SLIDE 1
Tobias Andersson Granberg, Ta0ana Polishchuk, Valen0n Polishchuk, Chris&ane Schmidt
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 2
Automatic Design of Aircraft Arrival Routes with Limited Turning - - PowerPoint PPT Presentation
Automatic Design of Aircraft Arrival Routes with Limited Turning - - PowerPoint PPT Presentation
Automatic Design of Aircraft Arrival Routes with Limited Turning Angle Tobias Andersson Granberg, Ta0ana Polishchuk, Valen0n Polishchuk, Chris&ane Schmidt Introduction: Air transportation, SIDs + STARs Grid-based IP formulation Experimental
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 3
Air transportation:
SLIDE 4
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 3
Air transportation:
- Significant growth over the last decades
SLIDE 5
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 3
Air transportation:
- Significant growth over the last decades
- International Air Transport Association (IATA) projected that the
number of passengers will double to reach 7 billion/year by 2034
SLIDE 6
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 3
Air transportation:
- Significant growth over the last decades
- International Air Transport Association (IATA) projected that the
number of passengers will double to reach 7 billion/year by 2034
- Terminal Maneuvering Area (TMA), i.e., the area surrounding one or
more neighboring aerodromes, is particularly affected by congestion
SLIDE 7
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 3
Air transportation:
- Significant growth over the last decades
- International Air Transport Association (IATA) projected that the
number of passengers will double to reach 7 billion/year by 2034
- Terminal Maneuvering Area (TMA), i.e., the area surrounding one or
more neighboring aerodromes, is particularly affected by congestion
- Design Arrival and Departure procedures ➜ higher throughput
SLIDE 8
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 3
Air transportation:
- Significant growth over the last decades
- International Air Transport Association (IATA) projected that the
number of passengers will double to reach 7 billion/year by 2034
- Terminal Maneuvering Area (TMA), i.e., the area surrounding one or
more neighboring aerodromes, is particularly affected by congestion
- Design Arrival and Departure procedures ➜ higher throughput
- In Air Traffic Management (ATM): humans-in-the-loop!
SLIDE 9
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 3
Air transportation:
- Significant growth over the last decades
- International Air Transport Association (IATA) projected that the
number of passengers will double to reach 7 billion/year by 2034
- Terminal Maneuvering Area (TMA), i.e., the area surrounding one or
more neighboring aerodromes, is particularly affected by congestion
- Design Arrival and Departure procedures ➜ higher throughput
- In Air Traffic Management (ATM): humans-in-the-loop!
๏ Planes constantly monitored/guided by air traffic controllers (ATCOs)
SLIDE 10
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 3
Air transportation:
- Significant growth over the last decades
- International Air Transport Association (IATA) projected that the
number of passengers will double to reach 7 billion/year by 2034
- Terminal Maneuvering Area (TMA), i.e., the area surrounding one or
more neighboring aerodromes, is particularly affected by congestion
- Design Arrival and Departure procedures ➜ higher throughput
- In Air Traffic Management (ATM): humans-in-the-loop!
๏ Planes constantly monitored/guided by air traffic controllers (ATCOs) ๏ Safe separation between aircraft
SLIDE 11
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 3
Air transportation:
- Significant growth over the last decades
- International Air Transport Association (IATA) projected that the
number of passengers will double to reach 7 billion/year by 2034
- Terminal Maneuvering Area (TMA), i.e., the area surrounding one or
more neighboring aerodromes, is particularly affected by congestion
- Design Arrival and Departure procedures ➜ higher throughput
- In Air Traffic Management (ATM): humans-in-the-loop!
๏ Planes constantly monitored/guided by air traffic controllers (ATCOs) ๏ Safe separation between aircraft ➡ Route design should:
SLIDE 12
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 3
Air transportation:
- Significant growth over the last decades
- International Air Transport Association (IATA) projected that the
number of passengers will double to reach 7 billion/year by 2034
- Terminal Maneuvering Area (TMA), i.e., the area surrounding one or
more neighboring aerodromes, is particularly affected by congestion
- Design Arrival and Departure procedures ➜ higher throughput
- In Air Traffic Management (ATM): humans-in-the-loop!
๏ Planes constantly monitored/guided by air traffic controllers (ATCOs) ๏ Safe separation between aircraft ➡ Route design should: ๏ lead to traffic patterns with “low complexity”
SLIDE 13
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 3
Air transportation:
- Significant growth over the last decades
- International Air Transport Association (IATA) projected that the
number of passengers will double to reach 7 billion/year by 2034
- Terminal Maneuvering Area (TMA), i.e., the area surrounding one or
more neighboring aerodromes, is particularly affected by congestion
- Design Arrival and Departure procedures ➜ higher throughput
- In Air Traffic Management (ATM): humans-in-the-loop!
๏ Planes constantly monitored/guided by air traffic controllers (ATCOs) ๏ Safe separation between aircraft ➡ Route design should: ๏ lead to traffic patterns with “low complexity” ๏ avoid creating conflict points
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 4
At most airports predesigned standard routes for departure and arrival:
SLIDE 15
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 4
At most airports predesigned standard routes for departure and arrival: Standard Instrument Departures (SIDs) and Standard Terminal Arrival Routes (STARs)
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 4
017° 30’ AMDT 80 29 SEP 2005 CHANGE: SID to ARS, DKR, NOSLI and TRS Swedish Civil Aviation Authority AD 2–ESSA–4–21 RWY 01L AIP-SVERIGE/SWEDEN STOCKHOLM/ARLANDA AERODROME FMS/RNAV SID 018° 00’ 60° 00’ 59° 30’ 018° 00’ 017° 30’ 59° 30’ 60° 00’ 018° 30’ 018° 30’ K O G A V 3 C ( K O G A 3 C ) ( 3 2 . 7 ° T ) < 2 6 . 2 > SA403 RESNA 3 C (RESN 3C) KOGAV SA850 BABAP DKR 116.80 DVOR DUNKER 591225.8N 0170043.5E NOSLI LEGEND See GEN 2.3 Tracks are in MAG. Tracks within brackets are in True. ELEV and ALT in ft MSL VAR 3.5°-4.5° E 2005 Fly-over wpt Fly-by wpt INITIAL CLIMB CLEARANCE Common to all SIDs published on this chart. Unless otherwise specified, climb to 5000 ft. 585616.5N 0173008.0E TROSA DVOR/DME TRS 114.30 90X elev 213 ft 593510.3N 0163901.4E AROS DVOR/DME ARS 112.80 75X elev 50 ft 594138.3N 0180335.6E ANE 113.30 80X elev 108 ft 594247.8N 0175109.2E DME ANW 112.05 57Y elev 163 ft 593515.7N 0174910.9E DME ASW 113.75 84Y elev 232 ft 594459.3N 0184600.6E NORTEL VOR/DME NTL 116.30 110X elev 68 ft DME 593154.1N 0181212.0E TEBBY DVOR/DME TEB 117.10 118X elev197 ft 593912.4N 0175451.9E ARLANDA DVOR/DME ARL 116.00 107X elev141 ft RESNA (003.4° T) < 31.2 > SA401 ( 7 9 . 9 ° T ) < 6 . 2 > ( 9 . 3 ° T ) < 1 8 . 7 > SA402 N O R T E L 3 C ( N T L 3 C ) (003.4° T) < 6.8 > (010.4° T) < 4.0 > SA421 (ARL DME 1.3) SA851 < 4 . > < 6.2 > SA723 < 4 . 5 > (224.1° T) AROS 4 C (ARS 4C) SA701 2 6 3 ° ( 2 6 6 . 9 ° T ) MENGA 1 C (MENA 1C) ( 9 9 . 3 ° T ) < 2 8 . 7 > TROSA 4 C (TRS 4C) 180° (183.1° T) < 35.2 > ( 1 9 7 . 3 ° T ) < 7 . > (118.4° T) < 6.9 > SA702 SA703 BABAP NEKLA < 30.6 > (145.7°) 593813.9N 0175726.5E DME ASE 114.45 91Y elev 141 ft 2 9 9 ° 359° 359° 7 6 ° 006° 2 4 9 ° (252.6° T) 221° 1 4 1 ° 9 5 ° 115° 194° 8 6 ° SA422 MENGA BABAP 3 C (BABA 3C) 153° (157.1°T) < 21.5 > < 3 . > < 27.5 > DUNKER 4C (DKR 4C) 218° (221.9° T) < 25.4 > <2.2> N O S L I 4 C ( N O S L 4 C ) 1 9 6 ° ( 1 9 9 . 3 ° T ) < 2 8 . 6 > SA724At most airports predesigned standard routes for departure and arrival: Standard Instrument Departures (SIDs) and Standard Terminal Arrival Routes (STARs)
AIRAC AMDT 5/2012 23 AUG 2012 CHANGE: New STAR NILUG 1M. Deleted TRS 3M, VAR, pagina LFV AD 2–ESSA–4–5 RWY 01L/01R AIP SWEDEN STOCKHOLM/ARLANDA AERODROME STAR Instrument LEGEND See GEN 2.3 BRG are MAG ELEV and ALT in ft MSL km 10 0 10 20 30 km NM 5 0 10 20 NM Description of ELTOK, NILUG and XILAN see AD 2–ESSA–4–6 V A R 4 °- 5
- M
- 2
STAR Stockholm, RWY 01L/01R SID Stockholm, RWY 01L
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 5
SIDs/STARs:
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 5
SIDs/STARs:
- Designed manually
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 5
SIDs/STARs:
- Designed manually
- No optimal routes for any specific criteria
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 5
SIDs/STARs:
- Designed manually
- No optimal routes for any specific criteria
- here: mathematical programming framework for finding
- ptimal STAR merge trees
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
6
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
6
Input:
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
6
Input: locations of the entry points to the TMA
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
6
Input: locations of the entry points to the TMA location and direction of the airport runway
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
6
Input: locations of the entry points to the TMA location and direction of the airport runway Output:
SLIDE 26
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
6
Input: locations of the entry points to the TMA location and direction of the airport runway Output: arrival tree that merges traffic from the entries to the runway,
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
6
Input: locations of the entry points to the TMA location and direction of the airport runway Output: arrival tree that merges traffic from the entries to the runway, i.e., a tree that has the entries as leaves and the runway as the root
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
6
Input: locations of the entry points to the TMA location and direction of the airport runway Output: arrival tree that merges traffic from the entries to the runway, i.e., a tree that has the entries as leaves and the runway as the root (arborescence oriented differently than usual)
SLIDE 29
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
6
Input: locations of the entry points to the TMA location and direction of the airport runway Output: arrival tree that merges traffic from the entries to the runway, i.e., a tree that has the entries as leaves and the runway as the root (arborescence oriented differently than usual)
- 1. No more than two routes merge at a point: in-degree ≤ 2
SLIDE 30
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
6
Input: locations of the entry points to the TMA location and direction of the airport runway Output: arrival tree that merges traffic from the entries to the runway, i.e., a tree that has the entries as leaves and the runway as the root (arborescence oriented differently than usual)
- 1. No more than two routes merge at a point: in-degree ≤ 2
- 2. Merge point separation: distance threshold L
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
6
Input: locations of the entry points to the TMA location and direction of the airport runway Output: arrival tree that merges traffic from the entries to the runway, i.e., a tree that has the entries as leaves and the runway as the root (arborescence oriented differently than usual)
- 1. No more than two routes merge at a point: in-degree ≤ 2
- 2. Merge point separation: distance threshold L
- 3. No sharp turns: angle threshold 𝛽, minimum edge length L
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
6
Input: locations of the entry points to the TMA location and direction of the airport runway Output: arrival tree that merges traffic from the entries to the runway, i.e., a tree that has the entries as leaves and the runway as the root (arborescence oriented differently than usual)
- 1. No more than two routes merge at a point: in-degree ≤ 2
- 2. Merge point separation: distance threshold L
- 3. No sharp turns: angle threshold 𝛽, minimum edge length L
- 4. Obstacle avoidance
SLIDE 33
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
6
Input: locations of the entry points to the TMA location and direction of the airport runway Output: arrival tree that merges traffic from the entries to the runway, i.e., a tree that has the entries as leaves and the runway as the root (arborescence oriented differently than usual)
- 1. No more than two routes merge at a point: in-degree ≤ 2
- 2. Merge point separation: distance threshold L
- 3. No sharp turns: angle threshold 𝛽, minimum edge length L
- 4. Obstacle avoidance
- 5. STAR–SID separation:
SLIDE 34
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
6
Input: locations of the entry points to the TMA location and direction of the airport runway Output: arrival tree that merges traffic from the entries to the runway, i.e., a tree that has the entries as leaves and the runway as the root (arborescence oriented differently than usual)
- 1. No more than two routes merge at a point: in-degree ≤ 2
- 2. Merge point separation: distance threshold L
- 3. No sharp turns: angle threshold 𝛽, minimum edge length L
- 4. Obstacle avoidance
- 5. STAR–SID separation:
STAR–SID crossings far from the runway,
SLIDE 35
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
6
Input: locations of the entry points to the TMA location and direction of the airport runway Output: arrival tree that merges traffic from the entries to the runway, i.e., a tree that has the entries as leaves and the runway as the root (arborescence oriented differently than usual)
- 1. No more than two routes merge at a point: in-degree ≤ 2
- 2. Merge point separation: distance threshold L
- 3. No sharp turns: angle threshold 𝛽, minimum edge length L
- 4. Obstacle avoidance
- 5. STAR–SID separation:
STAR–SID crossings far from the runway,
where arriving and departing planes sufficiently separated vertically (difference of descend and climb slopes)
SLIDE 36
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
7
Objective function:
SLIDE 37
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
7
Objective function: ๏ Short flight routes for aircraft
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
7
Objective function: ๏ Short flight routes for aircraft ➡ Minimize total length of the routes
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
7
Objective function: ๏ Short flight routes for aircraft ➡ Minimize total length of the routes ๏ STAR tree should "occupy little space"
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
7
Objective function: ๏ Short flight routes for aircraft ➡ Minimize total length of the routes ๏ STAR tree should "occupy little space" ➡ Minimize total length of the edges
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
7
Objective function: ๏ Short flight routes for aircraft ➡ Minimize total length of the routes ๏ STAR tree should "occupy little space" ➡ Minimize total length of the edges paths length
SLIDE 42
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
7
Objective function: ๏ Short flight routes for aircraft ➡ Minimize total length of the routes ๏ STAR tree should "occupy little space" ➡ Minimize total length of the edges paths length tree weight
SLIDE 43
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Optimal STAR merge trees
7
Objective function: ๏ Short flight routes for aircraft ➡ Minimize total length of the routes ๏ STAR tree should "occupy little space" ➡ Minimize total length of the edges paths length tree weight Pareto frontier of multicriteria optimization problem: set of Pareto optimal solutions (cannot be improved with respect to one of the objectives without sacrificing on the other)
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 8
Grid-based IP formulation
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
9
SLIDE 46
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
9
๏ Square grid in the TMA
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
9
๏ Square grid in the TMA ๏ Snap locations of the entry points and the runway onto the grid
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
9
๏ Square grid in the TMA ๏ Snap locations of the entry points and the runway onto the grid ๏ P: set of (snapped) entry points
SLIDE 49
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
9
๏ Square grid in the TMA ๏ Snap locations of the entry points and the runway onto the grid ๏ P: set of (snapped) entry points ๏ r: runway
SLIDE 50
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
9
๏ Square grid in the TMA ๏ Snap locations of the entry points and the runway onto the grid ๏ P: set of (snapped) entry points ๏ r: runway ๏ Side of the grid pixel: L (➜merge point separation)
SLIDE 51
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
9
๏ Square grid in the TMA ๏ Snap locations of the entry points and the runway onto the grid ๏ P: set of (snapped) entry points ๏ r: runway ๏ Side of the grid pixel: L (➜merge point separation) ๏ G = (V,E):
SLIDE 52
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
9
๏ Square grid in the TMA ๏ Snap locations of the entry points and the runway onto the grid ๏ P: set of (snapped) entry points ๏ r: runway ๏ Side of the grid pixel: L (➜merge point separation) ๏ G = (V,E): ๏ Every grid node connected to its 8 neighbors
SLIDE 53
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
9
๏ Square grid in the TMA ๏ Snap locations of the entry points and the runway onto the grid ๏ P: set of (snapped) entry points ๏ r: runway ๏ Side of the grid pixel: L (➜merge point separation) ๏ G = (V,E): ๏ Every grid node connected to its 8 neighbors ๏ G is bi-directed
SLIDE 54
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
9
๏ Square grid in the TMA ๏ Snap locations of the entry points and the runway onto the grid ๏ P: set of (snapped) entry points ๏ r: runway ๏ Side of the grid pixel: L (➜merge point separation) ๏ G = (V,E): ๏ Every grid node connected to its 8 neighbors ๏ G is bi-directed ๏ Only exceptions:
SLIDE 55
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
9
๏ Square grid in the TMA ๏ Snap locations of the entry points and the runway onto the grid ๏ P: set of (snapped) entry points ๏ r: runway ๏ Side of the grid pixel: L (➜merge point separation) ๏ G = (V,E): ๏ Every grid node connected to its 8 neighbors ๏ G is bi-directed ๏ Only exceptions: ๏ Entry points (no incoming edges)
SLIDE 56
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
9
๏ Square grid in the TMA ๏ Snap locations of the entry points and the runway onto the grid ๏ P: set of (snapped) entry points ๏ r: runway ๏ Side of the grid pixel: L (➜merge point separation) ๏ G = (V,E): ๏ Every grid node connected to its 8 neighbors ๏ G is bi-directed ๏ Only exceptions: ๏ Entry points (no incoming edges) ๏ r (no outgoing edges)
SLIDE 57
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
9
๏ Square grid in the TMA ๏ Snap locations of the entry points and the runway onto the grid ๏ P: set of (snapped) entry points ๏ r: runway ๏ Side of the grid pixel: L (➜merge point separation) ๏ G = (V,E): ๏ Every grid node connected to its 8 neighbors ๏ G is bi-directed ๏ Only exceptions: ๏ Entry points (no incoming edges) ๏ r (no outgoing edges) ๏ length of an edge (i, j)
`i,j
SLIDE 58
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
9
๏ Square grid in the TMA ๏ Snap locations of the entry points and the runway onto the grid ๏ P: set of (snapped) entry points ๏ r: runway ๏ Side of the grid pixel: L (➜merge point separation) ๏ G = (V,E): ๏ Every grid node connected to its 8 neighbors ๏ G is bi-directed ๏ Only exceptions: ๏ Entry points (no incoming edges) ๏ r (no outgoing edges) ๏ length of an edge (i, j) ๏ IP formulation is based on flow IP formulation for Steiner trees (Min Cost Flow Steiner arborescence)
`i,j
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
10
SLIDE 60
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
10
decision variables: edge e participates in the STAR.
xe
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
10
decision variables: edge e participates in the STAR. flow variables: gives the flow on edge e = (i, j) (i.e., from i to j )
xe fe
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
10
decision variables: edge e participates in the STAR. flow variables: gives the flow on edge e = (i, j) (i.e., from i to j )
xe fe
X
k:(k,i)∈E
fki − X
j:(i,j)∈E
fij = 8 > < > : |P| i = r −1 i ∈ P i ∈ V \ {P ∪ r} xe ≥ fe N ∀e ∈ E fe ≥ 0 ∀e ∈ E xe ∈ {0, 1} ∀e ∈ E
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
11
Objective functions: min X
e∈E
`efe (1) min X
e∈E
`exe (2)
SLIDE 64
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
11
Objective functions: min X
e∈E
`efe (1) min X
e∈E
`exe (2)
paths length
SLIDE 65
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
11
Objective functions: min X
e∈E
`efe (1) min X
e∈E
`exe (2)
paths length tree weight
SLIDE 66
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
12
Degree constraints:
X
k:(k,i)∈E
xki ≤ 2 ∀i ∈ V \ {P ∪ r} X
j:(i,j)∈E
xij ≤ 1 ∀i ∈ V \ {P ∪ r} X
k:(k,r)∈E
xkr = 1 X
j:(r,j)∈E
xrj ≤ 0 X
k:(k,i)∈E
xki ≤ 0 ∀i ∈ P X
j:(i,j)∈E
xij = 1 ∀i ∈ P
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ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
13
Turn angle constraints:
SLIDE 68
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
13
Turn angle constraints:
Ae
SLIDE 69
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
13
Turn angle constraints:
Ae
ae = |Ae|
SLIDE 70
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
13
Turn angle constraints: aexe + X
f∈Ae
xf ≤ ae ∀e ∈ E
Ae
ae = |Ae|
SLIDE 71
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Grid-based IP formulation
14
SID constraints:
We disallow STAR edges to intersect SID edges within distance d from the runway.
SLIDE 72
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 15
Experimental Study: Arlanda Airport
SLIDE 73
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
16
Stockholm TMA:
SLIDE 74
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
16
Stockholm TMA: ๏ Arlanda’s runway 19L
SLIDE 75
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
16
Stockholm TMA: ๏ Arlanda’s runway 19L ๏ Four main entry points: NILUG, XILAN, HMR, and ARS
SLIDE 76
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
16
Stockholm TMA: ๏ Arlanda’s runway 19L ๏ Four main entry points: NILUG, XILAN, HMR, and ARS ๏ Square grids of size 14x20 and 25x30
SLIDE 77
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
16
Stockholm TMA: ๏ Arlanda’s runway 19L ๏ Four main entry points: NILUG, XILAN, HMR, and ARS ๏ Square grids of size 14x20 and 25x30 ๏ Solve IP with
SLIDE 78
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
16
Stockholm TMA: ๏ Arlanda’s runway 19L ๏ Four main entry points: NILUG, XILAN, HMR, and ARS ๏ Square grids of size 14x20 and 25x30 ๏ Solve IP with ❖ Both objective functions
SLIDE 79
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
16
Stockholm TMA: ๏ Arlanda’s runway 19L ๏ Four main entry points: NILUG, XILAN, HMR, and ARS ๏ Square grids of size 14x20 and 25x30 ๏ Solve IP with ❖ Both objective functions ❖ Degree constraints
SLIDE 80
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
16
Stockholm TMA: ๏ Arlanda’s runway 19L ๏ Four main entry points: NILUG, XILAN, HMR, and ARS ๏ Square grids of size 14x20 and 25x30 ๏ Solve IP with ❖ Both objective functions ❖ Degree constraints ❖ Turn Angle constraints
SLIDE 81
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
16
Stockholm TMA: ๏ Arlanda’s runway 19L ๏ Four main entry points: NILUG, XILAN, HMR, and ARS ๏ Square grids of size 14x20 and 25x30 ๏ Solve IP with ❖ Both objective functions ❖ Degree constraints ❖ Turn Angle constraints ๏ 8 grid directions
SLIDE 82
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
16
Stockholm TMA: ๏ Arlanda’s runway 19L ๏ Four main entry points: NILUG, XILAN, HMR, and ARS ๏ Square grids of size 14x20 and 25x30 ๏ Solve IP with ❖ Both objective functions ❖ Degree constraints ❖ Turn Angle constraints ๏ 8 grid directions ๏ Postprocessing for smoother paths:
SLIDE 83
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
16
Stockholm TMA: ๏ Arlanda’s runway 19L ๏ Four main entry points: NILUG, XILAN, HMR, and ARS ๏ Square grids of size 14x20 and 25x30 ๏ Solve IP with ❖ Both objective functions ❖ Degree constraints ❖ Turn Angle constraints ๏ 8 grid directions ๏ Postprocessing for smoother paths: shortcuts by removing vertices as long as the turn angle constraint is not violated
SLIDE 84
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
16
Stockholm TMA: ๏ Arlanda’s runway 19L ๏ Four main entry points: NILUG, XILAN, HMR, and ARS ๏ Square grids of size 14x20 and 25x30 ๏ Solve IP with ❖ Both objective functions ❖ Degree constraints ❖ Turn Angle constraints ๏ 8 grid directions ๏ Postprocessing for smoother paths: shortcuts by removing vertices as long as the turn angle constraint is not violated
SLIDE 85
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
17
SLIDE 86
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
18
222 224 226 228 230 232 234 286 288 290 292 294 296 298 300 302 304
Tree Weight Paths Length
Pareto frontier:
SLIDE 87
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
18
222 224 226 228 230 232 234 286 288 290 292 294 296 298 300 302 304
Tree Weight Paths Length
Pareto frontier: Pareto optimal solutions:
SLIDE 88
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
19
Obstacle avoidance:
SLIDE 89
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
19
Obstacle avoidance:
SLIDE 90
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
19
Obstacle avoidance:
SLIDE 91
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
19
Obstacle avoidance:
SLIDE 92
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
SLIDE 93
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length
SLIDE 94
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length
SLIDE 95
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length
SLIDE 96
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length
SLIDE 97
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length tree weight
SLIDE 98
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length tree weight
SLIDE 99
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length tree weight
SLIDE 100
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length tree weight
SLIDE 101
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length tree weight serve the airlines’ request for short trajectories best
SLIDE 102
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length tree weight serve the airlines’ request for short trajectories best quite dense network
- f routes ➜
SLIDE 103
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length tree weight serve the airlines’ request for short trajectories best quite dense network
- f routes ➜
hard to control the traffic
SLIDE 104
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length tree weight most merge points are located close to TMA boundary serve the airlines’ request for short trajectories best quite dense network
- f routes ➜
hard to control the traffic
SLIDE 105
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length tree weight most merge points are located close to TMA boundary serve the airlines’ request for short trajectories best quite dense network
- f routes ➜
hard to control the traffic
➜helpful to use linear combination of these two functions
SLIDE 106
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length tree weight
➜helpful to use linear combination of these two functions
SLIDE 107
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length tree weight
➜helpful to use linear combination of these two functions
Solutions for large number of entry points could be used to suggest the number and location
- f entry points for a
design from scratch.
SLIDE 108
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length tree weight
➜helpful to use linear combination of these two functions
Solutions for large number of entry points could be used to suggest the number and location
- f entry points for a
design from scratch. 2 entry points
SLIDE 109
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
20
Increased Number of Entry Points:
paths length tree weight
➜helpful to use linear combination of these two functions
Solutions for large number of entry points could be used to suggest the number and location
- f entry points for a
design from scratch. 2 entry points 16 entry points
SLIDE 110
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
21
SID constraints:
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25Each tree: within approximately 2 CPU hours (105 B&B nodes)
SLIDE 111
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
22
SID constraints:
200 210 220 230 240 250 260 270 280 290 1 2 3 4 5 6 7 8 9 10 11 12 13
Paths Length Radius
SLIDE 112
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
22
SID constraints:
200 210 220 230 240 250 260 270 280 290 1 2 3 4 5 6 7 8 9 10 11 12 13
Paths Length Radius
d 1
SLIDE 113
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle
Experimental Study: Arlanda Airport
22
SID constraints:
200 210 220 230 240 250 260 270 280 290 1 2 3 4 5 6 7 8 9 10 11 12 13
Paths Length Radius
d 1
SLIDE 114
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 23
Conclusion/Outlook
SLIDE 115
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 24
SLIDE 116
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 24
Proof of concept for our grid-based IP approach for finding aircraft arrival routes with limited turning angle
SLIDE 117
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 24
Proof of concept for our grid-based IP approach for finding aircraft arrival routes with limited turning angle Easily integrates constraints from the departure routes
SLIDE 118
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 24
Proof of concept for our grid-based IP approach for finding aircraft arrival routes with limited turning angle Easily integrates constraints from the departure routes Static obstacles, e.g., no-fly zones, can be added
SLIDE 119
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 24
Proof of concept for our grid-based IP approach for finding aircraft arrival routes with limited turning angle Easily integrates constraints from the departure routes Static obstacles, e.g., no-fly zones, can be added Might choose to minimize weighted version: minimize the sum of trajectory lengths flown by all arriving aircraft (easily integrated by changing right-hand side of first equation)
SLIDE 120
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 24
Proof of concept for our grid-based IP approach for finding aircraft arrival routes with limited turning angle Easily integrates constraints from the departure routes Static obstacles, e.g., no-fly zones, can be added Might choose to minimize weighted version: minimize the sum of trajectory lengths flown by all arriving aircraft (easily integrated by changing right-hand side of first equation) Outlook:
SLIDE 121
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 24
Proof of concept for our grid-based IP approach for finding aircraft arrival routes with limited turning angle Easily integrates constraints from the departure routes Static obstacles, e.g., no-fly zones, can be added Might choose to minimize weighted version: minimize the sum of trajectory lengths flown by all arriving aircraft (easily integrated by changing right-hand side of first equation) Outlook: Simultaneous design of both SIDs and STARs
SLIDE 122
ATMOS, 25.08.2016 Automatic Design of Aircraft Arrival Routes with Limited Turning Angle 24
Proof of concept for our grid-based IP approach for finding aircraft arrival routes with limited turning angle Easily integrates constraints from the departure routes Static obstacles, e.g., no-fly zones, can be added Might choose to minimize weighted version: minimize the sum of trajectory lengths flown by all arriving aircraft (easily integrated by changing right-hand side of first equation) Outlook: Simultaneous design of both SIDs and STARs 3D routes