823 lines
29 KiB
Python
823 lines
29 KiB
Python
# backend/services/planning_engine.py
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#
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# EMS Platform – plánovací engine
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# Obsahuje: hlavní denní plán + rolling 15min replan
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#
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# Spouštění (APScheduler v main.py):
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# scheduler.add_job(run_daily_plan, 'cron', hour=15, minute=0)
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# scheduler.add_job(run_rolling_replan, 'cron', minute='*/15')
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import time
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import logging
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from dataclasses import dataclass, replace
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from datetime import datetime, timezone, timedelta
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from types import SimpleNamespace
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from typing import Optional
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import pulp
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from pulp import HiGHS_CMD
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logger = logging.getLogger(__name__)
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# ============================================================
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# Konstanty
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# ============================================================
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HORIZON_HOURS = 36 # horizont denního plánu
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INTERVAL_H = 0.25 # 15 minut v hodinách
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CURTAILMENT_PENALTY = 0.001 # Kč/Wh – malá penalizace za omezení FVE pole A
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SOLVER_TIME_LIMIT = 10 # sekund
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CORRECTION_WINDOW_H = 1 # hodina zpět pro výpočet korekčního faktoru
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CORRECTION_MIN_CLAMP = 0.5 # spodní limit korekčního faktoru
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CORRECTION_MAX_CLAMP = 1.5 # horní limit korekčního faktoru
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# Útlum korekce: čím dál od aktuálního času, tím méně korigujeme forecast
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CORRECTION_DECAY_SLOTS = 16 # po 16 slotech (4h) klesne korekce na 0
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# ============================================================
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# Datové třídy (lze nahradit pydantic modely)
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# ============================================================
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@dataclass
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class PlanningSlot:
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interval_start: datetime
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buy_price: float # Kč/kWh
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sell_price: float # Kč/kWh
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pv_a_forecast_w: int # W – pole A (řiditelné)
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pv_b_forecast_w: int # W – pole B (zelený bonus, pevné)
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load_baseline_w: int # W – predikce bazální spotřeby
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ev1_connected: bool
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ev2_connected: bool
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@dataclass
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class DispatchResult:
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interval_start: datetime
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battery_setpoint_w: int # kladné = nabíjení, záporné = vybíjení
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battery_soc_target: float # % SoC na konci intervalu
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grid_setpoint_w: int # kladné = import, záporné = export
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ev1_setpoint_w: Optional[int]
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ev2_setpoint_w: Optional[int]
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ev1_via_bat_w: int
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ev2_via_bat_w: int
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heat_pump_enabled: bool
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heat_pump_setpoint_w: int
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pv_a_curtailed_w: int
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expected_cost_czk: float
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effective_buy_price: float
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effective_sell_price: float
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# ============================================================
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# Korekce forecastu na základě skutečné výroby
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# ============================================================
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async def compute_correction_factor(
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site_id: int,
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now: datetime,
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db,
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window_h: float = CORRECTION_WINDOW_H,
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) -> tuple[float, dict]:
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"""
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Spočítá korekční faktor FVE forecastu z posledních window_h hodin.
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Vrátí (factor, log_data) kde factor je v rozsahu [CORRECTION_MIN_CLAMP, CORRECTION_MAX_CLAMP].
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factor = 1.0 pokud není dostatek dat nebo je rozdíl zanedbatelný.
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"""
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window_start = now - timedelta(hours=window_h)
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# Skutečná výroba za okno (z telemetrie)
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actual = await db.fetchval("""
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SELECT COALESCE(SUM(pv_power_w) * 0.25 / 1000.0, 0) -- kWh
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FROM ems.telemetry_inverter
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WHERE site_id = $1
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AND measured_at >= $2 AND measured_at < $3
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""", site_id, window_start, now)
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# Předpovídaná výroba za stejné okno (z nejnovějšího forecastu který platil tehdy)
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forecast = await db.fetchval("""
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SELECT COALESCE(SUM(fpi.power_w) * 0.25 / 1000.0, 0)
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FROM ems.forecast_pv_interval fpi
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JOIN ems.forecast_pv_run fpr ON fpr.id = fpi.run_id
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WHERE fpr.site_id = $1
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AND fpi.interval_start >= $2 AND fpi.interval_start < $3
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AND fpr.status = 'ok'
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AND fpr.created_at = (
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SELECT MAX(fpr2.created_at)
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FROM ems.forecast_pv_run fpr2
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WHERE fpr2.site_id = $1 AND fpr2.status = 'ok'
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AND fpr2.created_at <= $2
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)
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""", site_id, window_start, now)
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log_data = {
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"window_start": window_start,
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"window_end": now,
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"actual_pv_wh": actual * 1000,
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"forecast_pv_wh": forecast * 1000,
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}
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# Pokud forecast nebo actual jsou příliš malé (noc, <0.1 kWh) → žádná korekce
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if forecast < 0.1 or actual < 0.05:
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log_data["correction_factor"] = 1.0
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log_data["reason"] = "insufficient_data"
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return 1.0, log_data
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raw_factor = actual / forecast
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factor = max(CORRECTION_MIN_CLAMP, min(CORRECTION_MAX_CLAMP, raw_factor))
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log_data["correction_factor"] = factor
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log_data["raw_factor"] = raw_factor
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return factor, log_data
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def apply_forecast_correction(
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slots: list[PlanningSlot],
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now: datetime,
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factor: float,
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decay_slots: int = CORRECTION_DECAY_SLOTS,
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) -> list[PlanningSlot]:
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"""
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Aplikuje korekční faktor na FVE forecast zbývajících slotů.
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Korekce se lineárně utlumuje: na 1. slotu plná korekce,
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na decay_slots-tém slotu žádná korekce.
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Příklad: factor=0.85, slot 0 → pv_a *= 0.85, slot 8 → pv_a *= 0.925, slot 16+ → žádná korekce
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"""
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corrected = []
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for i, slot in enumerate(slots):
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if factor == 1.0 or i >= decay_slots:
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corrected.append(slot)
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continue
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# Lineární útlum: weight klesá od 1.0 (slot 0) do 0.0 (slot decay_slots)
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weight = 1.0 - (i / decay_slots)
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effective_factor = 1.0 + (factor - 1.0) * weight
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corrected.append(
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replace(
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slot,
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pv_a_forecast_w=max(0, int(slot.pv_a_forecast_w * effective_factor)),
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pv_b_forecast_w=max(0, int(slot.pv_b_forecast_w * effective_factor)),
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)
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)
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return corrected
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# ============================================================
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# LP Solver
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# ============================================================
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def solve_dispatch(
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slots: list[PlanningSlot],
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battery,
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heat_pump,
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grid,
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ev_sessions: list, # aktivní EV sessions [ev1_session, ev2_session]
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vehicles: list, # [vehicle1, vehicle2]
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current_soc_wh: float,
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current_tuv_temp_c: float,
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) -> tuple[list[DispatchResult], int]:
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"""
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LP solver pro dispatch optimalizaci.
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Vrátí (výsledky, solver_duration_ms).
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"""
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T = len(slots)
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EV = len(vehicles) # počet EV (typicky 2)
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EV_ROUNDTRIP_FACTOR = 1.0 / (battery.charge_efficiency * battery.discharge_efficiency)
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prob = pulp.LpProblem("ems_dispatch", pulp.LpMinimize)
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# --- Proměnné ---
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gi = [pulp.LpVariable(f"gi_{t}", 0, grid.max_import_power_w) for t in range(T)]
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ge = [pulp.LpVariable(f"ge_{t}", 0, grid.max_export_power_w) for t in range(T)]
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bc = [pulp.LpVariable(f"bc_{t}", 0, battery.max_charge_power_w) for t in range(T)]
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bd = [pulp.LpVariable(f"bd_{t}", 0, battery.max_discharge_power_w) for t in range(T)]
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soc = [pulp.LpVariable(f"soc_{t}", battery.reserve_soc_wh, battery.soc_max_wh) for t in range(T)]
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ca = [pulp.LpVariable(f"ca_{t}", 0, slots[t].pv_a_forecast_w) for t in range(T)]
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hp = [pulp.LpVariable(f"hp_{t}", 0, heat_pump.rated_heating_power_w) for t in range(T)]
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# EV proměnné per vozidlo
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ev_direct = [[pulp.LpVariable(f"evd_{e}_{t}", 0,
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min(vehicles[e].max_charge_power_w, grid.max_import_power_w))
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for t in range(T)] for e in range(EV)]
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ev_via_bat = [[pulp.LpVariable(f"evb_{e}_{t}", 0,
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vehicles[e].max_charge_power_w)
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for t in range(T)] for e in range(EV)]
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# --- Účelová funkce ---
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prob += pulp.lpSum(
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gi[t] * slots[t].buy_price * INTERVAL_H / 1000
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- ge[t] * slots[t].sell_price * INTERVAL_H / 1000
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+ (bc[t] + bd[t]) * battery.degradation_cost_czk_kwh * INTERVAL_H / 1000
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+ pulp.lpSum(
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ev_direct[e][t] * slots[t].buy_price * INTERVAL_H / 1000
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+ ev_via_bat[e][t] * slots[t].buy_price * EV_ROUNDTRIP_FACTOR * INTERVAL_H / 1000
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for e in range(EV)
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)
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+ ca[t] * CURTAILMENT_PENALTY
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for t in range(T)
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)
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# --- Omezení ---
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for t in range(T):
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s = slots[t]
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pv_a_net = s.pv_a_forecast_w - ca[t]
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ev_total_t = pulp.lpSum(ev_direct[e][t] + ev_via_bat[e][t] for e in range(EV))
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# Energetická bilance
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prob += (
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pv_a_net + s.pv_b_forecast_w + gi[t] + bd[t]
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== s.load_baseline_w + ev_total_t + hp[t] + bc[t] + ge[t]
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)
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# SoC kontinuita
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soc_prev = current_soc_wh if t == 0 else soc[t - 1]
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prob += soc[t] == (
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soc_prev
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+ bc[t] * battery.charge_efficiency * INTERVAL_H
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- bd[t] / battery.discharge_efficiency * INTERVAL_H
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)
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# ev_via_bat kryto z discharge
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prob += pulp.lpSum(ev_via_bat[e][t] for e in range(EV)) <= bd[t]
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# Záporná prodejní cena → zakázat export
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if s.sell_price < 0:
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prob += ge[t] == 0
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# Záporná nákupní cena → cap import na reálnou spotřebu
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if s.buy_price < 0:
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prob += gi[t] <= (
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battery.max_charge_power_w
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+ sum(v.max_charge_power_w for v in vehicles)
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+ heat_pump.rated_heating_power_w
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)
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# EV – limity a připojení
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for e in range(EV):
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connected = (
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(e == 0 and s.ev1_connected) or
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(e == 1 and s.ev2_connected)
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)
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if not connected:
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prob += ev_direct[e][t] == 0
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prob += ev_via_bat[e][t] == 0
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else:
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prob += ev_direct[e][t] + ev_via_bat[e][t] <= vehicles[e].max_charge_power_w
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# Deadline constraints pro EV
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for e, session in enumerate(ev_sessions):
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if session and session.target_deadline and session.energy_needed_wh > 0:
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t_dl = next(
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(t for t, s in enumerate(slots) if s.interval_start >= session.target_deadline),
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T - 1
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)
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prob += pulp.lpSum(
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(ev_direct[e][t] + ev_via_bat[e][t]) * INTERVAL_H
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for t in range(t_dl + 1)
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if (e == 0 and slots[t].ev1_connected) or (e == 1 and slots[t].ev2_connected)
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) >= session.energy_needed_wh
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# Nouzový ohřev TUV
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if current_tuv_temp_c < heat_pump.tuv_min_temp_c:
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prob += hp[0] >= heat_pump.rated_heating_power_w * 0.8
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# --- Řešení ---
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t_start = time.monotonic()
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solver = HiGHS_CMD(msg=False, timeLimit=SOLVER_TIME_LIMIT)
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status = prob.solve(solver)
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duration_ms = int((time.monotonic() - t_start) * 1000)
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if pulp.LpStatus[status] != 'Optimal':
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raise RuntimeError(f"Solver: {pulp.LpStatus[status]}")
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# --- Post-processing ---
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results = []
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for t in range(T):
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hp_raw = pulp.value(hp[t])
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hp_on = hp_raw > heat_pump.rated_heating_power_w * 0.3
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batt_w = round(pulp.value(bc[t]) - pulp.value(bd[t]))
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grid_w = round(pulp.value(gi[t]) - pulp.value(ge[t]))
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soc_pct = round(pulp.value(soc[t]) / battery.usable_capacity_wh * 100, 1)
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cost = (
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pulp.value(gi[t]) * slots[t].buy_price * INTERVAL_H / 1000
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- pulp.value(ge[t]) * slots[t].sell_price * INTERVAL_H / 1000
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)
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results.append(DispatchResult(
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interval_start = slots[t].interval_start,
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battery_setpoint_w = batt_w,
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battery_soc_target = soc_pct,
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grid_setpoint_w = grid_w,
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ev1_setpoint_w = round(pulp.value(ev_direct[0][t]) + pulp.value(ev_via_bat[0][t]))
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if slots[t].ev1_connected else None,
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ev2_setpoint_w = round(pulp.value(ev_direct[1][t]) + pulp.value(ev_via_bat[1][t]))
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if slots[t].ev2_connected else None,
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ev1_via_bat_w = round(pulp.value(ev_via_bat[0][t])),
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ev2_via_bat_w = round(pulp.value(ev_via_bat[1][t])),
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heat_pump_enabled = hp_on,
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heat_pump_setpoint_w = heat_pump.rated_heating_power_w if hp_on else 0,
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pv_a_curtailed_w = round(pulp.value(ca[t])),
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expected_cost_czk = round(cost, 4),
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effective_buy_price = slots[t].buy_price,
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effective_sell_price = slots[t].sell_price,
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))
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return results, duration_ms
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# ============================================================
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# Denní plán (15:00)
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# ============================================================
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async def run_daily_plan(site_id: int, db, triggered_by: str = "scheduler:daily") -> tuple[int, int]:
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"""
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Hlavní denní plánování. Spouštět v 15:00 po importu cen (14:00)
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a aktualizaci forecastu (14:30).
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Horizont: od začátku aktuálního 15min slotu do +36h.
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"""
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now = datetime.now(timezone.utc)
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horizon_from = _current_slot_start(now)
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horizon_to = horizon_from + timedelta(hours=HORIZON_HOURS)
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logger.info(f"[site={site_id}] Daily plan: {horizon_from} → {horizon_to}")
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slots = await _load_slots(site_id, horizon_from, horizon_to, db)
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battery, hp, grid, vehicles, ev_sessions, soc_wh, tuv_temp = await _load_site_context(
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site_id, db
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)
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results, duration_ms = solve_dispatch(
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slots, battery, hp, grid, ev_sessions, vehicles, soc_wh, tuv_temp
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)
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run_id = await _save_planning_run(
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site_id,
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results,
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horizon_from,
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horizon_to,
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run_type="daily",
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triggered_by=triggered_by,
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replan_from=None,
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soc_wh=soc_wh,
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duration_ms=duration_ms,
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correction=1.0,
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db=db,
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)
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logger.info(f"[site={site_id}] Daily plan done in {duration_ms} ms")
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return run_id, duration_ms
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# ============================================================
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# Rolling replan (každých 15min)
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# ============================================================
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||
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async def run_rolling_replan(
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site_id: int,
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db,
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*,
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triggered_by: str = "scheduler:rolling",
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allow_skip: bool = True,
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) -> tuple[Optional[int], Optional[int]]:
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"""
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Rolling replan každých 15 minut.
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1. Zjistí aktuální SoC baterie z telemetrie
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2. Spočítá korekční faktor FVE forecastu z poslední hodiny
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3. Aplikuje korekci na forecast zbytku dne (s útlumem)
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4. Spustí solver pro zbývající horizont aktivního plánu
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5. Uloží jako nový planning_run (aktivní plán se stane superseded)
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Pokud allow_skip=True (scheduler) a horizont je vyčerpaný → vrátí (None, None).
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Pokud allow_skip=False (API) → spustí denní plán jako náhradu.
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"""
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now = datetime.now(timezone.utc)
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replan_from = _current_slot_start(now)
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active_run = await db.fetchrow("""
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SELECT id, horizon_end FROM ems.planning_run
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WHERE site_id = $1 AND status = 'active'
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ORDER BY created_at DESC LIMIT 1
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""", site_id)
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if not active_run:
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logger.warning(f"[site={site_id}] Rolling replan: no active plan, triggering daily plan")
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return await run_daily_plan(site_id, db, triggered_by=triggered_by)
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horizon_to = active_run["horizon_end"]
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if (horizon_to - replan_from).total_seconds() < 1800:
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if allow_skip:
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logger.info(f"[site={site_id}] Rolling replan: horizon almost exhausted, skipping")
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return None, None
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logger.info(f"[site={site_id}] Rolling replan: horizon exhausted, running daily plan")
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return await run_daily_plan(site_id, db, triggered_by=triggered_by)
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logger.info(f"[site={site_id}] Rolling replan from {replan_from} → {horizon_to}")
|
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||
battery, hp, grid, vehicles, ev_sessions, soc_wh, tuv_temp = await _load_site_context(
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site_id, db
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||
)
|
||
|
||
correction_factor, correction_log = await compute_correction_factor(site_id, now, db)
|
||
|
||
slots = await _load_slots(site_id, replan_from, horizon_to, db)
|
||
|
||
slots = apply_forecast_correction(slots, now, correction_factor)
|
||
|
||
results, duration_ms = solve_dispatch(
|
||
slots, battery, hp, grid, ev_sessions, vehicles, soc_wh, tuv_temp
|
||
)
|
||
|
||
run_id = await _save_planning_run(
|
||
site_id,
|
||
results,
|
||
replan_from,
|
||
horizon_to,
|
||
run_type="rolling",
|
||
triggered_by=triggered_by,
|
||
replan_from=replan_from,
|
||
soc_wh=soc_wh,
|
||
duration_ms=duration_ms,
|
||
correction=correction_factor,
|
||
db=db,
|
||
)
|
||
|
||
await db.execute(
|
||
"""
|
||
INSERT INTO ems.forecast_correction_log
|
||
(site_id, window_start, window_end, actual_pv_wh, forecast_pv_wh,
|
||
correction_factor, applied_to_run_id)
|
||
VALUES ($1,$2,$3,$4,$5,$6,$7)
|
||
""",
|
||
site_id,
|
||
correction_log["window_start"],
|
||
correction_log["window_end"],
|
||
correction_log.get("actual_pv_wh"),
|
||
correction_log.get("forecast_pv_wh"),
|
||
correction_factor,
|
||
run_id,
|
||
)
|
||
|
||
logger.info(
|
||
f"[site={site_id}] Rolling replan done in {duration_ms} ms "
|
||
f"(correction={correction_factor:.3f})"
|
||
)
|
||
return run_id, duration_ms
|
||
|
||
|
||
async def run_plan_api(
|
||
site_id: int,
|
||
plan_type: str,
|
||
db,
|
||
*,
|
||
triggered_by: str = "api",
|
||
) -> tuple[int, int]:
|
||
"""Ruční / UI spuštění plánu. Vždy vrátí (run_id, solver_duration_ms)."""
|
||
pt = plan_type.lower().strip()
|
||
if pt == "daily":
|
||
return await run_daily_plan(site_id, db, triggered_by=triggered_by)
|
||
if pt == "rolling":
|
||
rid, ms = await run_rolling_replan(
|
||
site_id, db, triggered_by=triggered_by, allow_skip=False
|
||
)
|
||
if rid is None or ms is None:
|
||
raise RuntimeError("Rolling replan did not return a run")
|
||
return rid, ms
|
||
raise ValueError(f"Unknown plan_type: {plan_type!r} (use daily or rolling)")
|
||
|
||
|
||
# ============================================================
|
||
# Pomocné funkce
|
||
# ============================================================
|
||
|
||
def _current_slot_start(dt: datetime) -> datetime:
|
||
"""Zaokrouhlí čas dolů na začátek aktuálního 15min slotu."""
|
||
minute = (dt.minute // 15) * 15
|
||
return dt.replace(minute=minute, second=0, microsecond=0)
|
||
|
||
|
||
def _ev_session_ctx(row) -> Optional[SimpleNamespace]:
|
||
"""Kontext deadline constraintu pro jedno EV (nebo None)."""
|
||
if row is None or row["target_deadline"] is None:
|
||
return None
|
||
cap_kwh = row["veh_cap_kwh"]
|
||
if cap_kwh is None:
|
||
return None
|
||
cap_wh = float(cap_kwh) * 1000.0
|
||
tgt = row["target_soc_pct"]
|
||
if tgt is None:
|
||
tgt = row["default_target_soc_pct"]
|
||
if tgt is None:
|
||
return None
|
||
tgt_f = float(tgt)
|
||
soc0 = row["soc_at_connect_pct"]
|
||
if soc0 is None:
|
||
return None
|
||
needed_wh = (tgt_f - float(soc0)) / 100.0 * cap_wh
|
||
delivered = float(row["energy_delivered_wh"] or 0)
|
||
remaining = max(0.0, needed_wh - delivered)
|
||
if remaining <= 0:
|
||
return None
|
||
return SimpleNamespace(
|
||
target_deadline=row["target_deadline"],
|
||
energy_needed_wh=remaining,
|
||
)
|
||
|
||
|
||
async def _load_site_context(site_id: int, db):
|
||
"""
|
||
Načte baterii, TČ, síť, 2× vozidlo, otevřené EV session, SoC a TUV pro solver.
|
||
"""
|
||
brow = await db.fetchrow(
|
||
"""
|
||
SELECT bat.usable_capacity_wh,
|
||
bat.reserve_soc_percent,
|
||
bat.max_soc_percent,
|
||
bat.charge_efficiency,
|
||
bat.discharge_efficiency,
|
||
bat.degradation_cost_czk_kwh,
|
||
inv.max_charge_power_w,
|
||
inv.max_discharge_power_w
|
||
FROM ems.asset_battery bat
|
||
JOIN ems.asset_inverter inv ON inv.id = bat.inverter_id AND inv.site_id = bat.site_id
|
||
WHERE bat.site_id = $1
|
||
ORDER BY bat.id
|
||
LIMIT 1
|
||
""",
|
||
site_id,
|
||
)
|
||
if brow is None:
|
||
raise RuntimeError(f"No asset_battery for site_id={site_id}")
|
||
|
||
uc = float(brow["usable_capacity_wh"])
|
||
reserve_wh = float(brow["reserve_soc_percent"]) / 100.0 * uc
|
||
soc_max_wh = float(brow["max_soc_percent"]) / 100.0 * uc
|
||
battery = SimpleNamespace(
|
||
usable_capacity_wh=uc,
|
||
reserve_soc_wh=reserve_wh,
|
||
soc_max_wh=soc_max_wh,
|
||
charge_efficiency=float(brow["charge_efficiency"]),
|
||
discharge_efficiency=float(brow["discharge_efficiency"]),
|
||
degradation_cost_czk_kwh=float(brow["degradation_cost_czk_kwh"]),
|
||
max_charge_power_w=int(brow["max_charge_power_w"]),
|
||
max_discharge_power_w=int(brow["max_discharge_power_w"]),
|
||
)
|
||
|
||
hrow = await db.fetchrow(
|
||
"""
|
||
SELECT COALESCE(rated_heating_power_w, 8000) AS rated_heating_power_w,
|
||
COALESCE(tuv_min_temp_c, 45) AS tuv_min_temp_c
|
||
FROM ems.asset_heat_pump
|
||
WHERE site_id = $1
|
||
ORDER BY id
|
||
LIMIT 1
|
||
""",
|
||
site_id,
|
||
)
|
||
if hrow is None:
|
||
heat_pump = SimpleNamespace(rated_heating_power_w=0, tuv_min_temp_c=0.0)
|
||
else:
|
||
hp_w = int(hrow["rated_heating_power_w"])
|
||
heat_pump = SimpleNamespace(
|
||
rated_heating_power_w=max(hp_w, 0),
|
||
tuv_min_temp_c=float(hrow["tuv_min_temp_c"]),
|
||
)
|
||
|
||
grow = await db.fetchrow(
|
||
"""
|
||
SELECT max_import_power_w, max_export_power_w
|
||
FROM ems.site_grid_connection
|
||
WHERE site_id = $1
|
||
ORDER BY id
|
||
LIMIT 1
|
||
""",
|
||
site_id,
|
||
)
|
||
if grow is None:
|
||
raise RuntimeError(f"No site_grid_connection for site_id={site_id}")
|
||
grid = SimpleNamespace(
|
||
max_import_power_w=int(grow["max_import_power_w"]),
|
||
max_export_power_w=int(grow["max_export_power_w"]),
|
||
)
|
||
|
||
vrows = await db.fetch(
|
||
"""
|
||
SELECT v.battery_capacity_kwh,
|
||
v.max_charge_power_w,
|
||
v.default_target_soc_pct,
|
||
ch.code AS charger_code
|
||
FROM ems.asset_vehicle v
|
||
JOIN ems.asset_ev_charger ch ON ch.id = v.default_charger_id
|
||
WHERE v.site_id = $1
|
||
AND ch.code IN ('ev-charger-1', 'ev-charger-2')
|
||
ORDER BY ch.code
|
||
""",
|
||
site_id,
|
||
)
|
||
vehicles: list[SimpleNamespace] = [
|
||
SimpleNamespace(
|
||
max_charge_power_w=int(r["max_charge_power_w"]),
|
||
battery_capacity_kwh=float(r["battery_capacity_kwh"]),
|
||
default_target_soc_pct=float(r["default_target_soc_pct"]),
|
||
)
|
||
for r in vrows
|
||
]
|
||
while len(vehicles) < 2:
|
||
vehicles.append(
|
||
SimpleNamespace(
|
||
max_charge_power_w=0,
|
||
battery_capacity_kwh=1.0,
|
||
default_target_soc_pct=80.0,
|
||
)
|
||
)
|
||
|
||
srows = await db.fetch(
|
||
"""
|
||
SELECT es.target_deadline,
|
||
es.target_soc_pct,
|
||
es.soc_at_connect_pct,
|
||
es.energy_delivered_wh,
|
||
ch.code AS charger_code,
|
||
v.battery_capacity_kwh AS veh_cap_kwh,
|
||
v.default_target_soc_pct
|
||
FROM ems.ev_session es
|
||
JOIN ems.asset_ev_charger ch ON ch.id = es.charger_id
|
||
LEFT JOIN ems.asset_vehicle v ON v.id = es.vehicle_id
|
||
WHERE es.site_id = $1
|
||
AND es.session_end IS NULL
|
||
""",
|
||
site_id,
|
||
)
|
||
by_charger = {r["charger_code"]: r for r in srows}
|
||
ev_sessions = [
|
||
_ev_session_ctx(by_charger.get("ev-charger-1")),
|
||
_ev_session_ctx(by_charger.get("ev-charger-2")),
|
||
]
|
||
|
||
soc_pct = await db.fetchval(
|
||
"""
|
||
SELECT battery_soc_percent
|
||
FROM ems.telemetry_inverter
|
||
WHERE site_id = $1
|
||
ORDER BY measured_at DESC
|
||
LIMIT 1
|
||
""",
|
||
site_id,
|
||
)
|
||
if soc_pct is None:
|
||
soc_wh = uc * 0.5
|
||
else:
|
||
soc_wh = float(soc_pct) / 100.0 * uc
|
||
soc_wh = max(reserve_wh, min(soc_wh, soc_max_wh))
|
||
|
||
tuv = await db.fetchval(
|
||
"""
|
||
SELECT tuv_tank_temp_c
|
||
FROM ems.telemetry_heat_pump
|
||
WHERE site_id = $1
|
||
ORDER BY measured_at DESC
|
||
LIMIT 1
|
||
""",
|
||
site_id,
|
||
)
|
||
tuv_temp = float(tuv) if tuv is not None else 50.0
|
||
|
||
return battery, heat_pump, grid, vehicles, ev_sessions, soc_wh, tuv_temp
|
||
|
||
|
||
async def _load_slots(site_id, from_dt, to_dt, db) -> list[PlanningSlot]:
|
||
"""Načte 15min sloty s cenami, forecasty a stavem EV z DB."""
|
||
rows = await db.fetch("""
|
||
SELECT
|
||
ep.interval_start,
|
||
ep.effective_buy_price_czk_kwh AS buy_price,
|
||
ep.effective_sell_price_czk_kwh AS sell_price,
|
||
COALESCE(fpi_a.power_w, 0) AS pv_a_forecast_w,
|
||
COALESCE(fpi_b.power_w, 0) AS pv_b_forecast_w,
|
||
COALESCE(cbi.power_w, 500) AS load_baseline_w,
|
||
-- EV připojení z poslední telemetrie nabíječek (bez řádku = nepřipojeno)
|
||
(COALESCE(ev1.status, 'available') NOT IN ('available', 'unavailable')) AS ev1_connected,
|
||
(COALESCE(ev2.status, 'available') NOT IN ('available', 'unavailable')) AS ev2_connected
|
||
FROM ems.vw_site_effective_price ep
|
||
-- FVE pole A forecast
|
||
LEFT JOIN LATERAL (
|
||
SELECT fpi.power_w FROM ems.forecast_pv_interval fpi
|
||
JOIN ems.forecast_pv_run fpr ON fpr.id = fpi.run_id
|
||
JOIN ems.asset_pv_array apa ON apa.id = fpi.pv_array_id AND apa.site_id = fpr.site_id
|
||
WHERE fpr.site_id = $1 AND apa.code = 'pv-a'
|
||
AND fpi.interval_start = ep.interval_start AND fpr.status = 'ok'
|
||
ORDER BY fpr.created_at DESC LIMIT 1
|
||
) fpi_a ON true
|
||
-- FVE pole B forecast
|
||
LEFT JOIN LATERAL (
|
||
SELECT fpi.power_w FROM ems.forecast_pv_interval fpi
|
||
JOIN ems.forecast_pv_run fpr ON fpr.id = fpi.run_id
|
||
JOIN ems.asset_pv_array apa ON apa.id = fpi.pv_array_id AND apa.site_id = fpr.site_id
|
||
WHERE fpr.site_id = $1 AND apa.code = 'pv-b'
|
||
AND fpi.interval_start = ep.interval_start AND fpr.status = 'ok'
|
||
ORDER BY fpr.created_at DESC LIMIT 1
|
||
) fpi_b ON true
|
||
-- Bazální spotřeba
|
||
LEFT JOIN ems.consumption_baseline_interval cbi
|
||
ON cbi.site_id = $1 AND cbi.interval_start = ep.interval_start
|
||
AND cbi.data_type = 'forecast'
|
||
-- Stav EV nabíječek (aktuální, pro celý horizont stejný)
|
||
LEFT JOIN LATERAL (
|
||
SELECT t.status
|
||
FROM ems.telemetry_ev_charger t
|
||
JOIN ems.asset_ev_charger ch ON ch.id = t.charger_id
|
||
WHERE t.site_id = $1 AND ch.code = 'ev-charger-1'
|
||
ORDER BY t.measured_at DESC LIMIT 1
|
||
) ev1 ON true
|
||
LEFT JOIN LATERAL (
|
||
SELECT t.status
|
||
FROM ems.telemetry_ev_charger t
|
||
JOIN ems.asset_ev_charger ch ON ch.id = t.charger_id
|
||
WHERE t.site_id = $1 AND ch.code = 'ev-charger-2'
|
||
ORDER BY t.measured_at DESC LIMIT 1
|
||
) ev2 ON true
|
||
WHERE ep.site_id = $1
|
||
AND ep.interval_start >= $2 AND ep.interval_start < $3
|
||
ORDER BY ep.interval_start
|
||
""", site_id, from_dt, to_dt)
|
||
|
||
out: list[PlanningSlot] = []
|
||
for r in rows:
|
||
d = dict(r)
|
||
out.append(
|
||
PlanningSlot(
|
||
interval_start=d["interval_start"],
|
||
buy_price=float(d["buy_price"]),
|
||
sell_price=float(d["sell_price"]),
|
||
pv_a_forecast_w=int(d["pv_a_forecast_w"] or 0),
|
||
pv_b_forecast_w=int(d["pv_b_forecast_w"] or 0),
|
||
load_baseline_w=int(d["load_baseline_w"] or 0),
|
||
ev1_connected=bool(d["ev1_connected"]),
|
||
ev2_connected=bool(d["ev2_connected"]),
|
||
)
|
||
)
|
||
if not out:
|
||
raise RuntimeError(
|
||
"No planning slots available – check market prices and horizon settings"
|
||
)
|
||
return out
|
||
|
||
|
||
async def _save_planning_run(
|
||
site_id, results, horizon_from, horizon_to,
|
||
run_type, triggered_by, replan_from,
|
||
soc_wh, duration_ms, correction, db
|
||
) -> int:
|
||
"""Uloží výsledky solveru jako nový planning_run, deaktivuje předchozí."""
|
||
run_id = await db.fetchval("""
|
||
INSERT INTO ems.planning_run
|
||
(site_id, horizon_start, horizon_end, status,
|
||
run_type, triggered_by, replan_from,
|
||
soc_at_replan_wh, solver_duration_ms, forecast_correction_factor)
|
||
VALUES ($1,$2,$3,'draft',$4,$5,$6,$7,$8,$9)
|
||
RETURNING id
|
||
""", site_id, horizon_from, horizon_to,
|
||
run_type, triggered_by, replan_from,
|
||
soc_wh, duration_ms, correction)
|
||
|
||
# Bulk insert výsledků
|
||
await db.executemany("""
|
||
INSERT INTO ems.planning_interval
|
||
(run_id, interval_start,
|
||
battery_setpoint_w, battery_soc_target_pct,
|
||
grid_setpoint_w,
|
||
ev1_setpoint_w, ev2_setpoint_w, ev1_via_bat_w, ev2_via_bat_w,
|
||
heat_pump_enabled, heat_pump_setpoint_w,
|
||
pv_a_curtailed_w, expected_cost_czk,
|
||
effective_buy_price, effective_sell_price)
|
||
VALUES ($1,$2,$3,$4,$5,$6,$7,$8,$9,$10,$11,$12,$13,$14,$15)
|
||
""", [
|
||
(run_id, r.interval_start,
|
||
r.battery_setpoint_w, r.battery_soc_target,
|
||
r.grid_setpoint_w,
|
||
r.ev1_setpoint_w, r.ev2_setpoint_w, r.ev1_via_bat_w, r.ev2_via_bat_w,
|
||
r.heat_pump_enabled, r.heat_pump_setpoint_w,
|
||
r.pv_a_curtailed_w, r.expected_cost_czk,
|
||
r.effective_buy_price, r.effective_sell_price)
|
||
for r in results
|
||
])
|
||
|
||
# Aktivovat nový plán, supersede předchozí
|
||
await db.execute("""
|
||
UPDATE ems.planning_run SET status = 'superseded'
|
||
WHERE site_id = $1 AND status = 'active' AND id <> $2
|
||
""", site_id, run_id)
|
||
|
||
await db.execute(
|
||
"UPDATE ems.planning_run SET status = 'active' WHERE id = $1", run_id
|
||
)
|
||
|
||
return run_id
|