Datasets:

EridanusQ
/

UnitCommitment_Trajectory

	# UnitCommitment.jl: Optimization Package for Security-Constrained Unit Commitment
	# Copyright (C) 2020, UChicago Argonne, LLC. All rights reserved.
	# Released under the modified BSD license. See COPYING.md for more details.

	function _add_ramp_eqs!(
	model::JuMP.Model,
	g::ThermalUnit,
	formulation_prod_vars::Gar1962.ProdVars,
	formulation_ramping::DamKucRajAta2016.Ramping,
	formulation_status_vars::Gar1962.StatusVars,
	sc::UnitCommitmentScenario,
	)::Nothing
	# TODO: Move upper case constants to model[:instance]
	RESERVES_WHEN_START_UP = true
	RESERVES_WHEN_RAMP_UP = true
	RESERVES_WHEN_RAMP_DOWN = true
	RESERVES_WHEN_SHUT_DOWN = true
	known_initial_conditions = true
	is_initially_on = (g.initial_status > 0)
	SU = g.startup_limit
	SD = g.shutdown_limit
	RU = g.ramp_up_limit
	RD = g.ramp_down_limit
	gn = g.name
	eq_str_ramp_down = _init(model, :eq_str_ramp_down)
	eq_str_ramp_up = _init(model, :eq_str_ramp_up)
	reserve = _total_reserves(model, g, sc)

	# Gar1962.ProdVars
	prod_above = model[:prod_above]

	# Gar1962.StatusVars
	is_on = model[:is_on]
	switch_off = model[:switch_off]
	switch_on = model[:switch_on]

	for t in 1:model[:instance].time
	time_invariant =
	(t > 1) ? (abs(g.min_power[t] - g.min_power[t-1]) < 1e-7) : true

	# if t > 1 && !time_invariant
	# @warn(
	# "Ramping according to Damcı-Kurt et al. (2016) requires " *
	# "time-invariant minimum power. This does not hold for " *
	# "generator $(gn): min_power[$t] = $(g.min_power[t]); " *
	# "min_power[$(t-1)] = $(g.min_power[t-1]). Reverting to " *
	# "Arroyo and Conejo (2000) formulation for this generator.",
	# )
	# end

	max_prod_this_period =
	prod_above[sc.name, gn, t] +
	(RESERVES_WHEN_START_UP \|\| RESERVES_WHEN_RAMP_UP ? reserve[t] : 0.0)
	min_prod_last_period = 0.0
	if t > 1 && time_invariant
	min_prod_last_period = prod_above[sc.name, gn, t-1]

	# Equation (35) in Kneuven et al. (2020)
	# Sparser version of (24)
	eq_str_ramp_up[sc.name, gn, t] = @constraint(
	model,
	max_prod_this_period - min_prod_last_period <=
	(SU - g.min_power[t] - RU) * switch_on[gn, t] +
	RU * is_on[gn, t]
	)
	elseif (t == 1 && is_initially_on) \|\| (t > 1 && !time_invariant)
	if t > 1
	min_prod_last_period =
	prod_above[sc.name, gn, t-1] +
	g.min_power[t-1] * is_on[gn, t-1]
	else
	min_prod_last_period = max(g.initial_power, 0.0)
	end

	# Add the min prod at time t back in to max_prod_this_period to get _total_ production
	# (instead of using the amount above minimum, as min prod for t < 1 is unknown)
	max_prod_this_period += g.min_power[t] * is_on[gn, t]

	# Modified version of equation (35) in Kneuven et al. (2020)
	# Equivalent to (24)
	eq_str_ramp_up[sc.name, gn, t] = @constraint(
	model,
	max_prod_this_period - min_prod_last_period <=
	(SU - RU) * switch_on[gn, t] + RU * is_on[gn, t]
	)
	end

	max_prod_last_period =
	min_prod_last_period + (
	t > 1 && (RESERVES_WHEN_SHUT_DOWN \|\| RESERVES_WHEN_RAMP_DOWN) ?
	reserve[t-1] : 0.0
	)
	min_prod_this_period = prod_above[sc.name, gn, t]
	on_last_period = 0.0
	if t > 1
	on_last_period = is_on[gn, t-1]
	elseif (known_initial_conditions && g.initial_status > 0)
	on_last_period = 1.0
	end

	if t > 1 && time_invariant
	# Equation (36) in Kneuven et al. (2020)
	eq_str_ramp_down[sc.name, gn, t] = @constraint(
	model,
	max_prod_last_period - min_prod_this_period <=
	(SD - g.min_power[t] - RD) * switch_off[gn, t] +
	RD * on_last_period
	)
	elseif (t == 1 && is_initially_on) \|\| (t > 1 && !time_invariant)
	# Add back in min power
	min_prod_this_period += g.min_power[t] * is_on[gn, t]

	# Modified version of equation (36) in Kneuven et al. (2020)
	# Equivalent to (25)
	eq_str_ramp_down[sc.name, gn, t] = @constraint(
	model,
	max_prod_last_period - min_prod_this_period <=
	(SD - RD) * switch_off[gn, t] + RD * on_last_period
	)
	end
	end
	end