sets, elapsed=elapsed,
Tc=(Tc_lo_env, Tc_hi_env),
Tf=(Tf_lo_env, Tf_hi_env),
Tcold=(Tcold_lo, Tcold_hi),
n=(n_env_lo, n_env_hi))
catch err
msg = sprint(showerror, err)
println(" FAILED: ", first(msg, 300))
results[T_probe] = (status="FAILED", err=first(msg, 300))
break
end
end
println("\n=== Summary ===")
for T_probe in probe_horizons
haskey(results, T_probe) || continue
r = results[T_probe]
if r.status == "OK"
println(" T = $(T_probe) s: OK, $(r.n_sets) reach-sets, $(round(r.elapsed; digits=1))s wall")
else
println(" T = $(T_probe) s: FAILED")
end
end
# Save the longest-successful probe's envelope arrays for the app.
mat_out = joinpath(@__DIR__, "..", "..", "reachability", "reach_heatup_pj_result.mat")
saved = Dict{String, Any}()
saved["probe_horizons"] = collect(probe_horizons)
for T_probe in probe_horizons
haskey(results, T_probe) || continue
r = results[T_probe]
if r.status == "OK"
saved["T_$(Int(T_probe))_Tc_lo"] = r.Tc[1]
saved["T_$(Int(T_probe))_Tc_hi"] = r.Tc[2]
saved["T_$(Int(T_probe))_Tf_lo"] = r.Tf[1]
saved["T_$(Int(T_probe))_Tf_hi"] = r.Tf[2]
saved["T_$(Int(T_probe))_Tcold_lo"] = r.Tcold[1]
saved["T_$(Int(T_probe))_Tcold_hi"] = r.Tcold[2]
saved["T_$(Int(T_probe))_n_lo"] = r.n[1]
saved["T_$(Int(T_probe))_n_hi"] = r.n[2]
end
end
matwrite(mat_out, saved)
println("\nSaved envelope summaries to $mat_out")
Reference in New Issue View Git Blame Copy Permalink