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 for adding variables, constraints, and objective function terms
	# related to the binary commitment, startup and shutdown decisions of units
	function _add_unit_commitment!(
	model::JuMP.Model,
	g::ThermalUnit,
	formulation::Formulation,
	)
	if !all(g.must_run) && any(g.must_run)
	error("Partially must-run units are not currently supported")
	end
	if g.initial_power === nothing \|\| g.initial_status === nothing
	error("Initial conditions for $(g.name) must be provided")
	end

	# Variables
	_add_startup_shutdown_vars!(model, g)
	_add_status_vars!(model, g, formulation.status_vars)

	# Constraints and objective function
	_add_min_uptime_downtime_eqs!(model, g)
	_add_startup_cost_eqs!(model, g, formulation.startup_costs)
	_add_status_eqs!(model, g, formulation.status_vars)
	_add_commitment_status_eqs!(model, g)
	return
	end

	# Function for adding variables, constraints, and objective function terms
	# related to the continuous dispatch decisions of units
	function _add_unit_dispatch!(
	model::JuMP.Model,
	g::ThermalUnit,
	formulation::Formulation,
	sc::UnitCommitmentScenario,
	)

	# Variables
	_add_production_vars!(model, g, formulation.prod_vars, sc)
	_add_spinning_reserve_vars!(model, g, sc)
	_add_flexiramp_reserve_vars!(model, g, sc)

	# Constraints and objective function
	_add_net_injection_eqs!(model, g, sc)
	# [1]
	# _add_production_limit_eqs!(model, g, formulation.prod_vars, sc)
	# [1]
	_add_production_limit_eqs!(model, g, formulation.prod_vars, formulation.power_trajectories, sc)
	_add_production_piecewise_linear_eqs!(
	model,
	g,
	formulation.prod_vars,
	formulation.pwl_costs,
	formulation.status_vars,
	sc,
	)
	_add_ramp_eqs!(
	model,
	g,
	formulation.prod_vars,
	formulation.ramping,
	formulation.status_vars,
	sc,
	)
	_add_power_trajectory_eqs!(
	model,
	g,
	formulation.prod_vars,
	formulation.power_trajectories,
	formulation.status_vars,
	sc,
	)
	_add_startup_shutdown_limit_eqs!(model, g, sc)
	return
	end

	_is_initially_on(g::ThermalUnit)::Float64 = (g.initial_status > 0 ? 1.0 : 0.0)

	function _add_spinning_reserve_vars!(
	model::JuMP.Model,
	g::ThermalUnit,
	sc::UnitCommitmentScenario,
	)::Nothing
	reserve = _init(model, :reserve)
	reserve_shortfall = _init(model, :reserve_shortfall)
	for r in g.reserves
	r.type == "spinning" \|\| continue
	for t in 1:model[:instance].time
	reserve[sc.name, r.name, g.name, t] =
	@variable(model, lower_bound = 0, base_name = "reserve_$(sc.name)_$(r.name)_$(g.name)_$(t)")
	if (sc.name, r.name, t) ∉ keys(reserve_shortfall)
	reserve_shortfall[sc.name, r.name, t] =
	@variable(model, lower_bound = 0, base_name = "reserve_shortfall_$(sc.name)_$(r.name)_$(t)")
	if r.shortfall_penalty < 0
	set_upper_bound(reserve_shortfall[sc.name, r.name, t], 0.0)
	end
	end
	end
	end
	return
	end

	function _add_flexiramp_reserve_vars!(
	model::JuMP.Model,
	g::ThermalUnit,
	sc::UnitCommitmentScenario,
	)::Nothing
	upflexiramp = _init(model, :upflexiramp)
	upflexiramp_shortfall = _init(model, :upflexiramp_shortfall)
	mfg = _init(model, :mfg)
	dwflexiramp = _init(model, :dwflexiramp)
	dwflexiramp_shortfall = _init(model, :dwflexiramp_shortfall)
	for t in 1:model[:instance].time
	# maximum feasible generation, \bar{g_{its}} in Wang & Hobbs (2016)
	mfg[sc.name, g.name, t] = @variable(model, lower_bound = 0, base_name = "mfg_$(sc.name)_$(g.name)_$(t)")
	for r in g.reserves
	r.type == "flexiramp" \|\| continue
	upflexiramp[sc.name, r.name, g.name, t] = @variable(model) # up-flexiramp, ur_{it} in Wang & Hobbs (2016)
	dwflexiramp[sc.name, r.name, g.name, t] = @variable(model) # down-flexiramp, dr_{it} in Wang & Hobbs (2016)
	if (sc.name, r.name, t) ∉ keys(upflexiramp_shortfall)
	upflexiramp_shortfall[sc.name, r.name, t] =
	@variable(model, lower_bound = 0, base_name = "upflexiramp_shortfall_$(sc.name)_$(r.name)_$(t)")
	dwflexiramp_shortfall[sc.name, r.name, t] =
	@variable(model, lower_bound = 0, base_name = "dwflexiramp_shortfall_$(sc.name)_$(r.name)_$(t)")
	if r.shortfall_penalty < 0
	set_upper_bound(
	upflexiramp_shortfall[sc.name, r.name, t],
	0.0,
	)
	set_upper_bound(
	dwflexiramp_shortfall[sc.name, r.name, t],
	0.0,
	)
	end
	end
	end
	end
	return
	end

	function _add_startup_shutdown_vars!(model::JuMP.Model, g::ThermalUnit)::Nothing
	startup = _init(model, :startup)
	for t in 1:model[:instance].time
	for s in 1:length(g.startup_categories)
	startup[g.name, t, s] = @variable(model, binary = true, base_name = "startup_$(g.name)_$(t)_$(s)")
	end
	end
	return
	end

	function _add_startup_shutdown_limit_eqs!(
	model::JuMP.Model,
	g::ThermalUnit,
	sc::UnitCommitmentScenario,
	)::Nothing
	eq_shutdown_limit = _init(model, :eq_shutdown_limit)
	eq_startup_limit = _init(model, :eq_startup_limit)
	is_on = model[:is_on]
	prod_above = model[:prod_above]
	reserve = _total_reserves(model, g, sc)
	switch_off = model[:switch_off]
	switch_on = model[:switch_on]
	T = model[:instance].time
	for t in 1:T
	# Startup limit
	eq_startup_limit[sc.name, g.name, t] = @constraint(
	model,
	prod_above[sc.name, g.name, t] + reserve[t] <=
	(g.max_power[t] - g.min_power[t]) * is_on[g.name, t] -
	max(0, g.max_power[t] - g.startup_limit) * switch_on[g.name, t]
	)
	# Shutdown limit
	if g.initial_power > g.shutdown_limit
	eq_shutdown_limit[sc.name, g.name, 0] =
	@constraint(model, switch_off[g.name, 1] <= 0)
	end
	if t < T
	eq_shutdown_limit[sc.name, g.name, t] = @constraint(
	model,
	prod_above[sc.name, g.name, t] <=
	(g.max_power[t] - g.min_power[t]) * is_on[g.name, t] -
	max(0, g.max_power[t] - g.shutdown_limit) *
	switch_off[g.name, t+1]
	)
	end
	end
	return
	end

	function _add_ramp_eqs!(
	model::JuMP.Model,
	g::ThermalUnit,
	formulation::RampingFormulation,
	sc::UnitCommitmentScenario,
	)::Nothing
	prod_above = model[:prod_above]
	reserve = _total_reserves(model, g, sc)
	eq_ramp_up = _init(model, :eq_ramp_up)
	eq_ramp_down = _init(model, :eq_ramp_down)
	for t in 1:model[:instance].time
	# Ramp up limit
	if t == 1
	if _is_initially_on(g) == 1
	eq_ramp_up[sc.name, g.name, t] = @constraint(
	model,
	prod_above[sc.name, g.name, t] + reserve[t] <=
	(g.initial_power - g.min_power[t]) + g.ramp_up_limit
	)
	end
	else
	eq_ramp_up[sc.name, g.name, t] = @constraint(
	model,
	prod_above[sc.name, g.name, t] + reserve[t] <=
	prod_above[sc.name, g.name, t-1] + g.ramp_up_limit
	)
	end

	# Ramp down limit
	if t == 1
	if _is_initially_on(g) == 1
	eq_ramp_down[sc.name, g.name, t] = @constraint(
	model,
	prod_above[sc.name, g.name, t] >=
	(g.initial_power - g.min_power[t]) - g.ramp_down_limit
	)
	end
	else
	eq_ramp_down[sc.name, g.name, t] = @constraint(
	model,
	prod_above[sc.name, g.name, t] >=
	prod_above[sc.name, g.name, t-1] - g.ramp_down_limit
	)
	end
	end
	end

	function _add_power_trajectory_eqs!(
	model::JuMP.Model,
	g::ThermalUnit,
	formulation_prod_vars::ProductionVarsFormulation,
	formulation_power_trajectories::Nothing,
	formulation_status_vars::StatusVarsFormulation,
	sc::UnitCommitmentScenario,
	)::Nothing
	return
	end

	function _add_power_trajectory_eqs!(
	model::JuMP.Model,
	g::ThermalUnit,
	formulation_prod_vars::ProductionVarsFormulation,
	formulation_power_trajectories::PowerTrajectoriesFormulation,
	formulation_status_vars::StatusVarsFormulation,
	sc::UnitCommitmentScenario,
	)::Nothing
	T = model[:instance].time
	prod_above = model[:prod_above]
	is_on = model[:is_on]
	switch_on = model[:switch_on]
	switch_off = model[:switch_off]

	eq_traj_lower_startup = _init(model, :eq_traj_lower_startup)
	eq_traj_lower_shutdown = _init(model, :eq_traj_lower_shutdown)
	eq_traj_upper_startup = _init(model, :eq_traj_upper_startup)
	eq_traj_upper_shutdown = _init(model, :eq_traj_upper_shutdown)
	eq_traj_ramp_up = _init(model, :eq_traj_ramp_up)
	eq_traj_ramp_down = _init(model, :eq_traj_ramp_down)

	UD = hasproperty(g, :startup_curve) ? length(g.startup_curve) : 0
	DD = hasproperty(g, :shutdown_curve) ? length(g.shutdown_curve) : 0
	P_U = hasproperty(g, :startup_curve) ? g.startup_curve : zeros(UD)
	P_D = hasproperty(g, :shutdown_curve) ? g.shutdown_curve : zeros(DD)

	for t in 1:T
	set_lower_bound(prod_above[sc.name, g.name, t], -g.min_power[t])
	end

	for t in 1:T
	# sum_{i=1}^{UD} y(k-i+1)
	sum_y_UD = @expression(model, sum(switch_on[g.name, t-i+1] for i in 1:UD if t-i+1 >= 1; init=0))
	# sum_{i=1}^{DD} z(k+i)
	sum_z_DD = @expression(model, sum(switch_off[g.name, t+i] for i in 1:DD if t+i <= T; init=0))

	# [v(k) - sum_z - sum_y]
	base_status_term = @expression(model, is_on[g.name, t] - sum_z_DD - sum_y_UD)

	# [1] & [2]
	start_power_above = @expression(model, sum((P_U[i] - g.min_power[t]) * switch_on[g.name, t-i+1] for i in 1:UD if t-i+1 >= 1; init=0))
	shut_power_above = @expression(model, sum((P_D[i] - g.min_power[t]) * switch_off[g.name, t+DD-i+1] for i in 1:DD if t+DD-i+1 >= 1 && t+DD-i+1 <= T; init=0))

	eq_traj_lower_startup[sc.name, g.name, t] = @constraint(
	model,
	prod_above[sc.name, g.name, t] >=
	start_power_above - g.min_power[t] * sum_z_DD
	)
	eq_traj_lower_shutdown[sc.name, g.name, t] = @constraint(
	model,
	prod_above[sc.name, g.name, t] >=
	shut_power_above - g.min_power[t] * sum_y_UD
	)

	# [3]
	eq_traj_upper_startup[sc.name, g.name, t] = @constraint(
	model,
	prod_above[sc.name, g.name, t] <=
	start_power_above + (g.max_power[t] - g.min_power[t]) * (is_on[g.name, t] - sum_y_UD)
	)

	# [4]
	eq_traj_upper_shutdown[sc.name, g.name, t] = @constraint(
	model,
	prod_above[sc.name, g.name, t] <=
	shut_power_above + (g.max_power[t] - g.min_power[t]) * (is_on[g.name, t] - sum_z_DD)
	)

	# [5,6]
	if t == 1
	eq_traj_ramp_up[sc.name, g.name, t] = @constraint(
	model,
	prod_above[sc.name, g.name, t] - (g.initial_power - g.min_power[t]) <=
	g.max_power[t] * sum_y_UD + g.ramp_up_limit * (is_on[g.name, t] - sum_y_UD)
	)

	# z(k+i-1)
	sum_z_DD_prev = @expression(model, sum(switch_off[g.name, t+i-1] for i in 1:DD if t+i-1 <= T && t+i-1 >= 1; init=0))
	eq_traj_ramp_down[sc.name, g.name, t] = @constraint(
	model,
	(g.initial_power - g.min_power[t]) - prod_above[sc.name, g.name, t] <=
	g.max_power[t] * sum_z_DD_prev + g.ramp_down_limit * (_is_initially_on(g) - sum_z_DD_prev)
	)
	else
	eq_traj_ramp_up[sc.name, g.name, t] = @constraint(
	model,
	prod_above[sc.name, g.name, t] - prod_above[sc.name, g.name, t-1] <=
	g.max_power[t] * sum_y_UD + g.ramp_up_limit * (is_on[g.name, t] - sum_y_UD)
	)

	sum_z_DD_prev = @expression(model, sum(switch_off[g.name, t+i-1] for i in 1:DD if t+i-1 <= T && t+i-1 >= 1; init=0))
	eq_traj_ramp_down[sc.name, g.name, t] = @constraint(
	model,
	prod_above[sc.name, g.name, t-1] - prod_above[sc.name, g.name, t] <=
	g.max_power[t] * sum_z_DD_prev + g.ramp_down_limit * (is_on[g.name, t-1] - sum_z_DD_prev)
	)
	end
	end
	return
	end

	function _add_min_uptime_downtime_eqs!(
	model::JuMP.Model,
	g::ThermalUnit,
	)::Nothing
	is_on = model[:is_on]
	switch_off = model[:switch_off]
	switch_on = model[:switch_on]
	eq_min_uptime = _init(model, :eq_min_uptime)
	eq_min_downtime = _init(model, :eq_min_downtime)
	T = model[:instance].time
	for t in 1:T
	# Minimum up-time
	eq_min_uptime[g.name, t] = @constraint(
	model,
	sum(switch_on[g.name, i] for i in (t-g.min_uptime+1):t if i >= 1) <= is_on[g.name, t]
	)
	# Minimum down-time
	eq_min_downtime[g.name, t] = @constraint(
	model,
	sum(
	switch_off[g.name, i] for i in (t-g.min_downtime+1):t if i >= 1
	) <= 1 - is_on[g.name, t]
	)
	# Minimum up/down-time for initial periods
	if t == 1
	if g.initial_status > 0
	eq_min_uptime[g.name, 0] = @constraint(
	model,
	sum(
	switch_off[g.name, i] for
	i in 1:(g.min_uptime-g.initial_status) if i <= T
	) == 0
	)
	else
	eq_min_downtime[g.name, 0] = @constraint(
	model,
	sum(
	switch_on[g.name, i] for
	i in 1:(g.min_downtime+g.initial_status) if i <= T
	) == 0
	)
	end
	end
	end
	end

	function _add_commitment_status_eqs!(model::JuMP.Model, g::ThermalUnit)::Nothing
	is_on = model[:is_on]
	T = model[:instance].time
	eq_commitment_status = _init(model, :eq_commitment_status)
	for t in 1:T
	if g.commitment_status[t] !== nothing
	eq_commitment_status[g.name, t] = @constraint(
	model,
	is_on[g.name, t] == (g.commitment_status[t] ? 1.0 : 0.0)
	)
	end
	end
	return
	end

	function _add_net_injection_eqs!(
	model::JuMP.Model,
	g::ThermalUnit,
	sc::UnitCommitmentScenario,
	)::Nothing
	expr_net_injection = model[:expr_net_injection]
	for t in 1:model[:instance].time
	# Add to net injection expression
	add_to_expression!(
	expr_net_injection[sc.name, g.bus.name, t],
	model[:prod_above][sc.name, g.name, t],
	1.0,
	)
	add_to_expression!(
	expr_net_injection[sc.name, g.bus.name, t],
	model[:is_on][g.name, t],
	g.min_power[t],
	)
	end
	end

	function _total_reserves(model, g, sc)::Vector
	T = model[:instance].time
	reserve = [0.0 for _ in 1:T]
	spinning_reserves = [r for r in g.reserves if r.type == "spinning"]
	if !isempty(spinning_reserves)
	reserve += [
	sum(
	model[:reserve][sc.name, r.name, g.name, t] for
	r in spinning_reserves
	) for t in 1:model[:instance].time
	]
	end
	return reserve
	end

	function _actual_power(
	model::JuMP.Model,
	g::ThermalUnit,
	sc::UnitCommitmentScenario,
	t::Int,
	)::AffExpr
	prod_above = model[:prod_above]
	is_on = model[:is_on]
	return prod_above[sc.name, g.name, t] + g.min_power[t] * is_on[g.name, t]
	end

	function _in_startup_process(
	model::JuMP.Model,
	g::ThermalUnit,
	t::Int,
	)::AffExpr
	switch_on = model[:switch_on]
	UD = length(g.startup_curve)
	T = model[:instance].time
	return sum(
	switch_on[g.name, t - i + 1]
	for i in 1:UD if (t - i + 1) >= 1;
	init = AffExpr(0.0),
	)
	end

	function _in_shutdown_process(
	model::JuMP.Model,
	g::ThermalUnit,
	t::Int,
	)::AffExpr
	switch_off = model[:switch_off]
	DD = length(g.shutdown_curve)
	T = model[:instance].time
	return sum(
	switch_off[g.name, t + i]
	for i in 1:DD if (t + i) <= T;
	init = AffExpr(0.0),
	)
	end