WILDFIRE PREDICTION SYSTEM (WPS) SIMULATIONS (to be used with Prometheus training scenarios)

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Presentation transcript:

WILDFIRE PREDICTION SYSTEM (WPS) SIMULATIONS (to be used with Prometheus training scenarios)

SIMPLE MODEL 1: NO WIND OR SLOPE Open Simulation 1 – NoWindNoSlope.fgm No wind[0 m/s] No slope[0°] 30% relative humidity Uniform fuel (dry grass) Single POINT ignition Run the simulation: What fire behaviour should we expect? Where will the fire spread? What are the fire alignments? 2 km Ignition

SIMPLE MODEL 1: NO WIND OR SLOPE No wind[0 m/s] No slope[0°] 30% relative humidity Uniform fuel (dry grass) Single POINT ignition Fire behaviour: Uniform spread in all directions (400 m in 4 hours) Low intensity (no alignment) 2 km Each fire perimeter represents 20 minutes of fire spread (4 hours in total in this example)

SIMPLE MODEL 2: WIND Open Simulation 2 – WindNoSlope.fgm 10 km/hr wind [2.8 m/s] Southerly wind [180°] No slope [0°] 30% relative humidity Uniform fuel (dry grass) Single POINT ignition Run the simulation: What fire behaviour should we expect? Where will the fire spread? What are the fire alignments? 2 km Ignition

SIMPLE MODEL 2: WIND 10 km/hr wind [2.8 m/s] Southerly wind [180°] No slope [0°] 30% relative humidity Uniform fuel (dry grass) Single POINT ignition Fire behaviour: Spreading faster to the north (800 m in 4 hours) Low intensity in backing and flank fires (no alignment) Medium intensity in the head fire (alignments = 1)

SIMPLE MODEL 2: WIND Change the weather stream so that the wind speed is now 20 km/hr. 20 km/hr wind [5.6 m/s] Southerly wind [180°] No slope [0°] 30% relative humidity Uniform fuel (dry grass) Single POINT ignition Run the simulation: What fire behaviour should we expect? Where will the fire spread? What are the fire alignments? Edit daily weather conditions

SIMPLE MODEL 2: WIND 20 km/hr wind [5.6 m/s] Southerly wind [180°] No slope [0°] 30% relative humidity Uniform fuel (dry grass) Single POINT ignition Fire behaviour: Spreading even faster to the north (1.8 km in 4 hours) Low intensity in backing and flank fires (no alignment) Medium-to-high intensity in the head fire (alignments = 1)

SIMPLE MODEL 2: WIND Change the weather stream so that the wind speed is now 30 km/hr from the southeast (135°). 30 km/hr wind [8.3 m/s] Southeasterly wind [135°] No slope [0°] 30% relative humidity Uniform fuel (dry grass) Single POINT ignition Run the simulation: What fire behaviour should we expect? Where will the fire spread? What are the fire alignments? Edit daily weather conditions

SIMPLE MODEL 2: WIND 30 km/hr wind [8.3 m/s] Southeasterly wind [135°] No slope [0°] 30% relative humidity Uniform fuel (dry grass) Single POINT ignition Fire behaviour: Spreading even faster to the northwest (>3 km in 4 hours) Low-to-medium intensity in backing and flank fires (no alignment) High-to-very high intensity in the head fire (alignments = 1, high wind)

LANDSCAPE MODEL 1: SLOPE Open Simulation 3 – SlopeNoWind.fgm No wind[0 m/s] Flat terrain moving into hilly terrain 30% relative humidity Uniform fuel (dry heather) Single POINT ignition Run the simulation: What fire behaviour should we expect? Where will the fire spread? What are the fire alignments? Ignition

LANDSCAPE MODEL 1: SLOPE Open Simulation 3 – SlopeNoWind.fgm No wind[0 m/s] Flat terrain moving into hilly terrain 30% relative humidity Uniform fuel (dry heather) Single POINT ignition Run the simulation: What fire behaviour should we expect? Where will the fire spread? What are the fire alignments? 2 km Ignition Darker greys indicate low elevation Lighter greys indicate higher elevation (hills)

LANDSCAPE MODEL 1: SLOPE No wind[0 m/s] Flat terrain moving into hilly terrain 30% relative humidity Uniform fuel (dry heather) Single POINT ignition Fire behaviour: Initially a uniform spread with low intensity in all directions (no alignment) When fire moves upslope it accelerates and becomes more intense (alignment = 1 or 2) Fire decelerates on downslopes 2 km Each fire perimeter represents 20 minutes of fire spread (9 hours in total in this example)

LANDSCAPE MODEL 2: SLOPE & WIND Open Simulation 4 – SlopeAndWind.fgm 10 km/hr wind [2.8 m/s] Westerly wind [270°] Flat terrain moving into hilly terrain 30% relative humidity Uniform fuel (dry heather) Single POINT ignition Run the simulation: What fire behaviour should we expect? Where will the fire spread? What are the fire alignments? 2 km Ignition Darker greys indicate low elevation Lighter greys indicate higher elevation (hills)

LANDSCAPE MODEL 2: SLOPE & WIND 10 km/hr wind [2.8 m/s] Westerly wind [270°] Flat terrain moving into hilly terrain 30% relative humidity Uniform fuel (dry heather) Single POINT ignition Fire behaviour: Fire moves with the slope and wind eastwards Head fire burns with medium intensity, but this increases to high intensity on the steepest slopes (yellow patches). Fire burns with low intensity against the wind and slope (no alignment) 2 km Each fire perimeter represents 20 minutes of fire spread (9 hours in total in this example)

LANDSCAPE MODEL 2: SLOPE & WIND Change the weather stream so that the wind direction is now from the northwest (315°). 20 km/hr wind [5.6 m/s] Northwesterly wind [315°] Flat terrain moving into hilly terrain 30% relative humidity Uniform fuel (dry heather) Single POINT ignition Run the simulation: What fire behaviour should we expect? Where will the fire spread? What are the fire alignments? Edit daily weather conditions

LANDSCAPE MODEL 2: SLOPE & WIND 20 km/hr wind [5.6 m/s] Northwesterly wind [315°] Flat terrain moving into hilly terrain 30% relative humidity Uniform fuel (dry heather) Single POINT ignition Fire behaviour: Fire moves with the slope and wind southeastwards Head fire burns with medium intensity, but this increases to high intensity on the steepest slopes (yellow patches). Head fire decreases intensity when going down slope, even with the wind (alignment = 1 or 2, rather than 2 or 3) 2 km Lower intensity and rate of spread Highest rate of spread and intensity

LANDSCAPE MODEL 3: ASPECT Open Simulation 5 – AspectSlope.fgm No wind[0 m/s] Valley bottom with SE and NW facing slopes either side 30% relative humidity Uniform fuel (dry heather) Single POINT ignition Run the simulation: What fire behaviour should we expect? Where will the fire spread? What are the fire alignments? Ignition SE-facing slopes NW-facing slopes

LANDSCAPE MODEL 3: ASPECT Open Simulation 5 – AspectSlope.fgm No wind[0 m/s] Valley bottom with SE and NW facing slopes either side 30% relative humidity Uniform fuel (dry heather) Single POINT ignition Run the simulation: What fire behaviour should we expect? Where will the fire spread? What are the fire alignments? 2 km Ignition Darker greys indicate low elevation Lighter greys indicate higher elevation (hills)

LANDSCAPE MODEL 3: ASPECT No wind[0 m/s] Valley bottom with SE and NW facing slopes either side 30% relative humidity Uniform fuel (dry heather) Single POINT ignition Fire behaviour: Fire moves with the slope Two head fires moving up both slopes. Head fire along SE-facing slope moves quicker and with more intenisty due to aspect and greater slope (alignment = 2). Head fire along NW-facing slopes moves slower (alignment = 1). Lower intensity fire moves up and down the valley. 2 km Lower intensity and rate of spread Highest rate of spread and intensity

SIMPLE MODEL 3: WIND SHIFT Open Simulation 6 – WindShift.fgm 20 km/hr wind [5.6 m/s] Southerly wind [180°] changing to Westerly wind [270°] No slope[0°] 30% relative humidity Uniform fuel (dry grass) Single POINT ignition Run the simulation: What fire behaviour should we expect? Where will the fire spread? What are the fire alignments? 2 km Ignition

SIMPLE MODEL 3: WIND SHIFT 20 km/hr wind [5.6 m/s] Southerly wind [180°] changing to Westerly wind [270°] No slope [0°] 30% relative humidity Uniform fuel (dry grass) Single POINT ignition Fire behaviour: Spreading to the north (600 m in 2 hours) Low intensity in backing and flank fires (no alignment) When wind changes direction, the slow-moving low-intensity east flank fire becomes a large quick- moving (1 km in 2 hours) high-intensity head fire. 2 km

SIMPLE MODEL 3: WIND SHIFT Change the wind speed and wind direction in the weather stream by clicking on “edit” and then “hourly”. Here you can adjust the time of the wind shift and the direction that it shifts to, as well as the wind speed. Try doing the same for some of the landscape models used previously. Edit hourly weather conditions

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