The AirScene�� Pavement Management System of the present invention automatically tracks data required to determine various factors in an assessment of current and future pavement maintenance needs and utilizes this data to quantify the pavement damage caused by each individual aircraft movement and
The AirScene�� Pavement Management System of the present invention automatically tracks data required to determine various factors in an assessment of current and future pavement maintenance needs and utilizes this data to quantify the pavement damage caused by each individual aircraft movement and thus compute pavement condition based on an initial survey and the calculations of accrued damage over time. This information can be displayed through AirScene�� in the form of tables, graphs, or graphically represented on an airport diagram showing present conditions, rates of accruing damage, and future wear rates and areas. The system draws on the data from the AirScene�� Data Warehouse (ADW), a single repository for all the information acquired from a number of different sources. These data include: Aircraft or vehicle type (wheel layout, weight, vehicle specific parameters, and the like), Aircraft or vehicle location (ground track, position, gate used, and the like), Aircraft or vehicle dynamics (velocity, acceleration, take off, touchdown, and the like), Aircraft or vehicle actual weight (cargo load, fuel load, and the like), as well as Future operational data (flight schedules, increasing flight loads and demand, and the like).
대표청구항▼
We claim: 1. A system for determining pavement wear, comprising: electronic tracking system for automatically tracking actual continuous paths of real individual vehicles on the pavement to create vehicle path data; means for automatically storing vehicle path data; means for automatically calculat
We claim: 1. A system for determining pavement wear, comprising: electronic tracking system for automatically tracking actual continuous paths of real individual vehicles on the pavement to create vehicle path data; means for automatically storing vehicle path data; means for automatically calculating vehicle pavement wear based upon cumulative vehicle path data, by calculating cumulative wear to pavement areas caused by actual individual vehicle paths on the pavement; and a graphical display for displaying calculated vehicle pavement wear areas on a visual display as a graphical display of pavement wear overlaid on a map of the pavement. 2. The system of claim 1, further comprising: means for receiving initial survey data to establish a baseline of pavement condition; wherein said means for calculating pavement wear further calculates pavement conditions based upon initial survey data and calculated vehicle pavement wear data. 3. The system of claim 1, wherein the means for storing vehicle path data further includes a repository for individual vehicle information acquired from a plurality of data sources, including at least one of aircraft or vehicle type, including wheel layout, weight, and vehicle-specific parameters; aircraft or vehicle location including ground track, position, and gate used; aircraft or vehicle dynamics including velocity, acceleration, take off, and touchdown, aircraft or vehicle actual weight, including cargo load , fuel load, and passenger load; and future operational data, including flight schedules, increasing flight loads, and demand, and wherein said means for calculating pavement wear calculates vehicle pavement wear data based upon individual vehicle path and individual vehicle information. 4. The system of claim 1, wherein the means for calculating pavement wear based upon path of movement data determines pavement wear based upon where the vehicle was, how much it weighed, and how long it was on a particular section of pavement to determine wear on the pavement. 5. The system of claim 1, further comprising: means for using historic vehicle tracking data to predict future maintenance needs of the pavement by determining where pavement wear due to vehicle traffic will occur. 6. The system of claim 1, wherein said means for calculating pavement wear based upon path of movement data further calculates future airport operations using scheduled airline operations data, to determine future maintenance requirements of the pavement. 7. A system for determining pavement wear comprising: means for tracking continuous paths of individual vehicles on the pavement to create vehicle path data; means for storing vehicle path data; means for calculating vehicle pavement wear based upon cumulative vehicle path data, by calculating cumulative wear to pavement areas caused by individual vehicle paths on the pavement; means for displaying calculated vehicle pavement wear areas on a visual display; and means for detecting environmental influences on pavement wear, including at least one of heat/cool cycles, freeze/thaw cycles, rainfall, sunlight, and temperature, wherein said means for calculating pavement wear further calculates pavement wear based upon environmental influences, and combines pavement wear based upon environmental influences with pavement wear caused by individual vehicle paths, and wherein said means for displaying calculated pavement wear areas on a visual display displays combined environmental and calculated vehicle pavement wear data. 8. The system of claim 7, further comprising: means for receiving initial survey data to establish a baseline of pavement condition; wherein said means for calculating pavement wear further calculates pavement conditions based upon initial survey data and calculated vehicle pavement wear data. 9. The system of claim 7, wherein the means for storing vehicle path data further includes a repository for individual vehicle information acquired from a plurality of data sources, including at least one of aircraft or vehicle type, including wheel layout, weight, and vehicle-specific parameters; aircraft or vehicle location including ground track, position, and gate used; aircraft or vehicle dynamics including velocity, acceleration, take off, and touchdown, aircraft or vehicle actual weight, including cargo load, fuel load, and passenger load; and future operational data, including flight schedules, increasing flight loads, and demand, and wherein said means for calculating pavement wear calculates vehicle pavement wear data based upon individual vehicle path and individual vehicle information. 10. The system of claim 7, wherein the means for calculating pavement wear based upon path of movement data determines pavement wear based upon where the vehicle was, how much it weighed, and how long it was on a particular section of pavement to determine wear on the pavement. 11. The system of claim 7, further comprising: means for using historic vehicle tracking data to predict future maintenance needs of the pavement by determining where pavement wear due to vehicle traffic will occur. 12. The system of claim 7, wherein said means for calculating pavement wear based upon path of movement data further calculates future airport operations using scheduled airline operations data, to determine future maintenance requirements of the pavement. 13. A system for determining pavement wear, comprising: means for tracking vehicle movement, including path of movement data for vehicles on the pavement; means for storing path of movement data; means for calculating pavement wear based upon path of movement data; and means for displaying calculated pavement wear on a visual display, wherein the means for tracking vehicle movement, including path of movement data for vehicles on the pavement comprises one or more of Multilateration (Mlat), Automatic Dependent Surveillance, Broadcast (ADS-B), Airport Surface Detection Equipment, Model X (ADS-X), Airport Surface Detection Equipment, Model B (ADS-B), Airport Movement-Area Safety System (AMASS), and Airport Surface Detection Equipment (ASDE), to determine at least one of type of aircraft or vehicle, type of operation (taxi, park, departure, or arrival), where the aircraft or vehicle operated, and also which runways, taxiways, and gates were used. 14. The system of claim 13, further comprising: means for receiving initial survey data to establish a baseline of pavement condition; wherein said means for calculating pavement wear further calculates pavement conditions based upon initial survey data and calculated vehicle pavement wear data. 15. The system of claim 13, wherein the means for storing vehicle path data further includes a repository for individual vehicle information acquired from a plurality of data sources, including at least one of aircraft or vehicle type, including wheel layout, weight, and vehicle-specific parameters; aircraft or vehicle location including ground track, position, and gate used; aircraft or vehicle dynamics including velocity, acceleration, take off, and touchdown, aircraft or vehicle actual weight, including cargo load , fuel load, and passenger load; and future operational data, including flight schedules, increasing flight loads, and demand, and wherein said means for calculating pavement wear calculates vehicle pavement wear data based upon individual vehicle path and individual vehicle information. 16. The system of claim 13, wherein the means for calculating pavement wear based upon path of movement data determines pavement wear based upon where the vehicle was, how much it weighed, and how long it was on a particular section of pavement to determine wear on the pavement. 17. The system of claim 13, further comprising: means for using historic vehicle tracking data to predict future maintenance needs of the pavement by determining where pavement wear due to vehicle traffic will occur. 18. The system of claim 13, wherein said means for calculating pavement wear based upon path of movement data further calculates future airport operations using scheduled airline operations data, to determine future maintenance requirements of the pavement. 19. A system for determining pavement wear, comprising: means for tracking vehicle movement, including path of movement data for vehicles on the pavement; means for storing path of movement data; means for calculating pavement wear based upon path of movement data; and means for displaying calculated pavement wear on a visual display, wherein the means for tracking vehicle movement, including path of movement data for vehicles on the pavement uses data from the Aircraft Communication Addressing and Reporting System (ACARS), including at least one of weight of the aircraft, fuel, and cargo, time at the gate, time and position of wheels off the ground, and wheels on the ground. 20. The system of claim 19, further comprising: means for receiving initial survey data to establish a baseline of pavement condition; wherein said means for calculating pavement wear further calculates pavement conditions based upon initial survey data and calculated vehicle pavement wear data. 21. The system of claim 19, wherein the means for storing vehicle path data further includes a repository for individual vehicle information acquired from a plurality of data sources, including at least one of aircraft or vehicle type, including wheel layout, weight, and vehicle-specific parameters; aircraft or vehicle location including ground track, position, and gate used; aircraft or vehicle dynamics including velocity, acceleration, take off, and touchdown, aircraft or vehicle actual weight, including cargo load, fuel load, and passenger load; and future operational data, including flight schedules, increasing flight loads, and demand, and wherein said means for calculating pavement wear calculates vehicle pavement wear data based upon individual vehicle path and individual vehicle information. 22. The system of claim 19, wherein the means for calculating pavement wear based upon path of movement data determines pavement wear based upon where the vehicle was, how much it weighed, and how long it was on a particular section of pavement to determine wear on the pavement. 23. The system of claim 19, further comprising: means for using historic vehicle tracking data to predict future maintenance needs of the pavement by determining where pavement wear due to vehicle traffic will occur. 24. The system of claim 19, wherein said means for calculating pavement wear based upon path of movement data further calculates future airport operations using scheduled airline operations data, to determine future maintenance requirements of the pavement. 25. A system for determining pavement wear, comprising: means for tracking vehicle movement, including path of movement data for vehicles on the pavement; means for storing path of movement data; means for calculating pavement wear based upon path of movement data; means for displaying calculated pavement wear on a visual display; and means for receiving weather information and operational data from one or more of the Digital Automatic Terminal Information Service (D-ATIS), Automatic Surface Observation System (ASOS), METerologicval Aviation Reguliere (METAR), and Terminal Area Forecast (TAF), for calculating pavement wear from life-cycle and weather factors. 26. The system of claim 25, further comprising: means for receiving initial survey data to establish a baseline of pavement condition; wherein said means for calculating pavement wear further calculates pavement conditions based upon initial survey data and calculated vehicle pavement wear data. 27. The system of claim 25, wherein the means for storing path of movement data further includes a repository for individual vehicle information acquired from a plurality of data sources, including at least one of aircraft or vehicle type, including wheel layout, weight, and vehicle-specific parameters; aircraft or vehicle location including ground track, position, and gate used; aircraft or vehicle dynamics including velocity, acceleration, take off, and touchdown, aircraft or vehicle actual weight, including cargo load , fuel load, and passenger load; and future operational data, including flight schedules, increasing flight loads, and demand, and wherein said means for calculating pavement wear calculates vehicle pavement wear data based upon individual vehicle path and individual vehicle information. 28. The system of claim 25, wherein the means for calculating pavement wear based upon path of movement data determines pavement wear based upon where the vehicle was, how much it weighed, and how long it was on a particular section of pavement to determine wear on the pavement. 29. The system of claim 25, further comprising: means for using historic vehicle tracking data to predict future maintenance needs of the pavement by determining where pavement wear due to vehicle traffic will occur. 30. The system of claim 25, wherein said means for calculating pavement wear based upon path of movement data further calculates future airport operations using scheduled airline operations data, to determine future maintenance requirements of the pavement. 31. A system for determining pavement wear comprising: means for tracking continuous paths of individual vehicles on the pavement to create vehicle path data; means for storing vehicle path data; means for calculating vehicle pavement wear based upon cumulative vehicle path data, by calculating cumulative wear to pavement areas caused by individual vehicle paths on the pavement; means for displaying calculated vehicle pavement wear areas on a visual display; and means for determining and warning of pavement overload from individual vehicles, by receiving vehicle track data in real time, comparing vehicle type and weight with pavement in the vehicle track, and warning of pavement overload if an individual vehicle weight exceeds pavement capacity in the vehicle track. 32. The system of claim 31, further comprising: means for receiving initial survey data to establish a baseline of pavement condition; wherein said means for calculating pavement wear further calculates pavement conditions based upon initial survey data and calculated vehicle pavement wear data. 33. The system of claim 31, wherein the means for storing vehicle path data further includes a repository for individual vehicle information acquired from a plurality of data sources, including at least one of aircraft or vehicle type, including wheel layout, weight, and vehicle-specific parameters; aircraft or vehicle location including ground track, position, and gate used; aircraft or vehicle dynamics including velocity, acceleration, take off, and touchdown, aircraft or vehicle actual weight, including cargo load , fuel load, and passenger load; and future operational data, including flight schedules, increasing flight loads, and demand, and wherein said means for calculating pavement wear calculates vehicle pavement wear data based upon individual vehicle path and individual vehicle information. 34. The system of claim 31, wherein the means for calculating pavement wear based upon path of movement data determines pavement wear based upon where the vehicle was, how much it weighed, and how long it was on a particular section of pavement to determine wear on the pavement. 35. The system of claim 31, further comprising: means for using historic vehicle tracking data to predict future maintenance needs of the pavement by determining where pavement wear due to vehicle traffic will occur. 36. The system of claim 31, wherein said means for calculating pavement wear based upon path of movement data further calculates future airport operations using scheduled airline operations data, to determine future maintenance requirements of the pavement. 37. A system for determining pavement wear comprising: means for tracking continuous paths of individual vehicles on the pavement to create vehicle path data; means for storing vehicle path data; means for calculating vehicle pavement wear based upon cumulative vehicle path data, by calculating cumulative wear to pavement areas caused by individual vehicle paths on the pavement; means for displaying calculated vehicle pavement wear areas on a visual display; and a landing fee billing system, for calculating landing fees based upon vehicle weight data and vehicle track data such that vehicle landing fees are calculated based on damage a vehicle is likely to be causing to the pavement. 38. The system of claim 37, further comprising: means for receiving initial survey data to establish a baseline of pavement condition; wherein said means for calculating pavement wear further calculates pavement conditions based upon initial survey data and calculated vehicle pavement wear data. 39. The system of claim 37, wherein the means for storing vehicle path data further includes a repository for individual vehicle information acquired from a plurality of data sources, including at least one of aircraft or vehicle type, including wheel layout, weight, and vehicle-specific parameters; aircraft or vehicle location including ground track, position, and gate used; aircraft or vehicle dynamics including velocity, acceleration, take off, and touchdown, aircraft or vehicle actual weight, including cargo load , fuel load, and passenger load; and future operational data, including flight schedules, increasing flight loads, and demand, and wherein said means for calculating pavement wear calculates vehicle pavement wear data based upon individual vehicle path and individual vehicle information. 40. The system of claim 37, wherein the means for calculating pavement wear based upon path of movement data determines pavement wear based upon where the vehicle was, how much it weighed, and how long it was on a particular section of pavement to determine wear on the pavement. 41. The system of claim 37, further comprising: means for using historic vehicle tracking data to predict future maintenance needs of the pavement by determining where pavement wear due to vehicle traffic will occur. 42. The system of claim 37, wherein said means for calculating pavement wear based upon path of movement data further calculates future airport operations using scheduled airline operations data, to determine future maintenance requirements of the pavement. 43. A system for determining pavement wear comprising: means for tracking continuous paths of individual vehicles on the pavement to create vehicle path data; means for storing vehicle path data; means for calculating vehicle pavement wear based upon cumulative vehicle path data, by calculating cumulative wear to pavement areas caused by individual vehicle paths on the pavement; means for displaying calculated vehicle pavement wear areas on a visual display; means for tracking ground vehicles used to perform pavement inspection; and means for receiving pavement inspection data from ground vehicles and correlating pavement inspection data with ground vehicle tracking data to determine pavement condition. 44. The system of claim 43, further comprising: means for receiving initial survey data to establish a baseline of pavement condition; wherein said means for calculating pavement wear further calculates pavement conditions based upon initial survey data and calculated vehicle pavement wear data. 45. The system of claim 43, wherein the means for storing vehicle path data further includes a repository for individual vehicle information acquired from a plurality of data sources, including at least one of aircraft or vehicle type, including wheel layout, weight, and vehicle-specific parameters; aircraft or vehicle location including ground track, position, and gate used; aircraft or vehicle dynamics including velocity, acceleration, take off, and touchdown, aircraft or vehicle actual weight, including cargo load , fuel load, and passenger load; and future operational data, including flight schedules, increasing flight loads, and demand, and wherein said means for calculating pavement wear calculates vehicle pavement wear data based upon individual vehicle path and individual vehicle information. 46. The system of claim 43, wherein the means for calculating pavement wear based upon path of movement data determines pavement wear based upon where the vehicle was, how much it weighed, and how long it was on a particular section of pavement to determine wear on the pavement. 47. The system of claim 43, further comprising: means for using historic vehicle tracking data to predict future maintenance needs of the pavement by determining where pavement wear due to vehicle traffic will occur. 48. The system of claim 43, wherein said means for calculating pavement wear based upon path of movement data further calculates future airport operations using scheduled airline operations data, to determine future maintenance requirements of the pavement. 49. A system for determining pavement wear comprising: means for tracking continuous paths of individual vehicles on the pavement to create vehicle path data; means for storing vehicle path data; means for calculating vehicle pavement wear based upon cumulative vehicle path data, by calculating cumulative wear to pavement areas caused by individual vehicle paths on the pavement; means for displaying calculated vehicle pavement wear areas on a visual display; and means for monitoring maintenance processes of runway rubber removal including means for tracking and recording time, date, and position of runway rubber removal vehicles to verify affected pavement areas are cleaned. 50. The system of claim 49, further comprising: means for receiving initial survey data to establish a baseline of pavement condition; wherein said means for calculating pavement wear further calculates pavement conditions based upon initial survey data and calculated vehicle pavement wear data. 51. The system of claim 49, wherein the means for storing vehicle path data further includes a repository for individual vehicle information acquired from a plurality of data sources, including at least one of aircraft or vehicle type, including wheel layout, weight, and vehicle-specific parameters; aircraft or vehicle location including ground track, position, and gate used; aircraft or vehicle dynamics including velocity, acceleration, take off, and touchdown, aircraft or vehicle actual weight, including cargo load, fuel load, and passenger load; and future operational data, including flight schedules, increasing flight loads, and demand, and wherein said means for calculating pavement wear calculates vehicle pavement wear data based upon individual vehicle path and individual vehicle information. 52. The system of claim 49, wherein the means for calculating pavement wear based upon path of movement data determines pavement wear based upon where the vehicle was, how much it weighed, and how long it was on a particular section of pavement to determine wear on the pavement. 53. The system of claim 49, further comprising: means for using historic vehicle tracking data to predict future maintenance needs of the pavement by determining where pavement wear due to vehicle traffic will occur. 54. The system of claim 49, wherein said means for calculating pavement wear based upon path of movement data further calculates future airport operations using scheduled airline operations data, to determine future maintenance requirements of the pavement.
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