IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0623346
(2012-09-20)
|
등록번호 |
US-8833153
(2014-09-16)
|
발명자
/ 주소 |
- Adamson, Eric E.
- Bidwell, Alicia L.
|
출원인 / 주소 |
|
대리인 / 주소 |
Ostrager Chong Flaherty & Broitman P.C.
|
인용정보 |
피인용 횟수 :
3 인용 특허 :
3 |
초록
▼
A method for removing interference-induced distortion effects from an environment used to experimentally measure aerodynamic signatures. A space marching algorithm is used to extract the effects of environment including rail and wall reflections and rail edge effects to create an interference-free p
A method for removing interference-induced distortion effects from an environment used to experimentally measure aerodynamic signatures. A space marching algorithm is used to extract the effects of environment including rail and wall reflections and rail edge effects to create an interference-free pressure signature.
대표청구항
▼
1. A method for reducing interference-induced distortion by an off-body pressure signature while air is flowing through a test section of a wind tunnel, the method comprising: determining a value of a first interference factor associated with a first interference effect that occurs inside the test s
1. A method for reducing interference-induced distortion by an off-body pressure signature while air is flowing through a test section of a wind tunnel, the method comprising: determining a value of a first interference factor associated with a first interference effect that occurs inside the test section of the wind tunnel during model testing;installing a model and a pressure probe in the test section of the wind tunnel, the pressure probe being disposed aft of the model;transducing pressures exerted at respective pressure ports of the pressure probe into respective pressure signals;deriving from said respective pressure signals respective measured parameter values for each pressure port of a first group of said pressure ports; andcalculating corrected parameter values for each pressure port of said first group of said pressure ports utilizing weighted parameter values calculated by multiplying said first interference factor by said respective measured parameter values for each pressure port in said first group of said pressure ports. 2. The method as recited in claim 1, wherein said first interference factor is a function of numerically simulated or empirically derived pressure signals reflected off a top of the pressure probe. 3. The method as recited in claim 1, wherein said parameter is a difference between a measured static pressure and a free-stream static pressure divided by the free-stream static pressure. 4. The method as recited in claim 1, further comprising: determining a value of a second interference factor associated with a second interference effect that occurs inside the test section of the wind tunnel during model testing; andderiving from said respective pressure signals said respective measured parameter values for each pressure port of a second group of said pressure ports located aft of said first group of said pressure ports. 5. The method as recited in claim 4, further comprising calculating corrected parameter values for each pressure port of said second group of said pressure ports of the pressure probe using a first set and a second set of weighted parameter values, the first set of weighted parameter values being calculated by multiplying said first interference factor times said measured parameter values for each pressure port of said second group, and the second set of weighted parameter values being calculated by multiplying said second interference factor times the corrected parameter value for a respective pressure port located j ports forward of each pressure port of said second group for which a corrected parameter value is being calculated, where j is a positive integer. 6. The method as recited in claim 4, wherein said second interference factor is a function of numerically simulated or empirically derived pressure signals which have interacted with an edge of the pressure probe. 7. The method as recited in claim 4, further comprising: determining a value of a third interference factor associated with a third interference effect that occurs inside the test section of the wind tunnel during model testing; andderiving from said respective pressure signals said measured parameter values for each pressure port of a third group of said pressure ports located aft of said second group of said pressure ports. 8. The method as recited in claim 7, further comprising calculating corrected parameter values for each pressure port of said third group of said pressure ports of the pressure probe by subtracting a respective weighted parameter value of a third set of weighted parameter values from, adds a respective weighted parameter value of a fourth set of weighted parameter values to, and a respective weighted parameter value of a fifth set of weighted parameter values from a respective one of said measured parameter values for each pressure port of said third group. 9. The method as recited in claim 8, wherein said third set of weighted parameter values being calculated by multiplying said first interference factor times said measured parameter values for each pressure port of said third group, said fourth set of weighted parameter values being calculated by multiplying said second interference factor times the corrected parameter value for a respective pressure port located j ports forward of each pressure port of said third group for which a corrected parameter value is being calculated, and said fifth set of weighted parameter values being calculated by multiplying said third interference factor times the corrected parameter value for a respective pressure port located k ports forward of each pressure port of said third group for which a corrected parameter value is being calculated, where k is a positive integer greater than j. 10. The method as recited in claim 7, wherein said third interference factor is a function of numerically simulated or empirically derived pressure signals which have interacted with a wall of the wind tunnel. 11. The method as recited in claim 7, further comprising aggregating said corrected parameter values for said first group, said second group and said third group of said pressure ports to form a corrected pressure signature and making said pressures available for additional calculations, display on a screen, or data archival. 12. A method for removing interference induced distortion effects to prevent limiting accuracy of test measurement hardware inside of a test section of a wind tunnel during model testing, the method comprising: determining respective values of first and second interference factors respectively associated with first and second interference effects;acquiring parameter values for each pressure port of a multiplicity of pressure ports;calculating corrected parameter values for each pressure port of a first group of the multiplicity of pressure ports using weighted parameter values from one or more of said acquired parameter values for each pressure port of said first group of the multiplicity of pressure ports, said weighted parameter values being calculated by multiplying said first interference factor times said acquired parameter values for each pressure port of said first group of the multiplicity of pressure ports; andcalculating corrected parameter values for each pressure port of a second group of the multiplicity of pressure ports by subtracting a respective weighted parameter value of a first set of weighted parameter values and a respective weighted parameter value of a second set of weighted parameter values from a respective one of said acquired parameter values for each pressure port of said second group of the multiplicity of pressure ports. 13. The method as recited in claim 12, wherein said first set of weighted parameter values are calculated by multiplying said first interference factor times said acquired parameter values for each pressure port of said second group, and said second set of weighted parameter values are calculated by multiplying said second interference factor times the corrected parameter value for a respective pressure port located k ports forward of each pressure port of said second group for which a corrected parameter value is being calculated, where k is a positive integer. 14. The method as recited in claim 12, wherein said first interference factor is a function of numerically simulated or empirically derived pressure signals reflected from a pressure probe installed in a wind tunnel and said second interference factor is a function of numerically simulated or empirically derived pressure signals reflected from a wind tunnel wall. 15. The method as recited in claim 12, wherein said parameter is a difference between a static pressure and a free-stream static pressure divided by the free-stream static pressure; and wherein said parameter values are acquired by wind tunnel testing or numerical simulation of a wind tunnel testing of a model. 16. A system for reducing an off-body pressure signature of environmental effects within a wind tunnel about a test article, the system comprising a computer system programmed to perform the following operations: acquiring pressure data comprising measured parameter values corresponding to respective pressure ports of a pressure probe installed in a test section of a wind tunnel; andcalculating respective corrected parameter values for each pressure port of a first group of pressure ports of the pressure probe that subtracts a respective weighted parameter value from a respective one of said acquired parameter values for each pressure port of said first group, said respective weighted parameter values being calculated by multiplying a first interference factor times said acquired parameter values for each pressure port of said first group. 17. The system as recited in claim 16, wherein said computer system is further programmed to perform the following operation: calculating corrected parameter values for each pressure port of a second group of pressure ports of the pressure probe that subtracts a respective weighted parameter value of a first set of weighted parameter values from and adds a respective weighted parameter value of a second set of weighted parameter values to a respective one of said measured parameter values for each pressure port of said second group. 18. The system as recited in claim 17, wherein said first set of weighted parameter values are calculated by multiplying said first interference factor times said acquired parameter values for each pressure port of said second group, and said second set of weighted parameter values are calculated by multiplying a second interference factor times the corrected parameter value for a respective pressure port located j ports forward of each pressure port of said second group for which a corrected parameter value is being calculated, where j is a positive integer. 19. The system as recited in claim 18, wherein said computer system is further programmed to perform the following operation: calculating corrected parameter values for each pressure port of a third group of said pressure ports of the pressure probe using a third mathematical formula that subtracts a respective weighted parameter value of a third set of weighted parameter values from, adds a respective weighted parameter value of a fourth set of weighted parameter values to, and subtracts a respective weighted parameter value of a fifth set of weighted parameter values from a respective one of said acquired parameter values for each pressure port of said third group, said third set of weighted parameter values being calculated by multiplying said first interference factor times said acquired parameter values for each pressure port of said third group, said fourth set of weighted parameter values being calculated by multiplying said second interference factor times the corrected parameter value for a respective pressure port located j ports forward of each pressure port of said third group for which a corrected parameter value is being calculated, and said fifth set of weighted parameter values being calculated by multiplying a third interference factor times the corrected parameter value for a respective pressure port located k ports forward of each pressure port of said third group for which a corrected parameter value is being calculated, where k is a positive integer greater than j. 20. The system as recited in claim 16, wherein said parameter is a difference between a measured static pressure and a free-stream static pressure divided by the free-stream static pressure. 21. A method for removing an off-body pressure signature of interference-induced distortion of a test article while air is flowing through a test section of a wind tunnel in a flow direction, comprising: installing a model and a pressure probe in a test section of a wind tunnel, the pressure probe being disposed aft of the model;transducing pressures exerted at respective pressure ports of the pressure probe into respective pressure signals;deriving from said respective pressure signals measured parameter values for each pressure port; andcalculating corrected parameter values for each pressure port of a first group of pressure ports of the pressure probe that removes effects of reflections from a top of the pressure probe. 22. The method as recited in claim 21, further comprising: calculating corrected parameter values for each pressure port of a second group of pressure ports of the pressure probe that removes effects of reflections from a top of the pressure probe and effects of interactions with an edge of the pressure probe, the second group being located aft of the first group; andcalculating corrected parameter values for each pressure port of a third group of pressure ports of the pressure probe that removes the effects of reflections from a top of the pressure probe, the effects of interactions with an edge or edges of the pressure probe, and the effects of reflections from a wall or walls of the wind tunnel, the third group being located aft of the second group. 23. The method as recited in claim 21, wherein said parameter is a difference between a measured static pressure and a free-stream static pressure divided by the free-stream static pressure. 24. The method as recited in claim 21, further comprising aggregating said corrected parameter values for said first group, said second group and said third group of pressure ports to form a corrected pressure signature and making said pressures available for additional calculations, display on a screen, or data archival.
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