A vehicle power system includes a multiple of electrical generators which provide power for vehicle electrical systems or loads through an electrical load management center which communicates with a general purpose processor set such that the power supplied to each electrical load may be individuall
A vehicle power system includes a multiple of electrical generators which provide power for vehicle electrical systems or loads through an electrical load management center which communicates with a general purpose processor set such that the power supplied to each electrical load may be individually controlled. A display communicates with the GPPS to present an electrical system status screen to the vehicle crew such that the crew is constantly made aware of the prevailing electrical power conditions in a rapid and efficient manner. During a drastically reduced generator situation, the GPPS automatically disconnects loads via a predefined load shed priority list. Once electrical loads are disconnected via the predefined load shed priority list the crew can reactivate and deactivate selected systems for the current mission circumstances through a load recovery screen accessible through the display.
대표청구항▼
A vehicle power system includes a multiple of electrical generators which provide power for vehicle electrical systems or loads through an electrical load management center which communicates with a general purpose processor set such that the power supplied to each electrical load may be individuall
A vehicle power system includes a multiple of electrical generators which provide power for vehicle electrical systems or loads through an electrical load management center which communicates with a general purpose processor set such that the power supplied to each electrical load may be individually controlled. A display communicates with the GPPS to present an electrical system status screen to the vehicle crew such that the crew is constantly made aware of the prevailing electrical power conditions in a rapid and efficient manner. During a drastically reduced generator situation, the GPPS automatically disconnects loads via a predefined load shed priority list. Once electrical loads are disconnected via the predefined load shed priority list the crew can reactivate and deactivate selected systems for the current mission circumstances through a load recovery screen accessible through the display. sing: collecting analyte measurement values from one or more subject using an analyte monitoring device for each subject, said analyte monitoring device (i) comprising a transdermal sampling device, (ii) providing frequent analyte measurement values, wherein said analyte measurement values comprise acquired data points that are specifically related to analyte amount or concentration in the subject, and (iii) providing one or more error messages related to skipped analyte measurement values; and formulating said one or more analyte data databases by associating each of said data points and each of said one or more error messages related to skipped analyte measurement value with one or more data attributes. 2. The method of claim 1, wherein said data points further comprise derived data determined from one or more acquired data points and the derived data are associated with the data points from which they are derived. 3. The method of claim 2, wherein each of said derived data are associated with one or more data attributes. 4. The method of claim 2, wherein said analyte is glucose and said derived data comprises glucose amount or concentration. 5. The method of claim 4, wherein said analyte monitoring device is a glucose monitoring device, said glucose monitoring device comprising a transdermal sampling device, a sensing device, a display, and means to provide an audible alert when glucose levels in a subject being monitored are outside of a predetermined range. 6. The method of claim 5, wherein said acquired data points comprise electrochemical signals. 7. The method of claim 6, wherein said data attributes are selected from the group consisting of: chronological information, user perspiration levels, device operating temperature, missed measurements; skipped measurements, user body temperature, user skin conductance, environmental variables, alarm events, activity codes, total excursion, mean value, statistical function, subject code, demographic information, physical characteristics, and disease-associated characteristics. 8. The method of claim 1, wherein said analyte measurement values are collected from a single individual. 9. The method of claim 1, wherein said analyte measurement values are collected from more than one individual. 10. The method of claim 9, wherein said formulating further comprises compiling multiple databases from each database where the data points are collected from a single individual and the data points for each single individual are associated with one or more relevant data attributes. 11. The method of claim 1, wherein said analyte is a biological analyte. 12. The method of claim 11, wherein said biological analyte is glucose. 13. The method of claim 1, wherein said analyte monitoring device is capable of measuring more than one analyte. 14. The method of claim 13, wherein one of said analytes is glucose. 15. An analyte data database formulated from data points collected using an analyte monitoring device, said analyte monitoring device (i) comprising a transdermal sampling device, and (ii) providing frequent analyte measurement values, wherein said analyte measurement values comprise data points that are specifically related to analyte amount or concentration, and (iii) providing one or more error messages related to skipped analyte measurement values, wherein the data points and each of said one or more error messages related to skipped analyte measurement values are associated with one or more relevant data attributes. 16. The database of claim 15, wherein said data points further comprise derived data determined from one or more acquired data points and the derived data are associated with the data points from which they are derived. 17. The database of claim 16, wherein each of said derived data are associated with one or more data attributes. 18. The database of claim 16, wherein said analyte is glucose and said derived data comprises glucose amount or concentration. 19. The databas e of claim 18, wherein said analyte monitoring device is a glucose monitoring device, said glucose monitoring device comprising a transdermal sampling device, a sensing device, a display, and means to provide an audible alert when glucose levels in a subject being monitored are outside of a predetermined range. 20. The database of claim 19, wherein said acquired data points comprise electrochemical signals. 21. The database of claim 20, wherein said data attributes are selected from the group consisting of: chronological information, user perspiration levels, device operating temperature, missed measurements; skipped measurements, user body temperature, user skin conductance, environmental variables, alarm events, activity codes, total excursion, mean value, statistical function, subject code, demographic information, physical characteristics, and disease-associated characteristics. 22. The database of claim 15, wherein said analyte measurement values are collected from a single individual. 23. The database of claim 15, wherein said analyte measurement values are collected from more than one individual. 24. The database of claim 23, wherein said formulating further comprises compiling multiple databases from each database where the data points are collected from a single individual and the data points for each single individual are associated with one or more relevant data attributes. 25. The database of claim 15, wherein said analyte is a biological analyte. 26. The database of claim 25, wherein said biological analyte is glucose. 27. The database of claim 15, wherein said analyte monitoring device is capable of measuring more than one analyte. 28. The database of claim 27, wherein one of said analytes is glucose. 29. A method of manipulating an analyte data database, comprising providing the analyte data database of claim 15 and manipulating said data points via said attributes associated with said data points to determine relationships between said data points and said attributes. 30. A method of manipulating an analyte data database, comprising providing the analyte data database of claim 15; and manipulating said attributes via said data points associated with said attributes to determine relationships between said attributes and said data points.
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이 특허에 인용된 특허 (10)
Ejzak Richard P. (Rockford IL) Thom James B. (Rock City IL) Peterson William J. (Rockford IL) Glennon Timothy F. (Rockford IL), Control for an electrical generating and distribution system, and method of operation.
Jourdan, Jean-Marie; Betelle, Jean; Bougon, Philippe M. M., System for producing and distributing electrical energy for vehicles particularly aircraft, as well as an electrical power center for such a system.
Paik,Namwook; Donalds,Jamie; Landsman,Emanuel; Deokar,Vishwas; Rodenhiser,Fred; Williams,Steve, Apparatus and method for preventing an electrical backfeed.
Paik, Nam Wook; Haines, Lance Palmer; Deokar, Vishwas Mohaniraj; Donalds, James H.; Manganese, Michael, System and method for allocating power to loads.
Paik, Nam Wook; Haines, Lance Palmer; Deokar, Vishwas Mohaniraj; Donalds, James H.; Manganese, Michael, System and method for allocating power to loads.
Paik, Nam Wook; Haines, Lance Palmer; Deokar, Vishwas Mohaniraj; Donalds, James H.; Manganese, Michael, System and method for allocating power to loads.
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