Dashboard › PE Power Exam Prep › Transmission and Distribution › Stability & control › Small-signal stability & PSS — eigenvalues, modes, wide-area damping

Small-signal stability & PSS — eigenvalues, modes, wide-area damping

Linearise DAEs → A · Δx = Δẋ → eigenvalues λ = σ ± jω → damping ζ = −σ/sqrt(σ²+ω²); target ζ > 5-10%. Three rotor modes: local (1-3 Hz), inter-area (0.1-0.7 Hz, most problematic), torsional (10-50 Hz, SSR/SSCI). PSS: K·washout·lead-lag·limiter on AVR ref → boosts damping 2-5% → 15-25%. Tune via participation factors + residues. WADC for inter-area via PMU + HVDC/FACTS modulation. IBR: SSCI (Texas 2009), grid-forming inverters per IEEE 2800.

Senior ~16 min

Step 1 — Small-signal stability: linearise around operating point, find modes

Animation speed 0.55×

f_n — damping — PSS —

Reference notes

Small-signal stability is the ability of a power system to remain in synchronism following small disturbances. Method: linearize nonlinear differential-algebraic equations around the operating point; analyze eigenvalues of the state matrix. Damping ratio ζ < 5% is concerning; ζ < 0 is unstable. Power System Stabilizer (PSS) is the primary remediation device, in production since the 1960s. Wide-Area Damping Control (WADC) addresses inter-area modes that single PSS cannot fully damp. High-IBR grids face new instability classes (SSCI, SSTI).

Linearization and eigenvalue analysis

d(Δx)/dt = A · Δx + B · Δu (state-space linearization)

eigenvalues λ_k = σ_k ± j·ω_k (natural modes)

Linearize the nonlinear differential-algebraic equations (DAEs) around the operating point.
State matrix A typically has thousands of dimensions for a real-system model.
Each eigenvalue is the system's natural mode:
- Real eigenvalues: first-order modes (no oscillation). Stable if σ < 0.
- Complex-conjugate pairs: second-order oscillatory modes.
Natural frequency: f_n,k = ω_k / (2π) Hz.
Damping ratio: ζ_k = −σ_k / sqrt(σ_k² + ω_k²).
Target: ζ > 5-10% for all modes in normal operation; ζ < 0 (positive σ) is unstable.

Rotor mode categories

Mode type	Frequency	Typical pre-PSS damping	Notes
Local	1-3 Hz	5-15%	Single generator (or small group) oscillating against the rest of the system through transmission impedance. Improved by PSS on the generator.
Inter-area	0.1-0.7 Hz	1-5%	Entire regions oscillating against each other through long corridors. Most problematic. Requires PSS on multiple generators + WADC.
Torsional	10-50 Hz	varies	Mechanical oscillations of generator-turbine shaft. Excited by series capacitors (SSR) or IBR control (SSCI). Mitigated by torsional-stress relays, blocking filters, TCSC damping.

Historical examples

1970-71 Mohave Power Plant: SSR (sub-synchronous resonance) with a series-compensated 500 kV line destroyed turbine-generator shafts.
1996 WSCC August blackout: 0.7 Hz inter-area mode between Pacific Northwest and California became unstable, cascaded to system breakup.
Northern Europe 0.3 Hz mode: between Nordic and Continental Europe via HVDC links.
2009 Texas Lubbock-Brownsville SSCI: DFIG wind farms + series-capacitor-compensated 345 kV line caused 25 Hz oscillations; multiple converter and line trips.

Power System Stabilizer (PSS)

Adds a supplementary signal to the AVR (Automatic Voltage Regulator) voltage reference, modulating field excitation to provide a DAMPING TORQUE proportional to rotor speed deviation.
Input signal: rotor speed deviation Δω, or accelerating power (ΔP_mech − ΔP_elec), or both via dual-input PSS.
Transfer function: K · washout · two lead-lag stages · output limiter
- Gain K_PSS: 10-30 typical.
- Washout T_w = 5-20 s — high-pass filter; PSS responds to TRANSIENT speed changes only (removes DC bias).
- Lead-lag stages T_1-T_4 = 0.05-1 s — compensate phase shift through AVR-excitation system at the target mode frequency.
- Output limiter ±0.05-0.15 pu voltage — prevents AVR saturation.
Boosts rotor-mode damping from 2-5% (no PSS) to 15-25% (well-tuned PSS).
Standards: IEEE Std 421.5 defines PSS models — PSS1A (single-input), PSS2B (dual-input), PSS4B (multi-band, damps multiple modes simultaneously).
Vendors: GE, Siemens, ABB, Hitachi, Basler — every major excitation supplier offers PSS-equipped digital AVR platforms.

PSS tuning workflow

Identify problematic modes: eigenvalue analysis flags modes with ζ < 5%.
Compute participation factors: p_ki = (right-eigenvector)_i × (left-eigenvector)_i for each generator i and mode k. Generators with p_ki > 0.1 are PSS-installation candidates.
Compute residues: R_ki = sensitivity of mode k's eigenvalue to a feedback control loop at generator i. Magnitude = max damping improvement; angle = required phase compensation.
Design PSS: choose K_PSS, T_w, and lead-lag T_1-T_4 to produce the required phase compensation at the mode frequency.
Verify: eigenvalue analysis on modified A matrix; time-domain simulation.
Field-test: inject small step or harmonic into AVR setpoint; record rotor swing response; verify damping matches design.

Tools

PSS/E SSAT (Small-Signal Analysis Tool, Siemens)
GE PSLF NEVA
DSATools SSAT (Powertech Labs)
DIgSILENT PowerFactory
PowerWorld TSAT
Mudpack (academic, University of Illinois)

Wide-Area Damping Control (WADC)

Addresses INTER-AREA modes that no single local PSS can fully damp.
Architecture:
- PMUs at multiple buses across the inter-area corridor stream synchronized phasors at 30-60 Hz (IEEE C37.118.2).
- Central controller computes the inter-area mode (FFT, Prony, modal-tracking algorithms) and applies a damping control law.
- Modulates HVDC link power orders, FACTS device setpoints (SVC, STATCOM, TCSC), or PSS reference signals.
Demonstrations:
- Pacific DC Intertie (California-Oregon corridor) — HVDC modulation.
- China Southern Grid — wide-area damping at HVDC links.
- Brazil — wide-area system control.
- ENTSO-E European interconnection — inter-area damping studies.
- ERCOT — prototype PMU-based oscillation detection.
Communication delay: 10-50 ms for fiber-optic substation-to-control-center links.

IBR-induced instability classes (new for high-renewable grids)

SSCI — Sub-Synchronous Control Interaction: DFIG wind farms + series-capacitor-compensated lines → oscillations at sub-synchronous frequencies (10-50 Hz). 2009 Texas Lubbock-Brownsville incident. ERCOT now requires SSR-specific studies for any new series-capacitor near IBR concentrations.
SSTI — Sub-Synchronous Torsional Interaction: HVDC link or FACTS device interaction with nearby turbine-generator shaft modes.
Weak-grid PLL instability: grid-following inverters' PLL (phase-locked loop) interacts with grid impedance on weak grids (SCR < 3), producing 1-10 Hz oscillations.
PLL-PLL interaction: multiple IBRs on the same bus interact through their PLL dynamics, destabilizing voltage at 10s-100s of Hz.

Grid-following vs Grid-forming inverters

Mode	Behavior	Grid requirement
Grid-following (legacy IBR)	Measures grid voltage angle via PLL; injects current proportional to setpoint. Current-source-like.	Requires stiff grid (SCR > 3); unstable on weak grids.
Grid-forming (modern IBR)	Acts as voltage source — sets its own frequency and voltage. Provides synthetic inertia (programmable virtual inertia constant H_eff typically 1-3 s) and damping.	Required for high-IBR grids approaching 100% renewable. IEEE 2800-2022 / P2800.2 standards.

Grid-forming pilots: AEMO South Australia (Hornsdale Power Reserve battery), Hawaiian Electric Oahu, Eirgrid SOEF mode, ERCOT pilots.

Analysis tools for IBR stability

Extended small-signal models including IBR control loops.
Impedance-based stability analysis — Nyquist criterion on grid-IBR impedance ratio.
EMT (Electro-Magnetic Transient) simulation in PSCAD or RTDS for millisecond-scale dynamics.
Frequency-domain analysis for harmonic-stability issues in high-IBR grids.

Standards

IEEE Std 421.5 — Excitation system models (PSS1A, PSS2B, PSS4B).
IEEE C37.118.1 / C37.118.2 — Synchrophasor measurement and transmission.
IEEE 2800-2022 — IBR interconnection requirements.
IEEE P2800.2 — Grid-forming-specific requirements (in development).
NERC PRC-024 — Generator off-nominal frequency capability.

Take-away. Small-signal stability: linearize DAEs around operating point → eigenvalues λ = σ ± jω → damping ratio ζ = −σ / sqrt(σ²+ω²); target ζ > 5-10%. Three rotor mode categories: LOCAL (1-3 Hz), INTER-AREA (0.1-0.7 Hz, most problematic), TORSIONAL (10-50 Hz, SSR/SSCI). Power System Stabilizer (PSS) — K · washout · two lead-lag stages · limiter on AVR reference — boosts damping 2-5% → 15-25%. Tune via participation factors and residues; standards IEEE 421.5 (PSS1A/PSS2B/PSS4B). WADC uses PMUs + central controller modulating HVDC / FACTS / PSS for inter-area damping. IBR introduces new classes (SSCI, SSTI, weak-grid PLL); grid-forming inverters per IEEE 2800-2022 are the modern solution.