Voltage Stability Part 2: The Two-Bus Model — Setting Up the Voltage Stability Problem

ByMinh-Quan Tran
Voltage Stability Series — Part 2 of 5

The Two-Bus Model: Setting Up the Voltage Stability Problem

📅 June 2026📖 ~8 min read🏷 Power Systems · Stability Analysis
Voltage Stability Series — Theory
  1. Part 1 of 5 — What is Voltage Stability? Definition, Classification and Physical Intuition
  2. Part 2 of 5 — The Two-Bus Model: Setting Up the Voltage Stability Problem
  3. Part 3 of 5 — Deriving the PV Curve: The Nose Curve from First Principles
  4. Part 4 of 5 — The Nose Point: Maximum Loadability, Critical Voltage and the Jacobian
  5. Part 5 of 5 — Voltage Collapse: QV Curves, OLTC Feedback and Stability Indices
Contents
  1. Circuit description and notation
  2. Power balance equations (1)–(4)
  3. The quadratic in V₂ — equation (5)
  4. Why two solutions exist

1. The two-bus model

The two-bus system is the canonical analytical model for voltage stability. A source bus (Bus 1, infinite bus V₁∠δ) supplies a load bus (Bus 2, V₂∠0°) through line impedance Z = R + jX. The load draws complex power S = P + jQ.

Bus 1V₁∠δZ = R + jXBus 2V₂∠0P+jQI
Figure 1. Two-bus system. Bus 1 (infinite bus, V₁∠δ) supplies the load bus (Bus 2, V₂∠0) through impedance Z = R + jX. Current I flows from left to right.

Notation

Symbol Meaning Units
V₁ Sending-end voltage magnitude pu or kV
V₂ Receiving-end (load bus) voltage magnitude pu or kV
δ Angle between V₁ and V₂ rad or °
Z = R + jX Line impedance Ω or pu
P, Q Active and reactive power at load bus MW, MVAr

2. Power balance equations

Taking Bus 2 as the reference (V₂∠0°), the complex power at the load bus is:

S = P + jQ = V₂ · I*(1)

Line current from Bus 1 to Bus 2:

I = (V₁ − V₂) / Z(2)

Substituting (2) into (1) and separating real and imaginary parts:

P = (V₁·V₂·cosδ − V₂²·R) / (R² + X²)(3)
Q = (V₁·V₂·sinδ − V₂²·X) / (R² + X²)(4)

Equations (3) and (4) are the two-bus power flow equations. With Q = P·tanφ (fixed power factor) and V₁ fixed, we have two equations in two unknowns (V₂ and δ).

3. The quadratic in V₂

Eliminating δ entirely via the voltage phasor geometry gives:

V₁² = V₂² + 2(PR + QX) + (P² + Q²)(R² + X²) / V₂²(5)

Multiplying through by V₂² and rearranging gives a quadratic in V₂². Setting u = V₂²:

u² − [V₁² − 2(PR + QX)]·u + (P² + Q²)(R² + X²) = 0(6)

This quadratic has two roots — the mathematical origin of the PV curve’s two branches, derived in full in Part 3.

4. Why two solutions exist

Both roots are real under normal loading: one is the high-voltage (stable) operating point, the other is an abnormal low-voltage state. As loading P increases, the two roots approach each other. When they coincide, the discriminant equals zero — that is the nose point, the subject of Part 4.

Looking ahead

Part 3 solves the quadratic explicitly, plots the complete nose curve for three power factors, and shows how reactive compensation shifts the stability boundary.

References

  1. P. Kundur, Power System Stability and Control, McGraw-Hill, 1994 — Chapters 14–15.
  2. T. Van Cutsem and C. Vournas, Voltage Stability of Electric Power Systems, Springer, 1998.
  3. A. Bergen and V. Vittal, Power Systems Analysis, 2nd ed., Prentice Hall, 2000.
  4. J. Grainger and W. Stevenson, Power Systems Analysis, McGraw-Hill, 1994.

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