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Control of Power Converters in Low-Inertia Powe...

Florian Dörfler
September 25, 2024
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Control of Power Converters in Low-Inertia Power Systems

Mediterranean Conference on Control and Automation

Florian Dörfler

September 25, 2024
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  1. Control of Power Converters in Low-Inertia Power Systems Florian D¨

    orfler Automatic Control Laboratory, ETH Z¨ urich
  2. Acknowledgements Marcello Colombino Dominic Groß Ali Tayyebi-Khameneh Irina Subotic !

    ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! 17:30 18:15 Assessment of the proposals: with donors 18:15 19:00 Assessment of the proposals: without donors Further: Gab-Su Seo, Brian Johnson, Mohit Sinha, & Sairaj Dhople 1
  3. Replacing the power system foundation fuel & synchronous machines –

    not sustainable + central & dispatchable generation + large rotational inertia as buffer + self-synchronize through the grid + resilient voltage / frequency control – slow actuation & control renewables & power electronics + sustainable – distributed & variable generation – almost no energy storage – no inherent self-synchronization – fragile voltage / frequency control + fast / flexible / modular control 2
  4. Frequency of West Berlin re-connecting to Europe Hz *10 sec

    BEWAG UCTE December 7, 1994 before re-connection: islanded operation based on batteries & single boiler afterwards connected to European grid based on synchronous generation 4
  5. The concerns are not hypothetical issues broadly recognized by TSOs,

    device manufacturers, academia, agencies, etc. UPDATE REPORT ! BLACK SYSTEM EVENT IN SOUTH AUSTRALIA ON 28 SEPTEMBER 2016 AN UPDATE TO THE PRELIMINARY OPERATING INCIDENT REPORT FOR THE NATIONAL ELECTRICITY MARKET. DATA ANALYSIS AS AT 5.00 PM TUESDAY 11 OCTOBER 2016. lack of robust control: “Nine of the 13 wind farms online did not ride through the six voltage disturbances experienced during the event.” between the lines: conventional system would have been more resilient (?) obstacle to sustainability: power electronics integration ERCOT is recommending the transition to the following five AS products plus one additional AS that would be used during some transition period: 1. Synchronous Inertial Response Service (SIR), 2. Fast Frequency Response Service (FFR), 3. Primary Frequency Response Service (PFR), 4. Up and Down Regulating Reserve Service (RR), and 5. Contingency Reserve Service (CR). 6. Supplemental Reserve Service (SR) (during transition period) ERCOT CONCEPT PAPER Future Ancillary Services in ERCOT PUBLIC The relevance of inertia in power systems Pieter Tielens n, Dirk Van Hertem ELECTA, Department of Electrical Engineering (ESAT), University of Leuven (KU Leuven), Leuven, Belgium and EnergyVille, Genk, Belgium Contents lists available at ScienceDirect journal homepage: www.elsevier.com/locate/rser Renewable and Sustainable Energy Reviews Renewable and Sustainable Energy Reviews 55 (2016) 999–1009 MIGRATE project: Massive InteGRATion of power Electronic devices Frequency Stability Evaluation Criteria for the Synchronous Zone of Continental Europe – Requirements and impacting factors – RG-CE System Protection & Dynamics Sub Group However, as these sources are fully controllable, a regulation can be added to the inverter to provide “synthetic inertia”. This can also be seen as a short term frequency support. On the other hand, these sources might be quite restricted with respect to the available capacity and possible activation time. The inverters have a very low overload capability compared to synchronous machines. Impact of Low Rotational Inertia on Power System Stability and Operation Andreas Ulbig, Theodor S. Borsche, Göran Andersson ETH Zurich, Power Systems Laboratory Physikstrasse 3, 8092 Zurich, Switzerland ulbig | borsche | andersson @ eeh.ee.ethz.ch ! !"#$%% "&'()*%")+,-.)'%/),-)0% 1"2%/).3**)456(-34'% !"#$%&!&$!&'"!()*!+$,,-&&""! !"#$"% &'()*)+,-.+'%-,#"$"/)%'-0)'(+"1',%',' %2*30+.*.4%'3.*1)*%)+' 5
  6. Critically re-visit modeling/analysis/control Foundations and Challenges of Low-Inertia Systems (Invited

    Paper) Federico Milano University College Dublin, Ireland email: [email protected] Florian D¨ orfler and Gabriela Hug ETH Z¨ urich, Switzerland emails: dorfl[email protected], [email protected] David J. Hill∗ and Gregor Verbiˇ c University of Sydney, Australia ∗ also University of Hong Kong emails: [email protected], [email protected] • New models are needed which balance the need to include key features without burdening the model (whether for analytical or computational work) with uneven and excessive detail; • New stability theory which properly reflects the new devices and time-scales associated with CIG, new loads and use of storage; • Further computational work to achieve sensitivity guidelines including data-based approaches; • New control methodologies, e.g. new controller to mitigate the high rate of change of frequency in low inertia systems; • A power converter is a fully actuated, modular, and very fast control system, which are nearly antipodal characteristics to those of a synchronous machine. Thus, one should critically reflect the control of a converter as a virtual synchronous machine; and • The lack of inertia in a power system does not need to (and cannot) be fixed by simply “adding inertia back” in the systems. The later sections contain many suggestions for further work, which can be summarized as follows: a key unresolved challenge: control of power converters in low-inertia grids → industry & power community willing to explore green-field approach (see MIGRATE) with advanced control methods & theoretical certificates 6
  7. Our research agenda system-level • low-inertia power system models, stability,

    & performance metrics • optimal allocation of virtual inertia & fast-frequency response services ω τm τe iαβ if Lg Lg Lg iPV Lg VI VI VI 406 407 403 408 402 410 401 404 405 409 411 412 413 414 415 416 201 203 415 416 VI VI VI VI VI 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 204 215 VI VI VI 501 502 503 504 505 506 507 508 509 VI 217 102 101 VI VI VI VI 301 302 303 304 305 306 307 308 309 310 311 312 313 314 315 509 f nominal frequency ROCOF (max rate of change of frequency) frequency nadir restoration time secondary control inertial response primary control inter-area oscillations device-level (today) • decentralized nonlinear power converter control strategies • experimental implementation, cross-validation, & comparison −κ1 ∇W(θ1 ) + P-droop vf idc2 udc2 udc1 ix1 ix2 is1 is2 ex1 ex2 KP I (s) idc1 Gf P∗ g Q∗ g Relay 2 mαβ2 mαβ1 ˆ µf − sin θ1 cos θ1 Σ + 1 s + η 1 s θ1 θ2 Σ + + Ks is2 − ˆ is2 (θ2 ) z is2 vf µ∗ 2 − sin θ2 cos θ2 ˆ is2 (θ∗ 2 ) = 1 vf 2 P∗ g Q∗ g −Q∗ g P∗ g vf µ∗ 2 = 1 u∗ dc vf − Zs2 ˆ is2 (θ∗ 2 ) − sin θ∗ 2 cos θ∗ 2 = 1 µ∗ 2 u∗ dc vf − Zs2 ˆ is2 (θ∗ 2 ) −κ2 sin(θ2 −θ∗ 2 ) −Kdc (udc2 −u∗ dc ) Σ + + Gdc2 u∗ dc +ˆ ix2 (θ2 ) η Relay 1 u∗ dc Gdc1 Gdc2 Zs2 Zs1                        Yf Σ + steady-behavior compensation matching control matching control voltage control dc-control PQ-control sync-torque ˆ µf = 1 u∗ dc   − sin θ1 cos θ1 ⊤ Zs1 is2 + − sin θ1 cos θ1 ⊤ Zs1 is2 2 − Zs1 is2 2 + Zs1 Yf + I 2v∗2 f   200W/div 0 (a) (b) 2A/div 10ms/div Pg P∗ g is2,a is1,a 7
  8. Outline Introduction: Low-Inertia Power Systems Problem Setup: Modeling and Specifications

    State of the Art: Comparison & Critical Evaluation Dispatchable Virtual Oscillator Control Experimental Validation Conclusions
  9. Modeling: signal space in 3-phase AC circuits three-phase AC xa(t)

    xb(t) xc(t) = xa(t + T) xb(t + T) xc(t + T) periodic with 0 average 1 T T 0 xi (t)dt = 0 ⇡ h -2⇡ -⇡ 0 ⇡ 2⇡ 1 0 1 xabc (b) Symmetric three-phase AC signal with time-varying amplitude ⇡ h -2⇡ -⇡ 0 ⇡ 2⇡ 1 0 1 xabc (d) Asymmetric three-phase AC signal re- sulting of an asymmetric superposition of a symmetric signal with signals oscillating at higher frequencies c AC three-phase signals. The lines correspond to balanced (nearly true) = A(t) sin(δ(t)) sin(δ(t) − 2π 3 ) sin(δ(t) + 2π 3 ) so that xa (t) + xb (t) + xc (t)=0 2. PRELIMINARIES IN CONTROL THEORY AND POWER SYSTEMS -2⇡ -⇡ 0 ⇡ 2⇡ 1 0 1 xabc (a) Symmetric three-phase AC signal with constant amplitude -2⇡ -⇡ 0 ⇡ 2⇡ 1 0 1 xabc (b) Symmetric three-phase AC signal with time-varying amplitude -2⇡ -⇡ 0 ⇡ 2⇡ 1 0 1 xabc -2⇡ -⇡ 0 ⇡ 2⇡ 1 0 1 xabc synchronous (desired) =A sin(δ0 + ω0t) sin(δ0 + ω0t − 2π 3 ) sin(δ0 + ω0t + 2π 3 ) const. freq & amp ⇒ const. in rot. frame 2. PRELIMINARIES IN CONTROL THE -2⇡ -⇡ 0 ⇡ 2⇡ 1 0 1 xabc (a) Symmetric three-phase AC signal with constant amplitude xabc (b) tim -2⇡ -⇡ 0 ⇡ 2⇡ 1 0 1 xabc x assumption : balanced ⇒ 2d-coordinates x(t) = [xα (t) xβ (t)] or x(t) = A(t)eiδ(t) 9
  10. Modeling: the network interconnecting lines via Π-models & ODEs 6

    9 3 12 quasi-steady state algebraic model     i1 . . . in     nodal injections =     . . . ... . . . ... . . . −yk1 · · · n j=1 ykj · · · −ykn . . . ... . . . ... . . .     Laplacian matrix with ykj =1 / complex impedance     v1 . . . vn     nodal potentials salient feature: local measurement reveal global information ik local variable = j ykj (vk − vj ) global information 10
  11. Modeling: the power converter idc DC port modulation LC output

    filter AC port control (3-phase) to power grid vdc 1 2 i L R C v G io 1 2 vdc u network passive DC port port (idc , vdc ) for energy balance control → details neglected today: assume vdc to be stiffly regulated modulation ≡ lossless signal transformer (averaged) → controlled switching voltage vdc u with u ∈ −1 2 , +1 2 × −1 2 , +1 2 LC filter to smoothen harmonics with R, G modeling filter/switching losses well actuated, modular, & fast control system ≈ controllable voltage source 11
  12. Control objectives in the stationary frame 1. synchronous frequency: d

    dt vk = 0 −ω0 ω0 0 vk ∀ k ∈ V := {1, . . . , N} ∼ stabilization at harmonic oscillation with synchronous frequency ω0 2. voltage amplitude: vk = v ∀ k ∈ V (for ease of presentation) ∼ stabilization of voltage amplitude vk 3. prescribed power flow: vk io,k = pk , vk 0 −1 +1 0 io,k = qk ∀ k ∈ V ∼ steady-state active & reactive power injections {pk , qk } 12
  13. Main control challenges θ⋆ jk vk vj v⋆ k ω0

    ω0 C v io vk io,k vdc nonlinear objectives (vk , θkj ) & stabilization of a limit cycle local set-points: voltage/power (vk , pk , qk ) but no relative angles θkj decentralized control: only local measurements (vk , io,k ) available converter physics not resilient: no significant storage & state constraints no time-scale separation between slow sources & fast network + fully controllable voltage sources & stable linear network dynamics 13
  14. Limitations of grid-following control PLL v ˆ θ, ˆ ω

    stiff AC voltage P ≈ P is good for transferring power to a strong grid (what if everyone follows?) is not good for providing a voltage reference, stabilization, or black start tomorrow’s grid needs grid-forming control ≡ emergence of synchronization 14
  15. Naive baseline solution: emulation of virtual inertia !""" #$%&'%(#!)&' )&

    *)+"$ ','#"-'. /)01 23. &)1 2. -%, 2456 5676 !89:;8;<=><? />@=AB: !<;@=>B >< CD!EFGBH;I +><I *JK;@ E;<;@B=>J< -JLB88BI@;MB DBNLB@> -J?LBIIB8 %@B<>! "#$%&'# (&)*&+! ,---. B<I "LBO D1 ":F'BBIB<P! "&'./+ (&)*&+! ,--- !"#$%&'"'() %* +$,(-.'() /'-#%(-' .( 0.1$%2$.3- 4-.(2 5.$)6,7 !('$)., 8.".-9 :%(.! "#$%&'# (&)*&+! ,---; :6$<,(,$,<,(, =%%77,! (&)*&+! ,---; ,(3 06>67 ?@ ?9,(3%$>,$! (&)*&+! ,--- Virtual synchronous generators: A survey and new perspectives Hassan Bevrani a,b,⇑, Toshifumi Ise b, Yushi Miura b a Dept. of Electrical and Computer Eng., University of Kurdistan, PO Box 416, Sanandaj, Iran b Dept. of Electrical, Electronic and Information Eng., Osaka University, Osaka, Japan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
  16. Standard approach to converter control DC/AC power inverter measurement processing

    (e.g., via PLL) reference synthesis (e.g., droop or virtual inertia) cascaded voltage/current tracking control converter modulation DC voltage control DC voltage AC current & voltage PWM (P, Q, kV k, !) actuation of DC source/boost 1. acquiring & processing of AC measurements 2. synthesis of references (voltage/current/power) “how would a synchronous generator respond now ?” 3. cascaded PI controllers to track references 4. actuation via modulation 5. hidden assumption: DC supply instantaneously provides unlimited power → tight & fast DC-side control 16
  17. Virtual synchronous machine ≡ flywheel emulation vdc idc Cdc if

    Lf m M ω τm ir Lθ is S. D’Arco et al. / Electric Power Systems Research 122 (2015) 180–197 183 Fig. 1. Overview of investigated system configuration and control structure for the Virtual Synchronous Machine. e VSM-based power control with virtual inertia provides frequency and phase angle references ωVSM and ÂVSM to the internal control [D’Arco et al., ’15] • reference model : detailed model of synchronous generator + controls → most commonly accepted solution in industry (backward compatibility) → robust implementation requires tricks → good nominal performance but poor post-fault behavior → not resilient → poor fit: converter = flywheel – converter: fast actuation & no significant energy storage – machine: slow actuation & significant energy storage → over-parametrized & ignores limits → issues can be partially alleviated via proper nonlinear control [Arghir et al. ’17, ’19] 17
  18. Droop as simplest reference model [Chandorkar, Divan, Adapa, ’93] frequency

    control by mimicking p − ω droop property of synchronous machine: ω − ω0 ∝ p − p voltage control via q − v droop control: d dt v = −c1 ( v − v ) − c2 (q − q ) P2 P1 P ! !* !sync ωsync ω p(t) − p∗ ω0 → direct control of (p, ω) and (q, v ) assuming they are independent (approx. true only near steady state) → requires tricks in implementation : low-pass filters for dissipation, virtual impedances for saturation, limiters,... → performance: good near steady state but narrow region of attraction filtering logic for sync droop tracking controllers tricks 18
  19. Virtual Oscillator Control (VOC) nonlinear & open limit cycle oscillator

    as reference model for terminal voltage (1-phase): ¨ v + ω2 0 v + g(v) = io + - g(v) v io − + v v ) v ( g • simplified model amenable to theoretic analysis → almost global synchronization & local droop • in practice proven to be robust mechanism with performance superior to droop & others → problem : cannot be controlled(?) to meet specifications on amplitude & power injections [J. Aracil & F. Gordillo, ’02 ], [Torres, Hespanha, Moehlis, ’11], [Johnson, Dhople, Krein, ’13], [Dhople, Johnson, D¨ orfler, ’14] −4 −2 0 2 4 −4 −2 0 2 4 Voltage, v Current, i 19
  20. Comparison of grid-forming control [Tayyebi et al., ’19] P2 P1

    P ! !* !sync ωsync ω p(t) − p∗ ω0 droop control + good performance near steady state – relies on decoupling & small attraction basin vdc idc Cdc if Lf m M ω τm ir Lθ is synchronous machine emulation + backward compatible in nominal case – not resilient under large disturbances R C L g(v) v + - PWM dc,k virtual oscillator control (VOC) + robust & almost globally synchronization – cannot meet amplitude/power specifications ching of synchronous machines by DC storage lorian Dörfler ch, Switzerland Abstract Summary xαβ Structural similarities allow model matching by adding one integrator trategy for grid-forming converters in low-inertia power by identifying the structural similarities between the today: foundational control approach [Colombino, Groß, Brouillon, & D¨ orfler, ’17, ’18,’19] [Seo, Subotic, Johnson, Colombino, Groß, & D¨ orfler, ’18] 20
  21. Cartoon summary of today’s approach Conceptually, inverters are oscillators that

    have to synchronize Hypothetically, they could sync by communication (not feasible) 21
  22. Cartoon summary of today’s approach Colorful idea: inverters sync through

    physics & clever local control theory: sync of coupled oscillators & nonlinear decentralized control power systems/electronics experiments @NREL show superior performance 21
  23. Recall problem setup 1. simplifying assumptions (will be removed later)

    d dt vk(t) = uk(vk, io,k) io,k to network • converter ≈ controllable voltage source • grid ≈ quasi-static: d dt i + ri ≈ j ω0 + r i • lines ≈ homogeneous κ = tan( kj /rkj ) ∀k, j 2. fully decentralized control of converter terminal voltage & current set-points for relative angles {θjk } nonlocal measurements vj grid & load parameters local measurements (vk , io,k ) local set-points (vk , pk , qk ) 3. control objective stabilize desired quasi steady state (synchronous, 3-phase-balanced, and meet set-points in nominal case) θ⋆ jk vk vj v⋆ k ω0 ω0 22
  24. Colorful idea for closed-loop target dynamics d dt vk =

    0 −ω0 ω0 0 vk rotation at ω0 + c1 · eθ,k (v) synchronization + c2 · e v ,k (vk ) amplitude regulation θ⋆ jk vk vj v⋆ k ω0 ω0 synchronization: eθ,k (v) = n j=1 wjk vj − R(θjk )vk amplitude regulation: e v ,k (vk ) = v 2 − vk 2 vk 23
  25. Decentralized implementation of target dynamics eθ,k (v)= j wjk (vj

    −R(θjk )vk ) need to know wjk, vj , vk and θjk = j wjk (vj − vk ) “Laplacian” feedback + j wjk (I−R(θjk ))vk local feedback: Kk(θ )vk insight I: non-local measurements from communication through physics io,k local feedback = j yjk (vj − vk ) distributed feedback with wjk = ykj = ykj R(1/κ) insight II: angle set-points & line-parameters from power flow equations pk = v 2 j rjk(1−cos(θjk ))−ω0 jk sin(θjk ) r2 jk +ω2 0 2 jk qk = −v 2 j ω0 jk(1−cos(θjk ))+rjk sin(θjk ) r2 jk +ω2 0 2 jk        ⇒ Kk (θ ) global parameters = 1 v 2 R(κ) qk pk −pk qk local parameters 24
  26. Main results 1. desired target dynamics can be realized via

    fully decentralized control : d dt vk = 0 −ω0 ω0 0 vk rotation at ω0 + c1 · n j=1 wjk (vj − R(θjk )vk ) synchronization with global knowledge + c2 · (v 2 − vk 2) vk local amplitude regulation = 0 −ω0 ω0 0 vk rotation at ω0 + c1 · R (κ) 1 v 2 qk pk −pk qk vk − io,k synchronization through physics + c2 · (v 2 − vk 2) vk local amplitude regulation 2. almost global stability result : If the ... condition holds, the system is almost globally asymptotically stable with respect to a limit cycle corresponding to a pre-specified solution of the AC power-flow equations at a synchronous frequency ω0 . 25
  27. Main results cont’d 3. certifiable, sharp, and intuitive stability conditions

    : power transfer “small enough” compared to network connectivity amplitude control slower than synchronization control e.g., for resistive grid: 1 2 λ2 algebraic connectivity > max k n j=1 1 v 2 |pjk | power transfer + c2 c1 v 4. connection to droop control revealed in polar coordinates (for inductive grid) : d dt θk = ω0 + c1 pk v 2 − pk vk 2 ≈ vk ≈1 ω0 + c1 (pk − pk ) (p − ω droop) d dt vk ≈ vk ≈1 c1 (qk − qk ) + c2 (v − vk ) (q − v droop) 26
  28. Proof sketch for algebraic grid: Lyapunov & center manifold Lyapunov

    function: V (v) = 1 2 dist(v, S)2 + c2 v 2 k v 2 − vk 2 2 Z{02N } 0-stable manifold sync set S amplitude set A T target set T 02N T ∪ 02N is globally attractive lim t→∞ v(t) T ∪02N = 0 T is stable v(t) T ≤ χ( v0 T ) T is almost globally attractive 02N exponentially unstable =⇒ Z{02N } has measure zero ∀v0 / ∈ Z{02N } : lim t→∞ v(t) T = 0 stability & almost global attractivity =⇒ almost global asymptotic stability 27
  29. Case study: IEEE 9 Bus system 1 2 3 v1

    v2 v3 4 8 6 5 9 7 t = 0 s: black start of three inverters • initial state: vk (0) ≈ 10−3 • convergence to set-point t = 5 s: load step-up • 20% load increase at bus 5 • consistent power sharing t = 10 s: loss of inverter 1 • the remaining inverters synchronize • they supply the load sharing power 28
  30. Simulation of IEEE 9 Bus system 0 5 10 15

    0 0.5 1 1.5 2 pk [p.u.] 0 5 10 15 0.99 1 1.01 time [s] ω [p.u.] 0 5 10 15 0 0.5 1 vk [p.u.] 0 5 10 15 0 0.5 1 1.5 2 time [s] io,k [p.u.] 29
  31. Dropping assumptions: dynamic lines control gains ∼ 1.8 · 10−4

    0 2 4 49.99 50 50.01 50.02 fr. [Hz] η = 1.8 · 10−4 0 2 4 0.9 0.95 1 time [s] vk [p.u.] control gains ∼ 1.8 · 10−3 0 2 4 0 50 100 150 fr. [Hz] η = 1.8 · 10−3 0 2 4 6 k [p.u.] re-do the math leading to updated condition: amplitude control slower than sync control slower than line dynamics observations inverter control interferes with the line dynamics controller needs to be artificially slowed down recognized problem [Vorobev, Huang, Hosaini, & Turitsyn,’17] “networked control” reason communication through currents to infer voltages very inductive lines delay the information transfer the controller must be slow in very inductive networks 30
  32. Proof sketch for dynamic grid: perturbation-inspired Lyapunov d d t

    v = fv(v, i) i = h(v) −h(v) d d t i = fi(v, i) v i v y = i − h(v) Individual Lyapunov functions slow system: V (v) for d d t v = fv (v, h(v)) fast system: W(y) for d d t y = fi (v, y + h(v)) where d d t v = 0 & coordinate y = i − h(v) Lyapunov function for the full system ν(x) = dW(i − h(v)) + (1 − d)V (v) where d ∈ [0, 1] is free convex coefficient d d t ν(x) is decaying under stability condition Almost global asymptotic stability T ∪ {0n } globally attractive & T stable Z{0n} has measure zero 31
  33. Evaluation of stability conditions 0 5 10 15 20 10−5

    10−4 10−3 3 · 10−2 3 · 10−2 6 · 10−2 6 · 10−2 8 · 10−2 8 · 10−2 9.5 · 10−2 9.5 · 10−2 linear instability certified stability region constraints violated damping ratios amplitude gain [p.u.] synchronization gain [p.u.] 0 2 4 0 1 2 vk [p.u.] increase of control gains by factor 10 ⇒ oscillations, overshoots, & instability ⇒ conditions are highly accurate 32
  34. Dropping assumptions: detailed converter model voltage source model: d dt

    v(t) = u(v, io) io detailed converter model with LC filter: i L R C v G io 1 2 vdc u vdc 1 2 idea: invert LC filter so that v ≈ vdc u → control: perform robust inversion of LC filter via cascaded PI analysis: repeat proof via singular perturbation Lyapunov functions → almost global stability for sufficient time scale separation (quantifiable) VOC model < line dynamics < voltage PI < current PI [Subotic, ETH Z¨ urich Master thesis ’18] ...similar steps for control of vdc in a more detailed model 33
  35. Experimental results [Seo, Subotic, Johnson, Colombino, Groß, & D¨ orfler,

    APEC’18] black start of inverter #1 under 500 W load (making use of almost global stability) 250 W to 750 W load transient with two inverters active connecting inverter #2 while inverter #1 is regulating the grid under 500 W load change of setpoint: p of inverter #2 updated from 250 W to 500 W 35
  36. Conclusions Summary • challenges of low-inertia systems • dispatchable virtual

    oscillator control • theoretic analysis & experiments Ongoing & future work • theoretical questions: robustness & regulation • practical issue: compatibility with legacy system • experimental validations @ ETH, NREL, AIT Main references (others on website) D. Groß, M Colombino, J.S. Brouillon, & F. D¨ orfler. The effect of transmission-line dynamics on grid-forming dispatchable virtual oscillator control. M. Colombino, D. Groß, J.S. Brouillon, & F. D¨ orfler. Global phase and magnitude synchron- ization of coupled oscillators with application to the control of grid-forming power inverters. 36