How the network and interconnections are represented
Transmission is represented at the zonal level. Inter-zonal flows are bounded by interface limits and solved jointly with unit commitment and dispatch, so congestion separates zonal prices endogenously.
Zonal topology
The footprint is divided into 18 settlement zones connected by transmission interfaces. Each interface is a zone-to-zone path with a transfer limit applied as a constraint in unit commitment and economic dispatch, with flows bidirectional and bounded symmetrically.
Transmission line ends are mapped to zones following the same priority order used to site generation. The sum of line capacities between two zones gives the zone-to-zone capacity, which is then derated by a factor to reflect physical grid constraints. This derating is determined by looking at congestion patterns in the backtest. A small per-MWh flow penalty of $2/MWh, again set against nodal basis behavior in the backtest, is also applied.
Note that the split of Oklahoma Gas and Electric into OKGE (East) and OKGE (West) (see the Overview) allows the model to capture the sizeable congestion patterns that occur historically within this zone, by separating the wind-rich west from the load-rich east.
Interconnection to SPP West and non-SPP markets
SPP exchanges power with neighboring systems: MISO, ERCOT, WECC, the SPP West footprint, and smaller neighbors. Rather than co-optimizing flows with those external systems, the model represents the exchange as historical interchange netted into the relevant boundary zones:
- MISO: boundary-zone interchange on the eastern boundary
- ERCOT: interchange across the direct-current ties, netted at the southern boundary zone
- WECC and SPP West: interchange on the western boundary
- Associated Electric (AECI), Southwestern Power Administration (SPA), and other neighbors: boundary-zone interchange mapped from external balancing-authority data
External balancing-authority flows are taken from EIA-930 (and SPP tie-flow data where more granular), allocated to SPP boundary zones using fixed weights calibrated to historical interface flow patterns, and subtracted from those zones’ load. In effect the interconnection behaves as a fixed exchange profile at the footprint edge rather than a capacity-limited interface the model optimizes against. Explicit, capacity-constrained boundary interfaces are a planned future enhancement. No wheeling or hurdle charge is applied on flow within the footprint or on import and export with external systems.
Exports are not fully firm, however. When the footprint is tight, typically during peak hours or a steep net-load ramp, the model can pull its net exports back home rather than continue serving neighbors, but only at an elevated cost. This is a demand-response mechanism on each boundary zone’s net export: as the zone’s internal price rises from $500 to $1,000/MWh, progressively more of the net export is retracted, until at $1,000/MWh the full net export is withheld. Below $500/MWh exports flow normally, so the model only pulls interchange back when keeping the energy at home is worth more than the export.
Transmission expansion
Interface limits evolve over the forecast horizon as planned transmission is added. Two sources drive this:
- SPP transmission planning (STEP / Integrated Transmission Plan): curated SPP-approved projects, including major backbone upgrades, phased in by their planned in-service dates.
- NREL national transmission scenarios: longer-term gross inter-zonal capacity additions, applied to the out-years and to zone pairs the SPP plan does not cover.
Both sources are used together: where they cover the same zone pair, the SPP planning overlay takes precedence, and the NREL scenarios supply the additional longer-term expansion elsewhere. Added capacity raises the corresponding interface limit from its in-service year onward. The SPP-approved projects below are included directly.
The curated SPP overlay is drawn from the 2025 Integrated Transmission Plan. Its backbone projects, largely a 765 kV loop across Oklahoma and the Texas panhandle, are:
| In-service | Project | Zones | Voltage | Added capacity | Status |
|---|---|---|---|---|---|
| 2030 | Seminole – Southwest Shreveport (plus STATCOMs) | CSWS to OKGE | 765 kV | 2,340 MW | Approved |
| 2032 | Anthem – Seminole | CSWS to OKGE | 765 kV | 2,340 MW | Approved |
| 2032 | Woodward – Crawfish Draw | SPS to WFEC | 765 kV | 2,340 MW | Approved |
| 2032 | Woodward – Potter County | SPS to WFEC | 765 kV | 2,340 MW | Deferred |
| 2032 | Woodward – Viola | WFEC to WR | 765 kV | 2,340 MW | Deferred |
| 2032 | Viola – Anthem | CSWS to WR | 765 kV | 2,340 MW | Deferred |
| 2032 | Minco – Crawfish Draw | OKGE to SPS | 765 kV | 2,340 MW | Study |
| 2032 | Belfield – Roundup | BEPC to WAPW | 345 kV | 700 MW | Approved (western zones) |
“Approved” projects carry a notification to construct; “deferred” and “study” projects are included at their planned ratings but flagged for confirmation in later planning cycles.
Data sources
| Source | Description | Link |
|---|---|---|
| SPP STEP / transmission planning | Planned transmission additions and in-service dates | SPP Transmission Planning |
| NREL transmission scenarios | Long-term inter-zonal expansion | NREL NTP Study |
| EIA-930 | Historical inter-BA flows for boundary interchange allocation | EIA-930 |