Method and system for estimating evaporation representative of an area
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01W-001/00
A01G-025/16
출원번호
US-0394132
(2010-09-02)
등록번호
US-9229131
(2016-01-05)
우선권정보
ZA-2009/06090 (2009-09-02)
국제출원번호
PCT/IB2010/053946
(2010-09-02)
§371/§102 date
20120515
(20120515)
국제공개번호
WO2011/027313
(2011-03-10)
발명자
/ 주소
Savage, Michael John
출원인 / 주소
UNIVERSITY OF KWAZULU-NATAL
대리인 / 주소
Christie, Parker & Hale, LLP
인용정보
피인용 횟수 :
0인용 특허 :
5
초록▼
This invention related to a method of and a system for estimating evaporation representing an area at a particular location The method comprises receiving air temperature information, using the received air temperature information to determine at least average air temperature, standard deviation of
This invention related to a method of and a system for estimating evaporation representing an area at a particular location The method comprises receiving air temperature information, using the received air temperature information to determine at least average air temperature, standard deviation of the air temperature, and skewness of the air temperature at the particular location, receiving soil heat flux information and net irradiance information indicative of soil heat flux and net irradiance at the particular location respectively, determining, sensible heat flux at the particular location by using at least the determined average air temperature, standard deviation of the air temperature, and skewness of the air temperature associated with the particular location, and determining an estimate of the evaporation at the particular location by using the determined sensible heat flux, received soil heat flux and net irradiance information.
대표청구항▼
1. A method of estimating evaporation representing an area at a particular location, the method comprising the steps of: receiving, from at least one air temperature sensor at the particular location, air temperature information;determining, by using a processor, at least average air temperature, st
1. A method of estimating evaporation representing an area at a particular location, the method comprising the steps of: receiving, from at least one air temperature sensor at the particular location, air temperature information;determining, by using a processor, at least average air temperature, standard deviation of the air temperature, and skewness of the air temperature at the particular location substantially sub-hourly, by utilising the received air temperature;receiving, from a soil heat flux plate, soil heat flux information, the soil heat flux information being indicative of soil heat flux at the particular location;receiving, from a net radiometer, net irradiance information, the net irradiance information being indicative of net irradiance at the particular location;determining, sub-hourly, by using a processor, sensible heat flux at the particular location by utilising at least the determined average air temperature, standard deviation of the air temperature, and skewness of the air temperature associated with the particular location, anddetermining, sub-hourly, by using a processor, an estimate of the evaporation at the particular location by utilising the determined sensible heat flux, received soil heat flux information, and received net irradiance information, wherein the estimate of the evaporation is utilised for water resource management. 2. A method as claimed in claim 1, further comprising estimating, by using a processor, evaporation substantially in real-time or near real-time. 3. A method as claimed in claim 1, further comprising receiving, from a mobile or portable datalogger device, the air temperature information indicative of the skewness of air temperature, wherein the datalogger device comprises a statistical moment function to determine the skewness of the air temperature substantially in real-time from air temperature information received from a temperature sensor which is connected to the device or forms part thereof. 4. A method as claimed in claim 3, further comprising determining, by using a processor, the skewness of the air temperature in real-time from statistical moment information associated with the air temperature information received from the datalogger. 5. A method as claimed in claim 1, further comprising: determining, by using a processor, a structure function of air temperature, CT2 substantially in real-time; anddetermining, by using a processor, a structure parameter of refractive index, Cn2, in real-time, by utilising the determined structure function of air temperature CT2. 6. A method as claimed in claim 5, further comprising: receiving, at a processor, air temperature difference information between air temperatures measured by first and second air temperature sensors respectively which are located at the particular location; anddetermining, by using a processor, the structure function of air temperature CT2 by utilising the received air temperature difference information and a sensor distance between the first and second temperature sensors. 7. A method as claimed in claim 1, further comprising determining, by using a processor, the sensible heat flux by implementing a temperature-variance method, which includes adjustment for air temperature skewness, in the inertial sub-layer. 8. A method as claimed in claim 7, wherein the temperature variance method relies on Monin-Obukhov Similarity Theory (“MOST”). 9. A method as claimed in claim 1, further comprising determining, by using a processor, the sensible heat flux offline by way of an iterative procedure using MOST by utilising the determined structure parameter of refractive index Cn2. 10. A method as claimed in claim 1, further comprising determining, by using a processor, the sensible heat flux, for the roughness sub-layer, by implementing an air temperature structure function for a user-specified time lag. 11. A method as claimed in claim 10, further comprising determining, by using a processor, air temperature structure functions of order two, three and five respectively and using them to determine sensible heat flux offline by way of a surface renewal method which is implemented by the processor. 12. A method as claimed in claim 1, wherein determining the estimate of evaporation comprises subtracting, by using a processor, the determined sensible heat flux and received soil heat flux from the net irradiance. 13. A system for estimating evaporation representative of an area at a particular location, the system comprising: an air temperature receiver module arranged to receive air temperature information from temperature sensors at the particular location;a processor operable to use the received air temperature information to determine at least average air temperature, standard deviation of the air temperature, and skewness of the air temperature at the particular location sub-hourly;a soil heat flux receiver module arranged to receive soil heat flux information from a soil heat flux plate, the soil heat flux information being indicative of soil heat flux of the particular location;a net irradiance receiver module arranged to receive net irradiance information from a net radiometer, the net irradiance information being indicative of net irradiance associated with the particular location;a sensible heat flux determining module arranged to determine, in real-time, sensible heat flux associated with the particular location by using at least the determined at least average air temperature, standard deviation of the air temperature, and skewness of the air temperature at the particular location substantially sub-hourly, andan evaporation determining module arranged to determine, in real-time, an estimate of the evaporation level of the particular location by using at least the determined sensible heat flux, received soil heat flux information, and received net irradiance information, wherein the estimate of the evaporation is utilised for water resource management. 14. A system as claimed in claim 13, which includes: one or more air temperature sensors for measuring air temperature at the particular location, and wherein the air temperature receiver module is arranged to receive air temperature information from the temperature sensor at the particular location;a soil heat flux plate for measuring soil heat flux at the particular location, and wherein the soil heat flux receiver module arranged to receive soil heat flux information from the soil heat flux plate, the soil heat flux information being indicative of soil heat flux of the particular location; anda net radiometer for measuring the net irradiance associated with the particular location, and wherein the net irradiance receiver module is arranged to receive net irradiance information from the net radiometer, the net irradiance information being indicative of net irradiance associated with the particular location. 15. A system as claimed in claim 14, wherein the air temperature receiver module is communicatively coupled with a mobile or portable datalogger device, the datalogger device arranged for applying a statistical moment function to determine the skewness of the air temperature in real-time. 16. A system as claimed in claim 14, wherein, the sensible heat flux determining module is arranged to determine the sensible heat flux by a temperature variance method, including adjustment for air temperature skewness, in the inertial sub-layer. 17. A system as claimed in claim 16, wherein the temperature variance method relies on Monin-Obukhov Similarity Theory (MOST). 18. A system as claimed in claim 14, wherein the processor is configured to: determine a structure function of air temperature, CT2 in real-time and use the determined structure function of air temperature CT2 to determine a structure parameter of refractive index, Cn2, in real-time. 19. A system as claimed in claim 18, further comprising wo temperature sensors which are communicatively connected to the processor and which are, in use, positioned in the same horizontal plane, and wherein the processor is configured to: receive air temperature difference information between air temperatures measured by the first and second air temperature sensors respectively;determine or receive a sensor distance between the first and second temperature sensors; anduse the received air temperature difference information and the determined or received sensor distance to determine the structure function of air temperature CT2. 20. A non-transitory machine-readable medium embodying instructions which, when executed by a machine, cause the machine to: receive air temperature information from temperature sensors at a particular location;use the received air temperature information to determine average air temperature, standard deviation of the air temperature, and skewness of the air temperature associated with the particular location sub-hourly;receive soil heat flux information from a soil heat flux plate, the soil heat flux information being indicative of soil heat flux associated with the particular location;receive net irradiance information from a net radiometer, the net irradiance information being indicative of net irradiance associated with the particular location;determine, sub-hourly, sensible heat flux associated with the particular location by using at least the determined average air temperature, standard deviation of the air temperature, and skewness of the air temperature associated with the particular location sub-hourly, anddetermine, sub-hourly, an estimate of the evaporation level of the particular location by using at least the determined sensible heat flux, received soil heat flux information, and received net irradiance information, wherein the estimate of the evaporation is utilised for validating a remote sensing of the evaporation level of the particular location. 21. A non-transitory machine-readable medium as claimed in claim 20, wherein the machine-readable instructions, when executed by a machine, further cause the machine to: determine a structure function of air temperature, CT2 in real-time; and use the determined structure function of air temperature CT2 to determine a structure parameter of refractive index, Cn2, in real-time. 22. A non-transitory machine-readable medium as claimed in claim 21, wherein the machine-readable instructions, when executed by a machine, cause the machine to: receive air temperature difference information between air temperatures measured by first and second air temperature sensors respectively;determine or receive a sensor distance between the first and second temperature sensors; anduse the received air temperature difference information and the determined or received sensor distance to determine the structure function of air temperature CT2. 23. A non-transitory machine-readable medium as claimed in claim 20, wherein the machine-readable medium is configured for reading by a datalogger device. 24. A non-transitory machine-readable medium as claimed in claim 20, wherein the machine-readable medium comprises embedded code executable by a datalogger device. 25. A datalogger device comprising: an air temperature receiver module arranged to receive air temperature information from temperature sensors at a particular location;a processor operable to use the received air temperature information to determine average air temperature, standard deviation of the air temperature, and skewness of the air temperature associated with the particular location sub-hourly;a soil heat flux receiver module arranged to receive soil heat flux information from a heat flux plate, the soil heat flux information being indicative of soil heat flux associated with the particular location;a net irradiance receiver module arranged to receive net irradiance information from a net radiometer, the net irradiance information being indicative of net irradiance associated with the particular location;a sensible heat flux determining module arranged to determine, sub-hourly, sensible heat flux associated with the particular location by using at least the determined average air temperature, standard deviation of the air temperature, and skewness of the air temperature associated with the particular location, and an evaporation determining module arranged to determine, sub-hourly, an estimate of the evaporation level of the particular location by using at least the determined sensible heat flux, received soil heat flux information, and received net irradiance information, wherein the estimate of the evaporation is utilised in an atmospheric stability station for weather prediction. 26. A data-logging kit, comprising: a datalogger device as claimed in claim 25; andan air temperature difference sensor comprising: a first air temperature sensor; anda second air temperature sensor spaced at a predetermined sensor distance from the first air temperature sensor. 27. A datalogger device as claimed in claim 25, which includes: one or more air temperature sensors for measuring air temperature at the particular location, and wherein the air temperature receiver module is arranged to receive air temperature information from the temperature sensors at the particular location;a soil heat flux plate for measuring soil heat flux at the particular location, and wherein the soil heat flux receiver module arranged to receive soil heat flux information from the soil heat flux plate, the soil heat flux information being indicative of soil heat flux of the particular location; anda net radiometer for measuring the net irradiance associated with the particular location, and wherein the net irradiance receiver module is arranged to receive net irradiance information from the net radiometer, the net irradiance information being indicative of net irradiance associated with the particular location. 28. A datalogger device as claimed in claim 27, wherein the processor is configured to: determine a structure function of air temperature, CT2 in real-time; anddetermine a structure parameter of refractive index, Cn2, in real-time, by using the determined structure function of air temperature CT2. 29. A datalogger device as claimed in claim 28, wherein the processor is configured to: receive air temperature difference information between air temperatures measured by first and second air temperature sensors respectively;determine or receive a sensor distance between the first and second temperature sensors; andusing the received air temperature difference information and the determined or received sensor distance in order to determine the structure function of air temperature CT2. 30. A datalogger device as claimed in claim 27, wherein the processor is configured to apply a statistical moment instruction suitable for determining the skewness of the air temperature. 31. A datalogger device as claimed in claim 30, wherein the processor is configured to determine skewness from the moment of order three, average air temperature and the standard deviation of air temperature.
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이 특허에 인용된 특허 (5)
Upchurch Dan R. (Lubbock TX) Wanjura Donald F. (Lubbock TX) Burke John J. (Lubbock TX) Mahan James R. (Lubbock TX), Biologically-identified optimal temperature interactive console (Biotic) for managing irrigation.
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