초록 ▼

Adaptive irrigation of vegetation is achieved with a probe implanted into the soil for detecting rootage wetness needs by measuring soil impedance with contacts distributed along the probe. When a dryness threshold indicating rootage needs is met at a depth ZBEGIN previously entered into a control l

Adaptive irrigation of vegetation is achieved with a probe implanted into the soil for detecting rootage wetness needs by measuring soil impedance with contacts distributed along the probe. When a dryness threshold indicating rootage needs is met at a depth ZBEGIN previously entered into a control logic coupled to the probe, then irrigation is started. Irrigation is stopped when a wetness front is detected at depth Zend(i) automatically provided by the control logic. The depth of arrest of the drainage front Zfinal(i) descending below the depth Zend(i) is compared with a depth ZFINAL, also previously entered into the control logic. The depth Zend(i) is adapted at each irrigation cycle i for the drainage front to stop at the depth ZFINAL. The probe may be used to determine the depth ZBEGIN where resistance drops are detected first, by measuring resistance over time.

대표청구항 ▼

The invention claimed is: 1. A method for adaptive irrigation of vegetation including: a control logic for operating and managing successive cycles i of irrigation, with i=i [0,1,2, . . . ,n], for a vegetation having a maximum activity root layer (MARL) spanning a range of soil depth, at least one

The invention claimed is: 1. A method for adaptive irrigation of vegetation including: a control logic for operating and managing successive cycles i of irrigation, with i=i [0,1,2, . . . ,n], for a vegetation having a maximum activity root layer (MARL) spanning a range of soil depth, at least one probe for insertion into the soil, each at least one probe having a length and having a plurality of contacts longitudinally distributed in spaced-apart parallel alignment for deriving depth-related soil impedance data under command of the control logic, the at least one probe being coupled to the control logic via an electric circuit, at least one I/O device coupled to the control logic and allowing a user to input data, a controller running the control logic and coupled to command both the at least one I/O device and an irrigation valve operative for starting and for stopping irrigation fluid flow to the vegetation to be irrigated, respectively at a depth ZBEGIN and at a depth ZBEGIN, wherein: both ZBEGIN and Zend(i), are initial values entered as either one of both a user input or a default value, with ZBEGIN being disposed within the range of the MARL, and the depth Zend(I) corresponding to a depth above a depth ZFINAL, which is the depth below which a drainage front of the irrigation fluid should not descend, unless if so desired by a user, the method comprising the steps of: operating the control logic through the successive cycles i of irrigation for: accepting the irrigation-begin depth ZBEGIN as an initial value for a first cycle of irrigation, and in next cycles of irrigation, to derive from the at least one probe a depth ZBEGIN by taking resistance readings over all of the plurality of contacts to detect where changes in soil resistance measured over time increase fastest, which is where wetness uptake is most pronounced and indicates the depth ZBEGIN, and for accepting the depth Zend(i), as an initial value for a first cycle of irrigation, and in next cycles of irrigation, deriving from the at least one probe a depth Zend(i) which is adaptively adjusted at each irrigation cycle to converge towards the depth ZFINAL until reached, whereby irrigation fluid flow is started in response to wetness uptake properties of the rootage of the vegetation in the MARL, and stopped before the drainage front reaches the depth ZFINAL. 2. The method according to claim 1, wherein: the depth ZBEGIN, and the depth ZFINAL which is a control objective, are both entered as either one of both a user input into the control logic via the at least one I/O device and a default values, to provide rootage-property related depth values necessary for operating and for managing successive adaptive cycles of irrigation. 3. The method according to claim 1, wherein: soil-impedance derivation is adjusted to changing soil conditions by running an impedance reset operation at least once for each irrigation cycle. 4. The method according to claim 3, wherein: an impedance reset operation is performed immediately prior to start of irrigation fluid flow. 5. The method according to claim 1, wherein: soil dryness conditions are derived by measurement of soil impedance between a pair of adjacent contacts at depth ZBEGIN, and soil-impedance derivation is adjusted to changing soil conditions by running an impedance reset operation after stopping irrigation fluid flow, and after a time delay directly associated with fluid uptake properties of the roots. 6. The method according to claim 5, wherein: the time delay ranges between 5 hours and 20 hours. 7. The method according to claim 5, wherein: the time delay lapses after 10 hours. 8. The method according to claim 1, wherein: the irrigation-begin depth ZBEGIN is derived by utilizing the probe by taking at least one soil impedance measurement between each one of the adjacent contacts distributed along the probe, at least once after the irrigation fluid flow is stopped, ZBEGIN being detected within the MARL as a pronounced change in impedance. 9. The method according to claim 1, wherein: the depth Zend(i) at which the flow of irrigation fluid is stopped at the first irrigation cycle i=0 is optionally entered into the control logic via the at least one I/O device, and the depth Zend(i) is entered as any depth along the length of the probe, whereby a drainage front that descends below the depth of the probe for at least one irrigation cycle is an option. 10. The method according to claim 1, wherein: the probe is built as a spike assembled out of a collection of elements selected in combination from the group of modular elements having hollow contact pieces, hollow spacers, cones, and covers, each element being configured to provide solid mechanical retention support and firm fastening in longitudinal coextensive succession with an adjacent element, the spike has at least four contact pieces, three spacers, one cone, and one cover, assembled to form one unitary rigid probe, and the hollow contact pieces and the hollow spacers provide a coextensive and unobstructed passage interior to the spike. 11. The method according to claim 1, wherein: a dryness factor Y ranging from 1.1 to 2 is accepted as an initial value entered as either one of both a user input or a default, value, and a threshold for starting irrigation at the depth ZBEGIN is calculated by multiplication of the dryness factor Y by a reset resistance reading. 12. The method according to claim 1, wherein: a front factor T ranging from 0.9 to 0.95, for tracking either one of both a wetness front and a drainage front, is accepted as an initial value entered as either one of both a user input or a default value, a threshold for ending irrigation at the depth Zend (i) is calculated by multiplication of the front factor T by a reset resistance reading, the depth ZFINAL is an initial value entered as either one of both a user input or a default value, and the threshold for ending irrigation may be adjusted at each irrigation cycle until the depth ZFINAL is reached. 13. The method according to claim 1, wherein: the depth ZFINAL is an initial value entered as either one of both a user input or a default value, and the drainage front stop depth is detected at each next irrigation cycle, then compared to and adaptively adjusted if found different from the depth ZFINAL. 14. A computer readable memory storing instructions that, when executed by a microprocessor cause the microprocessor to perform each of the method steps of claim 1. 15. A computer readable memory storing instructions that, when executed by a microprocessor cause the microprocessor to perform each of the method steps of claim 2. 16. A computer readable memory storing instructions that, when executed by a microprocessor cause the microprocessor to perform each of the method steps of claim 3. 17. A computer readable memory storing instructions that, when executed by a microprocessor cause the microprocessor to perform each of the method steps of claim 4. 18. A computer readable memory storing instructions that, when executed by a microprocessor cause the microprocessor to perform each of the method steps of claim 5. 19. A system for irrigation of vegetation configured to intimately associate supply of irrigation fluid in response to vegetation-rootage related properties and needs, by adaptively adjusting successive irrigation cycles i, with i=i [0,1,2, . . . ,n], to converge toward a drainage fluid front arrest depth, comprising: a control logic for operating and managing irrigation for a vegetation having a maximum activity root layer (MARL) spanning a range of soil depth, at least one probe for insertion into the soil, each at least one probe having a length and having a plurality of contacts longitudinally distributed in spaced-apart parallel alignment for deriving depth-related soil impedance data from the soil under command of the control logic, the at least one probe being coupled to the control logic via an electric circuit, at least one I/O device coupled to the control logic and allowing a user to input data, a controller running the control logic, and coupled to command both the at least one I/O device and an irrigation valve operative for starting and for stopping irrigation fluid flow to the vegetation to be irrigated, respectively at a depth ZBEGIN and at a depth Zend(i), wherein: both ZBEGIN and Zend(i), are initial values entered as either one of both a user input or a default value, with ZBEGIN being disposed within the range of the MARL, and the depth zend(i) corresponding to a depth above a depth ZFINAL, which is the depth below which a drainage front of the irrigation fluid should not descend, unless if so desired by a user, wherein: operation of the control logic through the successive cycles i of irrigation for: the irrigation-begin depth ZBEGIN being entered as a preset parameter into the control logic for a first cycle of irrigation, and in next cycles of irrigation, deriving from the at least one probe a depth ZBEGIN by taking resistance readings over the plurality of contacts to detect where changes in soil resistance measured over time increases fastest, which is where wetness uptake is most pronounced and indicates the depth ZBEGIN, and for the depth ZBEGIN being entered as an initial value for a first cycle of irrigation, and next cycles of irrigation, deriving from the at least one probe a depth Zend(i) which is adaptively adjusted at each irrigation cycle to converge towards the depth ZFINAL, until reached, whereby irrigation fluid flow is started in response to wetness uptake properties and needs of the roots of the vegetation in the MARL, and stopped before the drainage front reaches the depth ZFINAL. 20. The system according to claim 19, wherein: the depth ZBEGIN, and the depth ZFINAL which is a control objective, are both entered as either one of both a user input into the control logic via the at least one I/O device and a default value, to provide rootage-property values necessary for operating and managing successive cycles of adaptive irrigation. 21. The system according to claim 19, wherein: soil-impedance derivation is adjusted to changing soil conditions by running an impedance reset operation at least once for each irrigation cycle. 22. The system according to claim 21, wherein: an impedance reset operation is performed just before starting irrigation fluid flow. 23. The system according to claim 19, wherein: soil dryness conditions are derived by measurement of soil impedance between a pair of adjacent contacts at depth ZBEGIN, and soil-impedance derivation is adjusted relatively to changing soil conditions by running an impedance reset operation after stopping irrigation fluid flow, and after a lapse of a delay for and directly associated with fluid absorption properties of the roots of the vegetation. 24. The system according to claim 23, wherein: the time delay ranges between 5 hours and 20 hours. 25. The system according to claim 23, wherein: the time delay lapses after 10 hours. 26. The system according to claim 19, wherein: the irrigation-begin depth ZBEGIN is obtained via the probe by sampling at least one impedance measurement for each one of the successive pairs of contacts distributed along the probe, at least once after the irrigation fluid flow is stopped, the depth ZBEGIN being distinguished within the range of the MARL as a distinctive change in impedance. 27. The system according to claim 19, wherein: the depth Zend(i) at which the flow of irrigation fluid is stopped at the first irrigation cycle i=0, is optionally entered into the control logic via the at least one I/O device as any depth along the length of the probe, whereby a drainage front that descends below the depth of the probe for at least one irrigation cycle is an option. 28. The system according to claim 19, wherein: the probe is built as spike assembled out of a collection of elements selected in combination from the group of modular elements having hollow contact pieces, hollow spacers, cones, and covers, each element being configured to provide solid mechanical retention support and firm fastening in longitudinal coextensive succession with an adjacent element, the spike has at least four contact pieces, three spacers, one cone, and one cover, assembled to form one unitary rigid probe, and the plurality of hollow contact pieces and of hollow spacers provide a coextensive and unobstructed passage interior to the spike. 29. The system according to claim 19, wherein: the depth ZBEGIN and a depth ZFINAL are entered into the control logic via the at leapt one I/O device, as two rootage-property related depth values necessary for operation of adaptive irrigation, and the depth Zend(i) is adaptively adjusted by the control logic, at each irrigation cycle, for the irrigation fluid flow to stop at the depth ZFINAL. 30. The system according to claim 19, wherein: a dryness factor Y ranging from 1.1 to 2 is accepted as an initial value entered as either one of both a user input or a default value, and a threshold for starting irrigation at the depth ZBEGIN is calculated by multiplication of the dryness factor Y by a reset resistance reading. 31. The system according to claim 19, wherein: a front factor T ranging from 0.9 to 0.95, for tracking either one of both a wetness front and a drainage front, is accepted as an initial value entered as either one of both a user input or a default value, a threshold for ending irrigation at the depth Zend(i) is calculated by multiplication of the front factor T by a reset resistance reading, the depth of ZFINAL is an initial value entered as either one of both a user input or a default value, and the threshold for ending irrigation may be adjusted at each irrigation cycle until the depth ZFINAL is reached. 32. The system according to claim 19, wherein: the depth ZFINAL is an initial value entered as either one of both a user input or a default value, and the drainage front stop depth is detected at each next irrigation cycle, then compared to and adaptively adjusted if found different from the depth ZFINAL.