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A plurality of wireless transmitters tethered to a plurality of soil moisture probes, each of said probes having first and second elongate conductive materials encapsulated in a non-conductive substrate, coupled to a power source and configured to be placed in the soil to form a capacitor. An irriga

A plurality of wireless transmitters tethered to a plurality of soil moisture probes, each of said probes having first and second elongate conductive materials encapsulated in a non-conductive substrate, coupled to a power source and configured to be placed in the soil to form a capacitor. An irrigation control box is equipped with a receiver and a processor coupled to a plurality of irrigation control valves, each irrigation control valve corresponding to an irrigation zone wherein at least one probe is placed. The processor converts signal data received from the plurality of transmitters into a soil moisture value and (i) opens a control valve corresponding to the zone to which the probe corresponds upon detecting that the soil moisture value in the zone has dropped below a threshold value and (ii) closes the control valve upon detecting that the soil moisture value has raised above a threshold value.

대표청구항 ▼

1. A system for controlling irrigation, comprising: a plurality of wireless transmitters coupled to a plurality of stand-alone soil moisture probes, wherein a single wireless transmitter is coupled to a single probe by a length of cable, and wherein each of the probes corresponds to a separate irrig

1. A system for controlling irrigation, comprising: a plurality of wireless transmitters coupled to a plurality of stand-alone soil moisture probes, wherein a single wireless transmitter is coupled to a single probe by a length of cable, and wherein each of the probes corresponds to a separate irrigation zone, said probe comprising: first and second elongate conductive materials encapsulated in a non-conductive substrate, said first and second elongate materials coupled to a power source and configured to be placed in the soil to form a capacitor;third and fourth elongate conductive materials encapsulated in the non-conductive substrate, said third and fourth elongate materials being conductively isolated from the first and second elongate conductive materials, coupled to a power source and configured to be placed in the soil to form a capacitor;a soil moisture circuit encapsulated in the non-conductive substrate coupled to the power source, said circuit having an oscillator for applying an electrical stimulus to the first and second elongate conductive materials and to the third and fourth elongate materials; anda ground conductive material in direct electrical contact with the soil disposed between the first and second elongate conductive materials, said ground conductive material being coupled to the soil moisture circuit and conductively isolated from the first and second elongate conductive materials;wherein the non-conductive substrate comprises a printed circuit board having a head and three coplanar prongs extending downward from the head, the first and second prongs extending downward from opposing sides of the head and the third prong extending downward between the first and second prongs, and wherein the first and third conductive materials are disposed within the first prong and the second and fourth conductive materials are disposed within the second prong, and wherein the ground conductive material is disposed on an outer surface of the third prong;an irrigation control box operatively coupled to a plurality of irrigation valves, wherein each of said irrigation valves corresponds to separate irrigation zones, and wherein said irrigation control box is configured to control the irrigation valves based on an upper and a lower soil moisture threshold value and comprises a receiver configured to receive a wireless data signal from the plurality of transmitters;wherein the irrigation control box is configured to receive a signal corresponding to an ambient temperature within an irrigation zone, and upon detecting that the ambient air temperature exceeds a threshold level, the irrigation control box is configured to modify the upper and lower soil moisture threshold values. 2. The system of claim 1, wherein the soil moisture circuit is configured to simultaneously apply an electrical stimulus to the first, second, third, and fourth elongate conductive materials. 3. The system of claim 1, wherein the soil moisture circuit is configured to simultaneously apply an electrical stimulus to the first and second elongate conductive materials followed by a simultaneous electrical stimulus to the third and fourth elongate conductive materials after a predetermined period of time. 4. The system of claim 1, wherein the cable extends outward from a head at an angle that is non parallel with a longitudinal axis of the probe. 5. The system of claim 4, wherein the head comprises a plurality of three collinear apertures each housing a coupling to the cable, the apertures being disposed at an angle that is non parallel with the longitudinal axis of the probe. 6. The system of claim 5, wherein the head of the probe is covered in a watertight covering that covers a portion of the cable. 7. The system of claim 1, wherein the irrigation control box contains a processor programmed to: (i) convert signal data received from the plurality of transmitters into a soil moisture value;(ii) open an irrigation control valve corresponding to the irrigation zone to which the probe corresponds upon detecting that the soil moisture value in the irrigation zone has dropped below a threshold value; and(iii) close the irrigation control valve corresponding to the irrigation zone to which the probe corresponds upon detecting that the soil moisture value in the irrigation zone has raised above a threshold value. 8. The system of claim 1, wherein the third elongate conductive material is disposed below the first elongate conductive material in the first prong and the fourth elongate conductive material is disposed below the second elongate conductive material in the second prong. 9. The system of claim 1, wherein the irrigation control box is configured to receive a signal corresponding to an ambient temperature within an irrigation zone, and upon detecting that the ambient air temperature exceeds a threshold level, the irrigation control box is configured to modify the upper and lower soil moisture threshold values. 10. A method of controlling irrigation, comprising: using a plurality of probes to detect a capacitance value in soil in a plurality of irrigation zones, wherein at least one probe is located in each of the plurality of irrigation zones, and wherein each probe is tethered to a wireless transmitter configured to send a wireless signal to an irrigation control box;transmitting a wireless signal from each of the plurality of wireless transmitters to a receiver coupled to the irrigation control box;receiving a plurality of signals from the plurality of wireless transmitters into a processor of the irrigation control box, said plurality of signals corresponding to the capacitance value in the soil measured in each one of the plurality of irrigation zones; converting the capacitance values to a soil moisture value and comparing the capacitance values to pre-determined upper and lower soil moisture threshold values; upon detecting that a soil moisture value in an irrigation zone has dropped below a lower threshold value, opening an irrigation control valve corresponding to the irrigation zone having the soil moisture value below the lower threshold value; upon detecting that a soil moisture value in an irrigation zone has raised above an upper threshold value, closing the irrigation control valve corresponding to the irrigation zone having the soil moisture value above the upper threshold value; measuring the ambient air temperature proximate to an irrigation zone; andupon detecting that the ambient air temperature exceeds a threshold level, modifying the upper and lower soil moisture threshold values;wherein the probes comprise: first and second elongate conductive materials encapsulated in a non-conductive substrate, said first and second elongate materials coupled to a power source and configured to be placed in the soil to form a capacitor;a soil moisture circuit encapsulated in the non-conductive substrate coupled to the power source, said circuit having an oscillator for applying an electrical stimulus to the first and second elongate conductive materials;third and fourth elongate conductive materials encapsulated in the non-conductive substrate, said third and fourth elongate materials being conductively isolated from the first and second elongate conductive materials, coupled to a power source and configured to be placed in the soil to form a capacitor; anda ground conductive material in direct electrical contact with the soil disposed between the first and second elongate conductive materials, said ground conductive material being coupled to the soil moisture circuit and conductively isolated from the first and second elongate conductive materials. 11. The method of claim 10, wherein the non-conductive substrate comprises a printed circuit board having a head and three coplanar prongs extending downward from the head and wherein the first and second prongs extend downward from opposing sides of the head and the third prong extends downward from the head and between the first and second prongs, and wherein the first and second conductive materials are disposed within the first and second prongs, respectively. 12. The method of claim 11, wherein the probe further comprises third and fourth elongate conductive materials encapsulated in the non-conductive substrate, said third and fourth elongate materials being disposed in the first and second prongs, respectively, and being conductively isolated from the first and second elongate conductive materials and electrically coupled to the soil moisture circuit. 13. The method of claim 12, further comprising simultaneously applying an electrical stimulus to the first and second elongate conductive materials followed a simultaneous electrical stimulus to the third and fourth elongate conductive materials after a predetermined period of time. 14. The method of claim 10, further comprising the steps of: (i) creating a priority ranking of irrigation zones;(ii) upon detection that the soil moisture value in more than one irrigation zones has dropped below a threshold value, ranking the irrigation zones where the soil moisture value has dropped below the threshold value according to the priority ranking; and(iii) opening the irrigation valve corresponding to the irrigation zone having the highest rank in step (ii). 15. The method of claim 10, wherein the non-conductive substrate comprises a printed circuit board having a head and three coplanar prongs extending downward from the head, the first and second prongs extending downward from opposing sides of the head and the third prong extending downward between the first and second prongs, and wherein the first and third conductive materials are disposed within the first prong and the second and fourth conductive materials are disposed within the second prong, and wherein the ground conductive material is disposed on an outer surface of the third prong. 16. A system for controlling irrigation comprising: a plurality of wireless transmitters tethered to a plurality of stand-alone soil moisture probes, each of said probes comprising: first and second elongate conductive materials encapsulated in a non-conductive substrate, said first and second elongate materials coupled to a power source and configured to be placed in the soil to form a capacitor;a soil moisture circuit encapsulated in the non-conductive substrate coupled to the power source, said circuit having an oscillator for applying an electrical stimulus to the first and second elongate conductive materials;third and fourth elongate conductive materials encapsulated in the non-conductive substrate, said third and fourth elongate materials being conductively isolated from the first and second elongate conductive materials, coupled to a power source and configured to be placed in the soil to form a capacitor; anda ground conductive material in direct electrical contact with the soil disposed between the first and second elongate conductive materials, said ground conductive material being coupled to the soil moisture circuit and conductively isolated from the first and second elongate conductive materials;an irrigation control box equipped with a receiver and a processor, said processor coupled to a plurality of irrigation control valves, each irrigation control valve corresponding to an irrigation zone, wherein at least one soil moisture probe is placed in the soil located in each irrigation zone;wherein the processor is programmed to convert signal data received from the plurality of transmitters into a soil moisture value, open an irrigation control valve corresponding to the irrigation zone to which the probe corresponds upon detecting that the soil moisture value in the irrigation zone has dropped below a threshold value, and close the irrigation control valve corresponding to the irrigation zone to which the probe corresponds upon detecting that the soil moisture value in the irrigation zone has raised above a threshold value; andwherein the irrigation control box is configured to receive a signal corresponding to an ambient temperature within an irrigation zone, and upon detecting that the ambient air temperature exceeds a threshold level, the irrigation control box is configured to modify the upper and lower soil moisture threshold values. 17. The system of claim 16 wherein the non-conductive substrate comprises a printed circuit board having a head and three coplanar prongs extending downward from the head, the first and second prongs extending downward from opposing sides of the head and the third prong extending downward between the first and second prongs, and wherein the first and third conductive materials are disposed within the first prong and the second and fourth conductive materials are disposed within the second prong, and wherein the ground conductive material is disposed on an outer surface of the third prong.