Defined interval (DI) risk based air traffic control separation
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G06F-019/00
G06G-007/70
G06G-007/76
G08G-005/00
출원번호
US-0897260
(2013-05-17)
등록번호
US-9082300
(2015-07-14)
발명자
/ 주소
Scott, William F
출원인 / 주소
Scott, William F
인용정보
피인용 횟수 :
1인용 특허 :
6
초록▼
A method and process of an optimized, derivational risk-based air traffic control system state capitalizing on data exchange and interactive surveillance modalities with satellite functionality. Data interrogation will exchange operationally relevant real-time information amongst users and regulator
A method and process of an optimized, derivational risk-based air traffic control system state capitalizing on data exchange and interactive surveillance modalities with satellite functionality. Data interrogation will exchange operationally relevant real-time information amongst users and regulators, and a computer complex wherein data exchanges accumulate for application of risk model criterion and sovereign requirements. The risk model compares optimization of the system state with current state and communicated intent, making value judgments concerning safety and efficiency of the system as a whole and at intervals over time. Intuitive localization “swabs” reflecting collision potential, upset potential and other risks associated with any operation of air traffic control objects, manifest this. Localization solution set information is transmitted where necessary for implementation and may be proximity assurance tasks or operational requirements that must be performed within defined boundaries creating non-risk adverse associations.
대표청구항▼
1. A method of achieving a risk-based optimized air traffic control system state, comprising: a plurality of sensors in communication with at least one central monitoring station including a host computer with a database acquiring and assimilating data relative to the air traffic control system-stat
1. A method of achieving a risk-based optimized air traffic control system state, comprising: a plurality of sensors in communication with at least one central monitoring station including a host computer with a database acquiring and assimilating data relative to the air traffic control system-state, said data including interactive, real-time information from air traffic control objects, data from environmental sensors and measurement devices, and data regarding regulation standards;at least one processer executing a program to associate a SWAB confine around each air traffic control object, said SWAB confine based on known or determined risk associated with the operation of an air traffic control object relative any other air traffic control object;optimizing the air traffic control system state by associating, in time and over time, SWAB confine associations and how each SWAB confine association may or may not present risk to any other air traffic control object;creating directed solutions for operating the air traffic control object, wherein the solutions may include risk-based achievements for the air traffic control object to make or separation distances or times to maintain;wherein said solutions are based on acceptable determinations after applied risk model criterion analysis;said solutions predicated upon a matrix relationship formula and application criteria calculation; andassigning solutions by interrogation and response to a flight management computer or other displays congruent to the air traffic control objects within the system for enactment, wherein the solution meets safety and efficiency thresholds that may include sovereign requirements. 2. The method of claim 1 wherein risk confines are produced, assessed and reported where said object's risk is defined, and then displayed by a valuation referred to as a SWAB in reference to its shape, and appending the SWAB to the air traffic control object for comparison with at least other SWABs that consist of ordered determinations, where said determinations are calculated substance of process findings. 3. The method of claim 1 wherein risk-based, air traffic control object requirements are created factoring safety of operations dynamics to maximize non-risk adverse proximal relationships, said requirements can include proximity assurance tasks or operational requirements that assure and maintain non-risk adverse associations transmitted and displayed to the air traffic control objects for implementation. 4. An air traffic operations control system, said system comprising: at least one central monitoring station including a host computer modified to run specific programs in support of defined interval solutions;a plurality of air traffic control objects, wherein each air traffic control object includes a transmitter and receiver for bi-directional communications;a plurality of data gathering sensors in communication with the host computer and the plurality of air traffic control objects, said sensors including environmental sensors and measurement devices;a database in communication with the host computer, air traffic control objects, and data gathering sensors, said database acquiring and assimilating data relative to the air traffic control system-state, said data including interactive, real-time information from said air traffic control objects, data from the plurality of sensors, and data regarding regulation standards; andat least one processor executing a program stored on a non-transitory computer readable medium, said processor;associating, in time and over time, defined interval solution associations and how each defined interval solution may or may not present risk to any other air traffic control object;creating directed solutions for operating the air traffic control object, wherein the solutions may include risk-based achievements for the air traffic control object to make or separation distances or times to maintain;wherein said solutions are based on acceptable determinations after applied risk model criterion analysis;said solutions predicated upon a matrix relationship formula and application criteria calculation; andassigning solutions by interrogation and response to a flight management computer or other displays congruent to the air traffic control objects within the system for enactment wherein the solution meets safety and efficiency thresholds that may include sovereign requirements. 5. The system of claim 4 wherein defined interval solutions are produced, assessed and reported where said object's risk is defined, and then displayed by a valuation referred to as a SWAB in reference to its shape, appending the SWAB to the air traffic control object for comparison with at least other SWABs that consist of ordered determinations, where said determinations are calculated substance of process findings. 6. The system of claim 4 wherein risk-based, air traffic control object requirements are created factoring safety of operations dynamics to maximize non-risk adverse proximal relationships, said requirements can include proximity assurance tasks or operational requirements that assure and maintain non-risk adverse associations transmitted and displayed to the air traffic control objects for implementation.
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이 특허에 인용된 특허 (6)
Roberts, Alison Laura Udal; Pember, Stephen James, Air traffic control.
Shanbhag, Vasudev Prakash; Krishna, Sridhar; Maji, Sanjib Kumar; Ravikumar, Shashi Kiran, Systems and methods for displaying degraded intruder traffic data on an aircraft display.
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