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The
Optimal Power Flow module is an intelligent load flow
that employs techniques to automatically adjust the
power system control settings while simultaneously
solving the load flows and optimizing operating conditions
within specific constraints. Optimal Power Flow uses state-of-the-art techniques
including an interior point method with barrier functions
and infeasibility handling to achieve ultimate accuracy
and flexibility in solving systems of any size. |
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- Solve multiple objectives simultaneously
- Interior point method with barrier functions
- Minimize power losses
- Active power optimization
- Reactive power optimization
- Optimal dispatch
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- Component & operating constraints
- Transmission line interface limit constraints
- Bus constraint with weighting factors
- Branch flow constraint with weighting factors
- Control limit constraints
- Diverse operating conditions
- Multiple loading categories
- Global & individual bus diversity factors
- Multiple demand factors
- Unlimited configurations
- Different nameplate data
- Smooth function of any variables
- Produce results with incredible speed
- User-controlled infeasibility handling
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- Comprehensive objectives & constraints
- Accurate AC model
- Increase system efficiencies
- Reduce operating costs
- Improve electrical system performance
- Increase reliability
- Strengthen security
- Short-term & long-term planning
- State-of-the-art interior point algorithm
- Logarithmic barrier functions (handles equality & inequality constraints)
- Controlled solution parameters
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- Flag critical & marginal cable temperatures
- Report all physical & calculated optimal settings
- Use Crystal Reports® for full color, customizable reports
- Export output reports to your favorite word processor
- Graphical display of results
- Report altered changes
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- Minimize system real & reactive power losses
- Minimize generation fuel costs
- Minimize system energy costs
- Maximize system performance
- Optimize power exchange with other systems (on-site generation, utilities, IPP’s, & power grids)
- Minimize load shedding
- Minimize generator fuel cost or heat rate with different cost models & fuel profiles
- Control generator’s MW (governor) & MVAR
- (AVR) settings within the specified limits
- Control voltage regulators (transformer tap positions) within the specified limits
- Size capacitors within the specified limits
- Maximize voltage & flow security indices
- Determine control settings
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