/install grid-dispatch-operator-dc-power-flow
DC Power Flow
DC power flow is a linearized approximation of AC power flow, suitable for economic dispatch and contingency analysis.
DC Approximations
- Lossless lines - Ignore resistance (R ≈ 0)
- Flat voltage - All bus voltages = 1.0 pu
- Small angles - sin(θ) ≈ θ, cos(θ) ≈ 1
Result: Power flow depends only on bus angles (θ) and line reactances (X).
Bus Number Mapping
Power system bus numbers may not be contiguous (e.g., case300 has non-sequential bus IDs). Always create a mapping from bus numbers to 0-indexed array positions:
# Create mapping: bus_number -> 0-indexed position
bus_num_to_idx = {int(buses[i, 0]): i for i in range(n_bus)}
# Use mapping for branch endpoints
f = bus_num_to_idx[int(br[0])] # NOT br[0] - 1
t = bus_num_to_idx[int(br[1])]
Susceptance Matrix (B)
Build from branch reactances using bus number mapping:
# Run: scripts/build_b_matrix.py
# Or inline:
bus_num_to_idx = {int(buses[i, 0]): i for i in range(n_bus)}
B = np.zeros((n_bus, n_bus))
for br in branches:
f = bus_num_to_idx[int(br[0])] # Map bus number to index
t = bus_num_to_idx[int(br[1])]
x = br[3] # Reactance
if x != 0:
b = 1.0 / x
B[f, f] += b
B[t, t] += b
B[f, t] -= b
B[t, f] -= b
Power Balance Equation
At each bus: Pg - Pd = B[i, :] @ θ
Where:
- Pg = generation at bus (pu)
- Pd = load at bus (pu)
- θ = vector of bus angles (radians)
Slack Bus
One bus must have θ = 0 as reference. Find slack bus (type=3):
slack_idx = None
for i in range(n_bus):
if buses[i, 1] == 3:
slack_idx = i
break
constraints.append(theta[slack_idx] == 0)
Line Flow Calculation
Flow on branch from bus f to bus t (use bus number mapping):
f = bus_num_to_idx[int(br[0])]
t = bus_num_to_idx[int(br[1])]
b = 1.0 / br[3] # Susceptance = 1/X
flow_pu = b * (theta[f] - theta[t])
flow_MW = flow_pu * baseMVA
Line Loading Percentage
loading_pct = abs(flow_MW) / rating_MW * 100
Where rating_MW = branch[5] (RATE_A column).
Branch Susceptances for Constraints
Store susceptances when building constraints:
branch_susceptances = []
for br in branches:
x = br[3]
b = 1.0 / x if x != 0 else 0
branch_susceptances.append(b)
Line Flow Limits (for OPF)
Enforce thermal limits as linear constraints:
# |flow| \x3C= rating → -rating \x3C= flow \x3C= rating
flow = b * (theta[f] - theta[t]) * baseMVA
constraints.append(flow \x3C= rate)
constraints.append(flow >= -rate)
- Make sure OpenClaw is installed (local or Docker)
- Run the install command in chat:
/install grid-dispatch-operator-dc-power-flow - After installation, invoke the skill by name or use
/grid-dispatch-operator-dc-power-flow - Provide required inputs per the skill's parameter spec and get structured output
What is dc-power-flow?
DC power flow analysis for power systems. Use when computing power flows using DC approximation, building susceptance matrices, calculating line flows and lo... It is an AI Agent Skill for Claude Code / OpenClaw, with 114 downloads so far.
How do I install dc-power-flow?
Run "/install grid-dispatch-operator-dc-power-flow" in the OpenClaw or Claude Code chat to install it in one step — no extra setup required.
Is dc-power-flow free?
Yes, dc-power-flow is completely free, licensed under MIT-0. You can download, install and use it at no cost.
Which platforms does dc-power-flow support?
dc-power-flow is cross-platform and runs anywhere OpenClaw / Claude Code is available (cross-platform).
Who created dc-power-flow?
It is built and maintained by wu-uk (@wu-uk); the current version is v0.1.0.