add flexiramp

4 years ago · a3a71ff5a9
parent 5e2cdb9e0c
commit a3a71ff5a9
13 changed files with 338 additions and 15 deletions
--- a/.DS_Store
+++ b/.DS_Store
--- a/docs/format.md
+++ b/docs/format.md
@ -36,6 +36,7 @@ This section describes system-wide parameters, such as power balance and reserve
 | `Time step (min)` | Length of each time step (in minutes). Must be a divisor of 60 (e.g. 60, 30, 20, 15, etc). | `60` | N
 | `Power balance penalty ($/MW)` | Penalty for system-wide shortage or surplus in production (in $/MW). This is charged per time step. For example, if there is a shortage of 1 MW for three time steps, three times this amount will be charged. | `1000.0` | Y
 | `Reserve shortfall penalty ($/MW)` | Penalty for system-wide shortage in meeting reserve requirements (in $/MW). This is charged per time step. Negative value implies reserve constraints must always be satisfied. | `-1` | Y
 | `Flexiramp penalty ($/MW)` | Penalty for system-wide shortage in meeting flexible ramping product requirements (in $/MW). This is charged per time step. | `500` | Y
 #### Example
@ -44,7 +45,8 @@ This section describes system-wide parameters, such as power balance and reserve
    "Parameters": {
        "Time horizon (h)": 4,
        "Power balance penalty ($/MW)": 1000.0,
-        "Reserve shortfall penalty ($/MW)": -1.0
+        "Reserve shortfall penalty ($/MW)": -1.0,
        "Flexiramp penalty ($/MW)": 100.0
    }
 }
 ```
@ -97,6 +99,8 @@ This section describes all generators in the system, including thermal units, re
 | `Initial power (MW)`  | Amount of power the generator at time step `-1`, immediately before the planning horizon starts. | Required | N
 | `Must run?`               | If `true`, the generator should be committed, even if that is not economical (Boolean). | `false` | Y
 | `Provides spinning reserves?`    | If `true`, this generator may provide spinning reserves (Boolean). | `true` | Y
 | `Provides flexible capacity?`    | If `true`, this generator may provide flexible ramping product (Boolean). | `true` | Y
 #### Production costs and limits
@ -136,6 +140,7 @@ Note that this curve also specifies the production limits. Specifically, the fir
            "Initial status (h)": 12,
            "Must run?": false,
            "Provides spinning reserves?": true,
            "Provides flexible capacity?": false,
        },
        "gen2": {
            "Bus": "b5",
@ -206,14 +211,16 @@ This section describes the characteristics of transmission system, such as its t
 ### Reserves
-This section describes the hourly amount of operating reserves required.
+This section describes the hourly amount of reserves required.
 | Key                   | Description                                        | Default   |  Time series?
 | :-------------------- | :------------------------------------------------- | --------- |  :----:
 | `Spinning (MW)`       | Minimum amount of system-wide spinning reserves (in MW). Only generators which are online may provide this reserve. | `0.0` | Y
 | `Up-flexiramp (MW)`       | Minimum amount of system-wide upward flexible ramping product (in MW). Only generators which are online may provide this reserve. | `0.0` | Y
 | `Down-flexiramp (MW)`       | Minimum amount of system-wide downward flexible ramping product (in MW). Only generators which are online may provide this reserve. | `0.0` | Y
-#### Example
+#### Example 1
 ```json
 {
@ -228,6 +235,27 @@ This section describes the hourly amount of operating reserves required.
 }
 ```
 #### Example 2
 ```json
 {
    "Reserves": {
        "up-flexiramp (MW)": [
            20.31042,
            23.65273,
            27.41784,
            25.34057
        ],
         "down-flexiramp (MW)": [
            19.41546,
            21.45377,
            23.53402,
            24.80973
        ]
    }
 }
 ```
 ### Contingencies
 This section describes credible contingency scenarios in the optimization, such as the loss of a transmission line or generator.
@ -287,6 +315,7 @@ Current limitations
 -------------------
 * All reserves are system-wide. Zonal reserves are not currently supported.
 * Upward and downward flexible ramping products can only be acquired under the WanHob2016 formulation, which does not support spinning reserves. 
 * Network topology remains the same for all time periods
 * Only N-1 transmission contingencies are supported. Generator contingencies are not currently supported.
 * Time-varying minimum production amounts are not currently compatible with ramp/startup/shutdown limits.
--- a/src/UnitCommitment.jl
+++ b/src/UnitCommitment.jl
@ -16,6 +16,7 @@ include("model/formulations/KnuOstWat2018/structs.jl")
 include("model/formulations/MorLatRam2013/structs.jl")
 include("model/formulations/PanGua2016/structs.jl")
 include("solution/methods/XavQiuWanThi2019/structs.jl")
 include("model/formulations/WanHob2016/structs.jl")
 include("import/egret.jl")
 include("instance/read.jl")
@ -36,6 +37,7 @@ include("model/formulations/KnuOstWat2018/pwlcosts.jl")
 include("model/formulations/MorLatRam2013/ramp.jl")
 include("model/formulations/MorLatRam2013/scosts.jl")
 include("model/formulations/PanGua2016/ramp.jl")
 include("model/formulations/WanHob2016/ramp.jl")
 include("model/jumpext.jl")
 include("solution/fix.jl")
 include("solution/methods/XavQiuWanThi2019/enforce.jl")
--- a/src/instance/read.jl
+++ b/src/instance/read.jl
@ -108,6 +108,11 @@ function _from_json(json; repair = true)
        json["Parameters"]["Power balance penalty (\$/MW)"],
        default = [1000.0 for t in 1:T],
    )
    # Penalty price for shortage in meeting system-wide flexiramp requirements
    flexiramp_shortfall_penalty = timeseries(
        json["Parameters"]["Flexiramp penalty (\$/MW)"],
        default = [500.0 for t in 1:T],
    )
    shortfall_penalty = timeseries(
        json["Parameters"]["Reserve shortfall penalty (\$/MW)"],
        default = [-1.0 for t in 1:T],
@ -200,6 +205,10 @@ function _from_json(json; repair = true)
                dict["Provides spinning reserves?"],
                default = [true for t in 1:T],
            ),
            timeseries(
                dict["Provides flexible capacity?"],
                default = [true for t in 1:T],
            ),
            startup_categories,
        )
        push!(bus.units, unit)
@ -207,11 +216,15 @@ function _from_json(json; repair = true)
        push!(units, unit)
    end
-    # Read reserves
+    # Read spinning, up-flexiramp, and down-flexiramp reserve requirements
-    reserves = Reserves(zeros(T))
+    reserves = Reserves(zeros(T), zeros(T), zeros(T))
    if "Reserves" in keys(json)
      reserves.spinning =
          timeseries(json["Reserves"]["Spinning (MW)"], default = zeros(T))
      reserves.upflexiramp =
          timeseries(json["Reserves"]["Up-flexiramp (MW)"], default = zeros(T))
      reserves.dwflexiramp =
          timeseries(json["Reserves"]["Down-flexiramp (MW)"], default = zeros(T))
  end
    # Read transmission lines
@ -287,6 +300,7 @@ function _from_json(json; repair = true)
        price_sensitive_loads = loads,
        reserves = reserves,
        shortfall_penalty = shortfall_penalty,
        flexiramp_shortfall_penalty = flexiramp_shortfall_penalty,
        time = T,
        units_by_name = Dict(g.name => g for g in units),
        units = units,
--- a/src/instance/structs.jl
+++ b/src/instance/structs.jl
@ -37,6 +37,7 @@ mutable struct Unit
    initial_status::Union{Int,Nothing}
    initial_power::Union{Float64,Nothing}
    provides_spinning_reserves::Vector{Bool}
    provides_flexiramp_reserves::Vector{Bool} # binary variable indicating whether the unit provides flexiramp
    startup_categories::Vector{StartupCategory}
 end
@ -54,6 +55,8 @@ end
 mutable struct Reserves
    spinning::Vector{Float64}
    upflexiramp::Vector{Float64} # up-flexiramp reserve requirements
    dwflexiramp::Vector{Float64} # down-flexiramp reserve requirements
 end
 mutable struct Contingency
@ -81,6 +84,7 @@ Base.@kwdef mutable struct UnitCommitmentInstance
    price_sensitive_loads::Vector{PriceSensitiveLoad}
    reserves::Reserves
    shortfall_penalty::Vector{Float64}
    flexiramp_shortfall_penalty::Vector{Float64} # penalty price for flexiramp shortfall
    time::Int
    units_by_name::Dict{AbstractString,Unit}
    units::Vector{Unit}
--- a/src/model/.DS_Store
+++ b/src/model/.DS_Store
--- a/src/model/build.jl
+++ b/src/model/build.jl
@ -32,6 +32,14 @@ function build_model(;
    formulation = Formulation(),
    variable_names::Bool = false,
 )::JuMP.Model
    if formulation.ramping ==WanHob2016.Ramping() && instance.reserves.spinning!=zeros(instance.time)
        error("Spinning reserves are not supported by the WanHob2016 ramping formulation")
    end
    @show formulation.ramping
    if formulation.ramping !== WanHob2016.Ramping() && (instance.reserves.upflexiramp!=zeros(instance.time) || instance.reserves.dwflexiramp!=zeros(instance.time))
        error("Flexiramp is supported only by the WanHob2016 ramping formulation")
    end
    @info "Building model..."
    time_model = @elapsed begin
        model = Model()
--- a/src/model/formulations/WanHob2016/ramp.jl
+++ b/src/model/formulations/WanHob2016/ramp.jl
@ -0,0 +1,152 @@
 # UnitCommitmentFL.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_flexiramp_vars!(model::JuMP.Model, g::Unit)::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[g.name,t]=@variable(model, lower_bound = 0)
        if g.provides_flexiramp_reserves[t]
            upflexiramp[g.name, t] = @variable(model) # up-flexiramp, ur_{it} in Wang & Hobbs (2016)
            dwflexiramp[g.name, t] = @variable(model) # down-flexiramp, dr_{it} in Wang & Hobbs (2016)
        else
            upflexiramp[g.name, t] = 0.0
            dwflexiramp[g.name, t] = 0.0
        end
        upflexiramp_shortfall[t] =
            (model[:instance].flexiramp_shortfall_penalty[t] >= 0) ?
            @variable(model, lower_bound = 0) : 0.0
        dwflexiramp_shortfall[t] =
            (model[:instance].flexiramp_shortfall_penalty[t] >= 0) ?
            @variable(model, lower_bound = 0) : 0.0
    end
    return
 end
 function _add_ramp_eqs!(
    model::JuMP.Model,
    g::Unit,
    formulation_prod_vars::Gar1962.ProdVars,
    formulation_ramping::WanHob2016.Ramping,
    formulation_status_vars::Gar1962.StatusVars,
 )::Nothing
    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
    minp=g.min_power
    maxp=g.max_power
    initial_power=g.initial_power
    is_on = model[:is_on]
    prod_above = model[:prod_above]
    upflexiramp=model[:upflexiramp]
    dwflexiramp=model[:dwflexiramp]
    mfg=model[:mfg]
    for t in 1:model[:instance].time
        @constraint(model, prod_above[gn, t] + (is_on[gn,t]*minp[t]) 
            <=mfg[gn,t]) # Eq. (19) in Wang & Hobbs (2016)
        @constraint(model, mfg[gn,t]<= is_on[gn,t]* maxp[t]) # Eq. (22) in Wang & Hobbs (2016)
        if t!=model[:instance].time 
            @constraint(model, minp[t] * (is_on[gn,t+1]+is_on[gn,t]-1) <= 
                prod_above[gn, t] - dwflexiramp[gn,t] +(is_on[gn,t]*minp[t]) 
                ) # first inequality of Eq. (20) in Wang & Hobbs (2016)
            @constraint(model, prod_above[gn, t] - dwflexiramp[gn,t] + (is_on[gn,t]*minp[t]) <=
                mfg[gn,t+1]
                + (maxp[t] * (1-is_on[gn,t+1]))
                ) # second inequality of Eq. (20) in Wang & Hobbs (2016)
            @constraint(model, minp[t] * (is_on[gn,t+1]+is_on[gn,t]-1) <=
                prod_above[gn, t] + upflexiramp[gn,t] + (is_on[gn,t]*minp[t])
                ) # first inequality of Eq. (21) in Wang & Hobbs (2016)
            @constraint(model, prod_above[gn, t] + upflexiramp[gn,t] +(is_on[gn,t]*minp[t]) <=
                mfg[gn,t+1] + (maxp[t] * (1-is_on[gn,t+1]))
                ) # second inequality of Eq. (21) in Wang & Hobbs (2016)
            if t!=1
                @constraint(model, mfg[gn,t]<=prod_above[gn,t-1] + (is_on[gn,t-1]*minp[t])
                    + (RU * is_on[gn,t-1])
                    + (SU*(is_on[gn,t] - is_on[gn,t-1]))
                    + maxp[t] * (1-is_on[gn,t])
                    ) # Eq. (23) in Wang & Hobbs (2016)
                @constraint(model, (prod_above[gn,t-1] + (is_on[gn,t-1]*minp[t])) 
                    - (prod_above[gn,t] + (is_on[gn,t]*minp[t]))
                    <= RD * is_on[gn,t] 
                    + SD * (is_on[gn,t-1] - is_on[gn,t])
                    + maxp[t] * (1-is_on[gn,t-1])
                    ) # Eq. (25) in Wang & Hobbs (2016)
            else
                @constraint(model, mfg[gn,t]<=initial_power
                    + (RU * is_initially_on)
                    + (SU*(is_on[gn,t] - is_initially_on))
                    + maxp[t] * (1-is_on[gn,t])
                    ) # Eq. (23) in Wang & Hobbs (2016) for the first time period
                @constraint(model, initial_power  
                    - (prod_above[gn,t] + (is_on[gn,t]*minp[t]))
                    <= RD * is_on[gn,t] 
                    + SD * (is_initially_on - is_on[gn,t])
                    + maxp[t] * (1-is_initially_on)
                    ) # Eq. (25) in Wang & Hobbs (2016) for the first time period
            end
            @constraint(model, mfg[gn,t]<=
                (SD*(is_on[gn,t] - is_on[gn,t+1]))
                + (maxp[t] * is_on[gn,t+1])
                ) # Eq. (24) in Wang & Hobbs (2016)
            @constraint(model, -RD * is_on[gn,t+1]
                -SD * (is_on[gn,t]-is_on[gn,t+1])
                -maxp[t] * (1-is_on[gn,t]) 
                <= upflexiramp[gn,t]
                ) # first inequality of Eq. (26) in Wang & Hobbs (2016)
            @constraint(model, upflexiramp[gn,t] <=
                RU * is_on[gn,t]
                + SU * (is_on[gn,t+1]-is_on[gn,t])
                + maxp[t] * (1-is_on[gn,t+1])
                ) # second inequality of Eq. (26) in Wang & Hobbs (2016)
            @constraint(model, -RU * is_on[gn,t]
                -SU * (is_on[gn,t+1]-is_on[gn,t])
                -maxp[t] * (1-is_on[gn,t+1])
                <= dwflexiramp[gn,t] 
                ) # first inequality of Eq. (27) in Wang & Hobbs (2016)
            @constraint(model, dwflexiramp[gn,t] <=
                RD * is_on[gn,t+1]
                + SD * (is_on[gn,t]-is_on[gn,t+1])
                + maxp[t] * (1-is_on[gn,t])
                ) # second inequality of Eq. (27) in Wang & Hobbs (2016)
            @constraint(model, -maxp[t] * is_on[gn,t]
                +minp[t] * is_on[gn,t+1]
                <= upflexiramp[gn,t]
                ) # first inequality of Eq. (28) in Wang & Hobbs (2016)
            @constraint(model, upflexiramp[gn,t] <=
                maxp[t] * is_on[gn,t+1]
                ) # second inequality of Eq. (28) in Wang & Hobbs (2016)
            @constraint(model, -maxp[t] * is_on[gn,t+1]
                <= dwflexiramp[gn,t]
                ) # first inequality of Eq. (29) in Wang & Hobbs (2016)
            @constraint(model, dwflexiramp[gn,t] <=
                (maxp[t] * is_on[gn,t])
                -(minp[t] * is_on[gn,t+1])
                ) # second inequality of Eq. (29) in Wang & Hobbs (2016)
        else
            @constraint(model, mfg[gn,t]<=prod_above[gn,t-1] + (is_on[gn,t-1]*minp[t])
                + (RU * is_on[gn,t-1])
                + (SU*(is_on[gn,t] - is_on[gn,t-1]))
                + maxp[t] * (1-is_on[gn,t])
                ) # Eq. (23) in Wang & Hobbs (2016) for the last time period
            @constraint(model, (prod_above[gn,t-1] + (is_on[gn,t-1]*minp[t])) 
                - (prod_above[gn,t] + (is_on[gn,t]*minp[t]))
                <= RD * is_on[gn,t] 
                + SD * (is_on[gn,t-1] - is_on[gn,t])
                + maxp[t] * (1-is_on[gn,t-1])
                ) # Eq. (25) in Wang & Hobbs (2016) for the last time period
        end
    end
 end
--- a/src/model/formulations/WanHob2016/structs.jl
+++ b/src/model/formulations/WanHob2016/structs.jl
@ -0,0 +1,18 @@
 # UnitCommitmentFL.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.
 """
 Formulation described in:
    B. Wang and B. F. Hobbs, "Real-Time Markets for Flexiramp: A Stochastic 
    Unit Commitment-Based Analysis," in IEEE Transactions on Power Systems, 
    vol. 31, no. 2, pp. 846-860, March 2016, doi: 10.1109/TPWRS.2015.2411268.
 """
 module WanHob2016
 import ..RampingFormulation
 struct Ramping <: RampingFormulation end
 end
--- a/src/model/formulations/base/system.jl
+++ b/src/model/formulations/base/system.jl
@ -5,6 +5,7 @@
 function _add_system_wide_eqs!(model::JuMP.Model)::Nothing
    _add_net_injection_eqs!(model)
    _add_reserve_eqs!(model)
    _add_flexiramp_eqs!(model) # Add system-wide flexiramp requirements
    return
 end
@ -54,3 +55,41 @@ function _add_reserve_eqs!(model::JuMP.Model)::Nothing
    end
    return
 end
 function _add_flexiramp_eqs!(model::JuMP.Model)::Nothing
     # Note: The flexpramp requirements in Wang & Hobbs (2016) are imposed as hard constraints 
    #       through Eq. (17) and Eq. (18). The constraints eq_min_upflexiramp[t] and eq_min_dwflexiramp[t] 
    #       provided below are modified versions of Eq. (17) and Eq. (18), respectively, in that   
    #       they include slack variables for flexiramp shortfall, which are penalized in the
    #       objective function.
    eq_min_upflexiramp = _init(model, :eq_min_upflexiramp)
    eq_min_dwflexiramp = _init(model, :eq_min_dwflexiramp)
    instance = model[:instance]
    for t in 1:instance.time
        flexiramp_shortfall_penalty = instance.flexiramp_shortfall_penalty[t]
        # Eq. (17) in Wang & Hobbs (2016)
        eq_min_upflexiramp[t] = @constraint(
            model,
            sum(model[:upflexiramp][g.name, t] for g in instance.units) +
            (flexiramp_shortfall_penalty >= 0 ? model[:upflexiramp_shortfall][t] : 0.0) >=
            instance.reserves.upflexiramp[t]
        )
        # Eq. (18) in Wang & Hobbs (2016)
        eq_min_dwflexiramp[t] = @constraint(
            model,
            sum(model[:dwflexiramp][g.name, t] for g in instance.units) +
            (flexiramp_shortfall_penalty >= 0 ? model[:dwflexiramp_shortfall][t] : 0.0) >=
            instance.reserves.dwflexiramp[t]
        )
        # Account for flexiramp shortfall contribution to objective
        if flexiramp_shortfall_penalty >= 0
            add_to_expression!(
                model[:obj],
                flexiramp_shortfall_penalty,
                (model[:upflexiramp_shortfall][t]+model[:dwflexiramp_shortfall][t]),
            )
        end
    end
    return
 end
--- a/src/model/formulations/base/unit.jl
+++ b/src/model/formulations/base/unit.jl
@ -13,6 +13,7 @@ function _add_unit!(model::JuMP.Model, g::Unit, formulation::Formulation)
    # Variables
    _add_production_vars!(model, g, formulation.prod_vars)
    _add_reserve_vars!(model, g)
    _add_flexiramp_vars!(model, g) # Add variables for flexiramp
    _add_startup_shutdown_vars!(model, g)
    _add_status_vars!(model, g, formulation.status_vars)
--- a/src/solution/solution.jl
+++ b/src/solution/solution.jl
@ -50,6 +50,26 @@ function solution(model::JuMP.Model)::OrderedDict
    sol["Is on"] = timeseries(model[:is_on], instance.units)
    sol["Switch on"] = timeseries(model[:switch_on], instance.units)
    sol["Switch off"] = timeseries(model[:switch_off], instance.units)
    if instance.reserves.upflexiramp != zeros(T) || instance.reserves.dwflexiramp != zeros(T)
        # Report flexiramp solutions only if either of the up-flexiramp and  
        # down-flexiramp requirements is not a default array of zeros
        sol["Up-flexiramp (MW)"] = timeseries(model[:upflexiramp], instance.units)
        sol["Up-flexiramp shortfall (MW)"] = OrderedDict(
            t =>
                (instance.flexiramp_shortfall_penalty[t] >= 0) ?
                round(value(model[:upflexiramp_shortfall][t]), digits = 5) : 0.0 for
            t in 1:instance.time
        )
        sol["Down-flexiramp (MW)"] = timeseries(model[:dwflexiramp], instance.units)
        sol["Down-flexiramp shortfall (MW)"] = OrderedDict(
            t =>
                (instance.flexiramp_shortfall_penalty[t] >= 0) ?
                round(value(model[:dwflexiramp_shortfall][t]), digits = 5) : 0.0 for
            t in 1:instance.time
        )
    else
        # Report spinning reserve solutions only if both up-flexiramp and  
        # down-flexiramp requirements are arrays of zeros.
        sol["Reserve (MW)"] = timeseries(model[:reserve], instance.units)
        sol["Reserve shortfall (MW)"] = OrderedDict(
            t =>
@ -57,6 +77,8 @@ function solution(model::JuMP.Model)::OrderedDict
                round(value(model[:reserve_shortfall][t]), digits = 5) : 0.0 for
            t in 1:instance.time
        )    
    end
    sol["Net injection (MW)"] =
        timeseries(model[:net_injection], instance.buses)
    sol["Load curtail (MW)"] = timeseries(model[:curtail], instance.buses)
--- a/src/validation/validate.jl
+++ b/src/validation/validate.jl
@ -338,6 +338,40 @@ function _validate_reserve_and_demand(instance, solution, tol = 0.01)
            )
            err_count += 1
        end
        upflexiramp =
            sum(solution["Up-flexiramp (MW)"][g.name][t] for g in instance.units)
        upflexiramp_shortfall =
            (instance.flexiramp_shortfall_penalty[t] >= 0) ?
            solution["Up-flexiramp shortfall (MW)"][t] : 0
        if upflexiramp + upflexiramp_shortfall < instance.reserves.upflexiramp[t] - tol
            @error @sprintf(
                "Insufficient up-flexiramp at time %d (%.2f + %.2f should be %.2f)",
                t,
                upflexiramp,
                upflexiramp_shortfall,
                instance.reserves.upflexiramp[t],
            )
            err_count += 1
        end
        dwflexiramp =
            sum(solution["Down-flexiramp (MW)"][g.name][t] for g in instance.units)
        dwflexiramp_shortfall =
            (instance.flexiramp_shortfall_penalty[t] >= 0) ?
            solution["Down-flexiramp shortfall (MW)"][t] : 0
        if dwflexiramp + dwflexiramp_shortfall < instance.reserves.dwflexiramp[t] - tol
            @error @sprintf(
                "Insufficient down-flexiramp at time %d (%.2f + %.2f should be %.2f)",
                t,
                dwflexiramp,
                dwflexiramp_shortfall,
                instance.reserves.dwflexiramp[t],
            )
            err_count += 1
        end
    end
    return err_count