diff --git a/CHANGELOG.md b/CHANGELOG.md index 0b8a2ad7..4f399f68 100644 --- a/CHANGELOG.md +++ b/CHANGELOG.md @@ -8,6 +8,10 @@ - Added capability to evaluate the optimality of a given partition against a set of load scenarios to judge robustness +## v3.5.1 + +- Fixed bug in `constraint_mc_power_balance_shed_block` (`LPUBFDiagPowerModel` version) where `pd_zblock_zdemand` was used instead of `qd_zblock_zdemand` + ## v3.5.0 - Added support for individually shedable loads to block LinDistFlow formulation diff --git a/Project.toml b/Project.toml index 28e69221..fd3c29f0 100644 --- a/Project.toml +++ b/Project.toml @@ -35,7 +35,7 @@ UUIDs = "cf7118a7-6976-5b1a-9a39-7adc72f591a4" [compat] ArgParse = "1.1" Combinatorics = "1" -EzXML = "1.1.0" +EzXML = "1.2.0" Graphs = "1.4.1, 1.6, 1.7, 1.8, 1.9" HiGHS = "1.5.2" Hwloc = "2" @@ -43,7 +43,7 @@ InfrastructureModels = "0.7" Ipopt = "0.9, 1.0.2, 1.3" JSON = "0.21" JSONSchema = "0.3.3, 1" -JuMP = "0.22, 0.23, 1" +JuMP = "1 - 1.14" Juniper = "0.8, 0.9" LoggingExtras = "0.4.7, 0.4.9" PolyhedralRelaxations = "0.3.3, 0.3.4, 0.3.5" diff --git a/README.md b/README.md index df1554f9..d9bf3073 100644 --- a/README.md +++ b/README.md @@ -69,7 +69,7 @@ If you find PowerModelsONM useful for your work, we kindly request that you cite ## License -This code is provided under a BSD license as part of the Multi-Infrastructure Control and Optimization Toolkit (MICOT) project, LA-CC-13-108. +This code is provided under a BSD license as part of the Multi-Infrastructure Control and Optimization Toolkit (MICOT) project, C15024. [docs-dev-img]: https://github.com/lanl-ansi/PowerModelsONM.jl/workflows/Documentation/badge.svg [docs-dev-url]: https://lanl-ansi.github.io/PowerModelsONM.jl/dev diff --git a/src/core/constraint.jl b/src/core/constraint.jl index 614c8f3d..08e33002 100644 --- a/src/core/constraint.jl +++ b/src/core/constraint.jl @@ -219,7 +219,7 @@ function constraint_radial_topology(pm::AbstractUnbalancedPowerModel, nw::Int; r var(pm, nw)[:f] = Dict{Tuple{Int,Int,Int},JuMP.VariableRef}() var(pm, nw)[:lambda] = Dict{Tuple{Int,Int},JuMP.VariableRef}() var(pm, nw)[:beta] = Dict{Tuple{Int,Int},JuMP.VariableRef}() - var(pm, nw)[:alpha] = Dict{Tuple{Int,Int},Union{JuMP.VariableRef,Int}}() + var(pm, nw)[:alpha] = Dict{Tuple{Int,Int},Union{JuMP.VariableRef,JuMP.AffExpr,Int}}() # "real" node and branch sets N₀ = ids(pm, nw, :blocks) @@ -250,9 +250,10 @@ function constraint_radial_topology(pm::AbstractUnbalancedPowerModel, nw::Int; r end # create an aux varible α that maps to the switch states - for (s,sw) in ref(pm, nw, :switch) - (i,j) = (ref(pm, nw, :bus_block_map, sw["f_bus"]), ref(pm, nw, :bus_block_map, sw["t_bus"])) - var(pm, nw, :alpha)[(i,j)] = var(pm, nw, :switch_state, s) + switch_lookup = Dict{Tuple{Int,Int},Vector{Int}}((ref(pm, nw, :bus_block_map, sw["f_bus"]), ref(pm, nw, :bus_block_map, sw["t_bus"])) => Int[ss for (ss,ssw) in ref(pm, nw, :switch) if (ref(pm, nw, :bus_block_map, sw["f_bus"])==ref(pm, nw, :bus_block_map, ssw["f_bus"]) && ref(pm, nw, :bus_block_map, sw["t_bus"])==ref(pm, nw, :bus_block_map, ssw["t_bus"])) || (ref(pm, nw, :bus_block_map, sw["f_bus"])==ref(pm, nw, :bus_block_map, ssw["t_bus"]) && ref(pm, nw, :bus_block_map, sw["t_bus"])==ref(pm, nw, :bus_block_map, ssw["f_bus"]))] for (s,sw) in ref(pm, nw, :switch)) + for ((i,j), switches) in switch_lookup + var(pm, nw, :alpha)[(i,j)] = JuMP.@expression(pm.model, sum(var(pm, nw, :switch_state, s) for s in switches)) + JuMP.@constraint(pm.model, var(pm, nw, :alpha, (i,j)) <= 1) end f = var(pm, nw, :f) diff --git a/src/form/lindistflow.jl b/src/form/lindistflow.jl index 6853ff53..00b5a9a4 100644 --- a/src/form/lindistflow.jl +++ b/src/form/lindistflow.jl @@ -152,7 +152,7 @@ function constraint_mc_power_balance_shed_block(pm::PMD.LPUBFDiagModel, nw::Int, == sum(qg[g][t] for (g, conns) in bus_gens if t in conns) - sum(qs[s][t] for (s, conns) in bus_storage if t in conns) - - sum(pd_zblock_zdemand[l][t] for (l, conns) in bus_loads if t in conns) + - sum(qd_zblock_zdemand[l][t] for (l, conns) in bus_loads if t in conns) - sum((-w[t] * LinearAlgebra.diag(Bt')[idx]) for (sh, conns) in uncontrolled_shunts if t in conns) - sum(-var(pm, nw, :capacitor_reactive_power, sh)[t] for (sh, conns) in controlled_shunts if t in conns) ) diff --git a/test/data/network.ieee13mod.dss b/test/data/network.ieee13mod.dss new file mode 100644 index 00000000..39218334 --- /dev/null +++ b/test/data/network.ieee13mod.dss @@ -0,0 +1,181 @@ +Clear +Set DefaultBaseFrequency=60 + +! +! This script is based on a script developed by Tennessee Tech Univ students +! Tyler Patton, Jon Wood, and David Woods, April 2009 +! + +new circuit.IEEE13Nodeckt +~ basekv=115 pu=1.0001 phases=3 bus1=SourceBus +~ Angle=30 ! advance angle 30 deg so result agree with published angle +~ MVAsc3=20000 MVASC1=21000 ! stiffen the source to approximate inf source +~ baseMVA=1 + + +!SUB TRANSFORMER DEFINITION +! Although this data was given, it does not appear to be used in the test case results +! The published test case starts at 1.0 per unit at Bus 650. To make this happen, we will change the impedance +! on the transformer to something tiny by dividing by 1000 using the DSS in-line RPN math +New Transformer.Sub Phases=3 Windings=2 XHL=(8 1000 /) +~ wdg=1 bus=SourceBus conn=delta kv=115 kva=5000 %r=(.5 1000 /) +~ wdg=2 bus=650 conn=wye kv=4.16 kva=5000 %r=(.5 1000 /) + +! FEEDER 1-PHASE VOLTAGE REGULATORS +! Define low-impedance 2-wdg transformer + +New Transformer.Reg1 phases=1 bank=reg1 XHL=0.01 kVAs=[1666 1666] +~ Buses=[650.1 RG60.1] kVs=[2.4 2.4] %LoadLoss=0.01 +~ %rs=[0 0] ! correct default here + +New Transformer.Reg2 phases=1 bank=reg1 XHL=0.01 kVAs=[1666 1666] +~ Buses=[650.2 RG60.2] kVs=[2.4 2.4] %LoadLoss=0.01 +~ %rs=[0 0] ! correct default here + +New Transformer.Reg3 phases=1 bank=reg1 XHL=0.01 kVAs=[1666 1666] +~ Buses=[650.3 RG60.3] kVs=[2.4 2.4] %LoadLoss=0.01 +~ %rs=[0 0] ! correct default here + + +!TRANSFORMER DEFINITION +New Transformer.XFM1 Phases=3 Windings=2 XHL=2 +~ wdg=1 bus=633 conn=Wye kv=4.16 kva=500 %r=.55 XHT=1 +~ wdg=2 bus=634 conn=Wye kv=0.480 kva=500 %r=.55 XLT=1 + +!ADD A SWITCH AT THE SUBSTATION +New Line.cb_101 Phases=3 Bus1=RG60 Bus2=600 Switch=y r1=0 r0=0 x1=0.000 x0=0.000 c1=0.000 c0=0.000 normamps=800 emergamps=1000 + +!LINE CODES + +// these are local matrix line codes +// corrected 9-14-2011 +New linecode.mtx601 nphases=3 BaseFreq=60 +~ rmatrix = (0.3465 | 0.1560 0.3375 | 0.1580 0.1535 0.3414 ) +~ xmatrix = (1.0179 | 0.5017 1.0478 | 0.4236 0.3849 1.0348 ) +~ units=mi +New linecode.mtx602 nphases=3 BaseFreq=60 +~ rmatrix = (0.7526 | 0.1580 0.7475 | 0.1560 0.1535 0.7436 ) +~ xmatrix = (1.1814 | 0.4236 1.1983 | 0.5017 0.3849 1.2112 ) +~ units=mi +New linecode.mtx603 nphases=2 BaseFreq=60 +~ rmatrix = (1.3238 | 0.2066 1.3294 ) +~ xmatrix = (1.3569 | 0.4591 1.3471 ) +~ units=mi +New linecode.mtx604 nphases=2 BaseFreq=60 +~ rmatrix = (1.3238 | 0.2066 1.3294 ) +~ xmatrix = (1.3569 | 0.4591 1.3471 ) +~ units=mi +New linecode.mtx605 nphases=1 BaseFreq=60 +~ rmatrix = (1.3292 ) +~ xmatrix = (1.3475 ) +~ units=mi +New Linecode.mtx606 nphases=3 Units=mi +~ Rmatrix=[0.791721 |0.318476 0.781649 |0.28345 0.318476 0.791721 ] +~ Xmatrix=[0.438352 |0.0276838 0.396697 |-0.0184204 0.0276838 0.438352 ] +~ Cmatrix=[383.948 |0 383.948 |0 0 383.948 ] +New linecode.mtx607 nphases=1 BaseFreq=60 +~ rmatrix = (1.3425 ) +~ xmatrix = (0.5124 ) +~ cmatrix = [236] +~ units=mi + +!LOADSHAPE DEFINITION +New LoadShape.microgrid1a interval=1 npts=8 useactual=no mult=(0.25, 0.4, 0.8, 1.0, 1.0, 0.8, 0.6, 0.5) +New LoadShape.microgrid1b interval=1 npts=8 useactual=no mult=(1.0, 1.0, 0.8, 0.5, 0.4, 0.4, 0.4, 0.8) +New LoadShape.microgrid1c interval=1 npts=8 useactual=no mult=(0.25, 0.4, 0.8, 1.0, 1.4, 2.0, 1.0, 0.8) +New LoadShape.microgrid1d interval=1 npts=8 useactual=no mult=(0.4, 0.4, 0.4, 1.0, 1.0, 0.8, 0.8, 0.6) +New LoadShape.pvdaily interval=1 npts=8 useactual=no mult=(0, 0, 0.4, 1.0, 0.8, 0.3, 0, 0) + +!LOAD DEFINITIONS +New Load.671 Bus1=671.1.2.3 Phases=3 Conn=Delta Model=1 kV=4.16 kW=1155 kvar=660 vminpu=0.6 vmaxpu=1.4 +New Load.634a Bus1=634.1 Phases=1 Conn=Wye Model=1 kV=0.277 kW=160 kvar=110 vminpu=0.6 vmaxpu=1.4 +New Load.634b Bus1=634.2 Phases=1 Conn=Wye Model=1 kV=0.277 kW=120 kvar=90 vminpu=0.6 vmaxpu=1.4 +New Load.634c Bus1=634.3 Phases=1 Conn=Wye Model=1 kV=0.277 kW=120 kvar=90 vminpu=0.6 vmaxpu=1.4 +New Load.645 Bus1=645.2 Phases=1 Conn=Wye Model=1 kV=2.4 kW=170 kvar=125 vminpu=0.6 vmaxpu=1.4 +New Load.646 Bus1=646.2.3 Phases=1 Conn=Delta Model=2 kV=4.16 kW=230 kvar=132 vminpu=0.6 vmaxpu=1.4 +New Load.692 Bus1=692.3.1 Phases=1 Conn=Delta Model=5 kV=4.16 kW=170 kvar=151 vminpu=0.6 vmaxpu=1.4 daily=microgrid1d +New Load.675a Bus1=675.1 Phases=1 Conn=Wye Model=1 kV=2.4 kW=485 kvar=190 vminpu=0.6 vmaxpu=1.4 daily=microgrid1d +New Load.675b Bus1=675.2 Phases=1 Conn=Wye Model=1 kV=2.4 kW=68 kvar=60 vminpu=0.6 vmaxpu=1.4 daily=microgrid1d +New Load.675c Bus1=675.3 Phases=1 Conn=Wye Model=1 kV=2.4 kW=290 kvar=212 vminpu=0.6 vmaxpu=1.4 daily=microgrid1d +New Load.611 Bus1=611.3 Phases=1 Conn=Wye Model=5 kV=2.4 kW=170 kvar=80 vminpu=0.6 vmaxpu=1.4 +New Load.652 Bus1=652.1 Phases=1 Conn=Wye Model=2 kV=2.4 kW=128 kvar=86 vminpu=0.6 vmaxpu=1.4 +New Load.670a Bus1=670.1 Phases=1 Conn=Wye Model=1 kV=2.4 kW=17 kvar=10 vminpu=0.6 vmaxpu=1.4 +New Load.670b Bus1=670.2 Phases=1 Conn=Wye Model=1 kV=2.4 kW=66 kvar=38 vminpu=0.6 vmaxpu=1.4 +New Load.670c Bus1=670.3 Phases=1 Conn=Wye Model=1 kV=2.4 kW=117 kvar=68 vminpu=0.6 vmaxpu=1.4 + +!CAPACITOR DEFINITIONS +New Capacitor.Cap1 Bus1=675 phases=3 kVAR=600 kV=4.16 +New Capacitor.Cap2 Bus1=611.3 phases=1 kVAR=100 kV=2.4 + +!Bus 670 is the concentrated point load of the distributed load on line 632 to 671 located at 1/3 the distance from node 632 + +!LINE DEFINITIONS +New Line.650632 Phases=3 Bus1=600.1.2.3 Bus2=632.1.2.3 LineCode=mtx601 Length=2000 units=ft normamps=800 emergamps=800 +New Line.632670 Phases=3 Bus1=632.1.2.3 Bus2=670.1.2.3 LineCode=mtx601 Length=667 units=ft normamps=800 emergamps=800 +New Line.670671 Phases=3 Bus1=670.1.2.3 Bus2=671.1.2.3 LineCode=mtx601 Length=1333 units=ft normamps=800 emergamps=800 +New Line.671680 Phases=3 Bus1=671.1.2.3 Bus2=680.1.2.3 LineCode=mtx601 Length=1000 units=ft normamps=800 emergamps=800 +New Line.632633 Phases=3 Bus1=632.1.2.3 Bus2=633.1.2.3 LineCode=mtx602 Length=500 units=ft +New Line.632645 Phases=2 Bus1=632.3.2 Bus2=645.3.2 LineCode=mtx603 Length=500 units=ft +New Line.645646 Phases=2 Bus1=645.3.2 Bus2=646.3.2 LineCode=mtx603 Length=300 units=ft +New Line.692675 Phases=3 Bus1=692.1.2.3 Bus2=675.1.2.3 LineCode=mtx606 Length=500 units=ft normamps=800 emergamps=800 +New Line.671684 Phases=2 Bus1=671.1.3 Bus2=684.1.3 LineCode=mtx604 Length=300 units=ft +New Line.684611 Phases=1 Bus1=684.3 Bus2=611.3 LineCode=mtx605 Length=300 units=ft +New Line.684652 Phases=1 Bus1=684.1 Bus2=652.1 LineCode=mtx607 Length=800 units=ft + +!SWITCH DEFINITIONS +New Line.671692 Phases=3 Bus1=671 Bus2=692 Switch=y r1=0 r0=0 x1=0.000 x0=0.000 c1=0.000 c0=0.000 normamps=800 emergamps=1000 +New Line.680675 Phases=3 Bus1=680 Bus2=675 Switch=y r1=0 r0=0 x1=0.000 x0=0.000 c1=0.000 c0=0.000 normamps=800 emergamps=1000 enabled=n + +!MICROGRID DEFINITIONS +New Line.670700 Phases=3 Bus1=670 Bus2=700 Switch=y r1=0 r0=0 x1=0.000 x0=0.000 c1=0.000 c0=0.000 enabled=y +New Line.700701 Phases=3 Bus1=700.1.2.3 Bus2=701.1.2.3 LineCode=mtx601 Length=800 units=ft +New Load.700 Phases=3 Bus1=700.1.2.3 Conn=Wye Model=1 kv=4.16 kw=10 kvar=3 daily=microgrid1b +New Load.701 Phases=3 Bus1=701.1.2.3 Conn=Wye Model=1 kv=4.16 kw=15 kvar=5 daily=microgrid1b + +New PVSystem.PV_mg1b Phases=3 Bus1=700.1.2.3 kv=4.16 conn=wye irradiance=1 Pmpp=25 kva=35 pf=0.74 daily=pvdaily +New Storage.Battery_mg1b Phases=3 Bus1=700 kwhstored=5 kwhrated=50 kwrated=10 %idlingkw=0 %idlingkvar=0 %effcharge=100 %effdischarge=100 %charge=100 %discharge=100 %r=0 %x=0 enabled=y + +New Line.701702 Phases=3 Bus1=701 Bus2=702 Switch=y r1=0 r0=0 x1=0.000 x0=0.000 c1=0.000 c0=0.000 enabled=y +New Line.702703 Phases=3 Bus1=702.1.2.3 Bus2=703.1.2.3 LineCode=mtx601 Length=900 units=ft +New Load.702 Phases=3 Bus1=702.1.2.3 conn=wye model=1 kv=4.16 kw=50 kvar=20 daily=microgrid1a +New Load.703 Phases=3 Bus1=703.1.2.3 conn=wye model=1 kv=4.16 kw=135 kvar=100 daily=microgrid1a + +New PVSystem.PV_mg1a Phases=3 Bus1=703.1.2.3 kv=4.16 conn=wye irradiance=1 Pmpp=25 kva=210 pf=0.74 daily=pvdaily +New Storage.Battery_mg1a Phases=3 Bus1=700 kwhstored=25 kwhrated=200 kwrated=50 %idlingkw=0 %idlingkvar=0 %effcharge=100 %effdischarge=100 %charge=100 %discharge=100 %r=0 %x=0 enabled=y + +New Line.703800 Phases=3 Bus1=703 Bus2=800aux Switch=y r1=0 r0=0 x1=0 x0=0 c1=0 c0=0 enabled=y normamps=600 emergamps=600 +New Line.800800aux Phases=3 Bus1=800aux Bus2=800 LineCode=mtx601 Length=1000 units=ft +New Line.800801 Phases=3 Bus1=800 Bus2=801 Switch=y r1=0 r0=0 x1=0 x0=0 c1=0 c0=0 enabled=y normamps=50 emergamps=50 + +New Load.801 Phases=3 Bus1=801 conn=wye model=1 kv=4.16 kw=200.0 kvar=120.0 daily=microgrid1c + +New Storage.Battery_mg1c Phases=3 Bus1=801 kwhstored=500 kwhrated=1000 kwrated=250 %idlingkw=0 %idlingkvar=0 %effcharge=100 %effdischarge=100 %charge=100 %discharge=100 %r=0 %x=0 enabled=y + +New Line.801675 Phases=3 Bus1=801 Bus2=675aux Switch=y r1=0 r0=0 x1=0 x0=0 c1=0.0 c0=0.0 normamps=50 emergamps=50 enabled=n ! tie switch +New Line.675675aux Phases=3 Bus1=675 Bus2=675aux LineCode=mtx601 Length=15 units=mi normamps=800 emergamps=800 + +New Generator.675 Phases=3 Bus1=675 kv=2.4 kva=2000 kw=1500 kvar=1200 + +New Relay.801675 monitoredobj=line.801675 +New Recloser.671700 monitoredobj=line.671700 phasetrip=140 +New Relay.632645 MonitoredObj=line.632645 + +!New CapControl.cap1 Capacitor=Cap1 element=Line.692675 ptphase=3 terminal=2 type=voltage ptratio=1 ctratio=1 ONsetting=2500 OFFsetting=2540 VoltOverride=N +!New CapControl.cap2 Capacitor=Cap2 element=Line.684611 terminal=3 ptphase=3 type=kvar ptratio=1 ctratio=1 ONsetting=0 OFFsetting=0 VoltOverride=Y Vmin=0 Vmax=10000 + +Set Voltagebases=[115, 4.16, .48] +calcv + +! POINT REGULATOR CONTROLS TO REGULATOR TRANSFORMER AND SET PARAMETERS +new regcontrol.Reg1 transformer=Reg1 winding=2 vreg=122 band=2 ptratio=20 ctprim=700 R=3 X=9 +new regcontrol.Reg2 transformer=Reg2 winding=2 vreg=122 band=2 ptratio=20 ctprim=700 R=3 X=9 +new regcontrol.Reg3 transformer=Reg3 winding=2 vreg=122 band=2 ptratio=20 ctprim=700 R=3 X=9 + +Transformer.Reg1.Taps=[1.0 1.0625] +Transformer.Reg2.Taps=[1.0 1.0500] +Transformer.Reg3.Taps=[1.0 1.06875] + +Set Controlmode=OFF +Set tolerance=0.001 + +Solve diff --git a/test/graphml.jl b/test/graphml.jl index 1e11bfda..87088686 100644 --- a/test/graphml.jl +++ b/test/graphml.jl @@ -7,9 +7,7 @@ @test length(graph.edge) == 6 save_graphml("../test/data/ieee13_nested.graphml", eng; type="nested") - open("../test/data/ieee13_nested.graphml", "r") do io - @test length(readlines(io)) == 1509 - end + @test length(EzXML.nodes(EzXML.nodes(EzXML.readxml("../test/data/ieee13_nested.graphml").node)[1])) == 185 rm("../test/data/ieee13_nested.graphml") end @@ -19,9 +17,7 @@ @test length(graph.edge) == 57 save_graphml("../test/data/ieee13_unnested.graphml", eng; type="unnested") - open("../test/data/ieee13_unnested.graphml", "r") do io - @test length(readlines(io)) == 1479 - end + @test length(EzXML.nodes(EzXML.nodes(EzXML.readxml("../test/data/ieee13_unnested.graphml").node)[1])) == 185 rm("../test/data/ieee13_unnested.graphml") end end diff --git a/test/mld.jl b/test/mld.jl index 8f7a1b16..8baec756 100644 --- a/test/mld.jl +++ b/test/mld.jl @@ -35,7 +35,7 @@ r = optimize_switches!(args) @test all(_r["termination_status"] == OPTIMAL for (n,_r) in r) - @test isapprox(sum(Float64[_r["objective"] for _r in values(r)]), 119.89; atol=1) + @test isapprox(sum(Float64[_r["objective"] for _r in values(r)]), 176.86; atol=1) end @testset "test rolling-horizon optimal switching - lindistflow - traditional" begin @@ -53,7 +53,7 @@ r = optimize_switches!(args) @test all(_r["termination_status"] == OPTIMAL for (n,_r) in r) - @test isapprox(sum(Float64[_r["objective"] for _r in values(r)]), 119.89; atol=1) + @test isapprox(sum(Float64[_r["objective"] for _r in values(r)]), 176.86; atol=1) end @testset "test rolling-horizon optimal switching - nfa - block" begin @@ -138,7 +138,7 @@ r = optimize_switches!(args) @test first(r).second["termination_status"] == OPTIMAL - @test isapprox(r["1"]["objective"], 80.65; atol=1) + @test isapprox(r["1"]["objective"], 80.64; atol=1) end @testset "test full-lookahead optimal switching - lindistflow - traditional - radial-disabled - inverter-disabled" begin @@ -203,3 +203,76 @@ end end end + + +@testset "test radiality " begin + solver = build_solver_instances(;solver_options=Dict{String,Any}("HiGHS"=>Dict{String,Any}("output_flag"=>false, "presolve"=>"off")))["mip_solver"] + eng_s = parse_file("../test/data/network.ieee13mod.dss") + + eng_s["time_elapsed"] = 1.0 + eng_s["switch_close_actions_ub"] = Inf + + PMD.apply_voltage_bounds!(eng_s; vm_lb=0.9, vm_ub=1.1) + PMD.apply_voltage_angle_difference_bounds!(eng_s, 10.0) + PMD.adjust_line_limits!(eng_s, Inf) + PMD.adjust_transformer_limits!(eng_s, Inf) + + for switch in values(eng_s["switch"]) + switch["dispatchable"] = YES + switch["state"] = CLOSED + switch["status"] = ENABLED + end + + for t in ["storage", "solar", "generator"] + for obj in values(eng_s[t]) + obj["inverter"] = GRID_FOLLOWING + end + end + + set_option!(eng_s, ("options", "objective", "disable-load-block-weight-cost"), true) + set_option!(eng_s, ("options", "objective", "disable-storage-discharge-cost"), true) + set_option!(eng_s, ("options", "objective", "disable-generation-dispatch-cost"), true) + + r = solve_block_mld(eng_s, LPUBFDiagPowerModel, solver) + + @test r["solution"]["switch"]["680675"]["state"] != r["solution"]["switch"]["671692"]["state"] + @test length(filter(x->x.second["state"]==OPEN, r["solution"]["switch"])) == 2 + @test r["objective"] < 1.0 + + eng_s["switch"]["680675"]["state"] = OPEN + + r = solve_block_mld(eng_s, LPUBFDiagPowerModel, solver) + + @test r["solution"]["switch"]["680675"]["state"] == OPEN + @test r["solution"]["switch"]["671692"]["state"] == OPEN + @test length(filter(x->x.second["state"]==OPEN, r["solution"]["switch"])) == 2 + @test r["objective"] < 1.0 + + eng_s["switch"]["680675"]["state"] = CLOSED + eng_s["switch"]["671692"]["state"] = OPEN + + r = solve_block_mld(eng_s, LPUBFDiagPowerModel, solver) + + @test r["solution"]["switch"]["680675"]["state"] == OPEN + @test r["solution"]["switch"]["671692"]["state"] == OPEN + @test length(filter(x->x.second["state"]==OPEN, r["solution"]["switch"])) == 2 + @test r["objective"] < 1.0 + + eng_s["switch"]["680675"]["state"] = OPEN + eng_s["switch"]["671692"]["state"] = OPEN + + r = solve_block_mld(eng_s, LPUBFDiagPowerModel, solver) + + @test (r["solution"]["switch"]["680675"]["state"] != r["solution"]["switch"]["671692"]["state"]) || (r["solution"]["switch"]["680675"]["state"] == OPEN) + @test length(filter(x->x.second["state"]==OPEN, r["solution"]["switch"])) == 2 + @test r["objective"] < 1.0 + + eng_s["switch"]["680675"]["dispatchable"] = NO + eng_s["switch"]["671692"]["dispatchable"] = NO + + r = solve_block_mld(eng_s, LPUBFDiagPowerModel, solver) + + @test r["solution"]["switch"]["680675"]["state"] == r["solution"]["switch"]["671692"]["state"] + @test length(filter(x->x.second["state"]==OPEN, r["solution"]["switch"])) == 2 + @test r["objective"] < 1.0 +end diff --git a/test/runtests.jl b/test/runtests.jl index ea187469..800b413d 100644 --- a/test/runtests.jl +++ b/test/runtests.jl @@ -8,6 +8,7 @@ Distributed.addprocs(3) # cd("test"); import Gurobi; using PowerModelsONM import JSON +import EzXML import PowerModelsDistribution as PMD import Juniper