최소 단어 이상 선택하여야 합니다.
최대 10 단어까지만 선택 가능합니다.
다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
NTIS 바로가기다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
DataON 바로가기다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
Edison 바로가기다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
Kafe 바로가기국가/구분 | United States(US) Patent 등록 |
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국제특허분류(IPC7판) |
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출원번호 | US-0276219 (2011-10-18) |
등록번호 | US-8538592 (2013-09-17) |
발명자 / 주소 |
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출원인 / 주소 |
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대리인 / 주소 |
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인용정보 | 피인용 횟수 : 13 인용 특허 : 140 |
Embodiments of the present invention provide methods and apparatus for water conservation with landscape irrigation controllers, plug-in and add-on devices, and centralized systems. In embodiments of the invention, a water budget percentage is determined by comparing current local geo-environmental
Embodiments of the present invention provide methods and apparatus for water conservation with landscape irrigation controllers, plug-in and add-on devices, and centralized systems. In embodiments of the invention, a water budget percentage is determined by comparing current local geo-environmental data with stored local geo-environmental data, and the preliminary irrigation schedule or station run times are automatically modified based upon that water budget percentage. Embodiments of the present invention also provide for automation of mandated landscape watering restrictions alone, or in various combinations with water budgeting methods and apparatus.
1. A method for controlling landscape irrigation by a controller comprising the steps of: a. automatically producing a water budget percentage without calculating reference evapotranspiration; andb. automatically modifying at least one irrigation schedule of said controller using said percentage. 2.
1. A method for controlling landscape irrigation by a controller comprising the steps of: a. automatically producing a water budget percentage without calculating reference evapotranspiration; andb. automatically modifying at least one irrigation schedule of said controller using said percentage. 2. The method of claim 1 wherein said step of producing a water budget percentage comprises comparing current environmental data for a location with stored geo-environmental data for the location. 3. The method of claim 2 wherein said stored geo-environmental data comprises historic evapotranspiration data. 4. The method of claim 2 wherein said current data is received from at least one environmental sensor. 5. The method of claim 4 wherein said at least one environmental sensor is selected from the group of: ambient temperature, soil temperature, soil moisture, solar radiation, wind, relative humidity, precipitation, and combinations thereof. 6. The method of claim 1 comprising the additional step of transmitting said water budget percentage wirelessly. 7. The method of claim 1 comprising the further steps of: c. providing at least one shut down sensor selected from the group of: a precipitation sensor, a wind sensor, and a freeze sensor; andd. preventing watering according to input from said at least one sensor. 8. The method of claim 2 comprising the further step of determining location from manual input. 9. The method of claim 8 wherein said determined location is used to obtain said historic geo-environmental data for said location. 10. A method of controlling landscape irrigation by a controller comprising the steps of: a. automatically producing a water budget percentage without calculating reference evapotranspiration, andb. automatically modifying at least one station run time of said controller using said percentage. 11. A method for controlling landscape irrigation by a controller comprising the steps of: a. automatically producing periodic water budget percentages without calculating reference evapotranspiration;b. accumulating said periodic water budget percentages over time; andc. automatically allowing watering to take place when said accumulated percentages reach a threshold. 12. The method of claim 11 wherein said step of producing water budget percentages comprises comparing current geo-environmental data for a location with stored geo-environmental data for the location. 13. The method of claim 12 wherein said stored geo-environmental data comprises historic evapotranspiration data. 14. The method of claim 12 wherein said current data is received from at least one environmental sensor. 15. The method of claim 14 wherein said at least one environmental sensor is selected from the group of: ambient temperature, precipitation, soil temperature, soil moisture, solar radiation, wind, relative humidity, and combinations thereof. 16. The method of claim 11 comprising the additional step of transmitting said water budget percentages wirelessly. 17. The method of claim 11 comprising the further steps of: c. providing at least one shut down sensor selected from the group of: a precipitation sensor, a wind sensor, and a freeze sensor; andd. preventing watering according to input from said at least one sensor. 18. The method of claim 12 comprising the further step of determining location from manual input. 19. The method of claim 18 wherein said determined location is used to obtain said historic geo-environmental data for said location. 20. A method for controlling landscape irrigation by a controller comprising the steps of: a. receiving at least one schedule of restricted watering times;b. automatically producing periodic water budget percentages without calculating reference evapotranspiration;c. accumulating said periodic water budget percentages over time; andd. automatically preventing irrigation until said accumulated percentages reach a threshold, and then automatically preventing irrigation until allowed according to said at least one restricted schedule. 21. The method of claim 20 wherein said step of producing a water budget percentage comprises comparing current environmental data for a location with stored geo-environmental data for the location. 22. The method of claim 21 wherein said stored geo-environmental data comprises historic evapotranspiration data. 23. The method of claim 21 wherein said current data is received from at least one environmental sensor. 24. The method of claim 23 wherein said at least one environmental sensor is selected from the group of: ambient temperature, soil temperature, soil moisture, solar radiation, wind, relative humidity, precipitation, and combinations thereof. 25. The method of claim 20 comprising the additional step of transmitting said water budget percentages wirelessly. 26. The method of claim 20 comprising the further steps of: c. providing at least one shut down sensor selected from the group of: a precipitation sensor, a wind sensor, and a freeze sensor; andd. preventing watering according to input from said at least one sensor. 27. The method of claim 22 comprising the further step of determining location from manual input. 28. The method of claim 27 wherein said determined location is used to obtain historic geo-environmental data for said location. 29. The method of claim 20 wherein a plurality of schedules of restricted watering times are received, and comprising the additional step of automatically selecting one of said restricted schedules by location. 30. The method claim 20 wherein said schedule of restricted watering times is received wirelessly. 31. The method of claim 29 comprising the further step of determining location from manual input. 32. The method of claim 31 wherein said determined location is used to obtain historic geo-environmental data for said location. 33. The method of claim 20 comprising the further step of manually inputting said schedule of restricted watering times. 34. The method of claim 20 wherein a plurality of schedules of restricted watering times are received, and comprising the additional step of automatically selecting one of said restricted schedules according to location. 35. A method for controlling landscape irrigation by a controller comprising the steps of: a. said controller receiving a plurality of schedules of restricted watering times;b. said controller automatically selecting one of said restricted schedules by location; andc. said controller disabling at least one valve to prevent irrigation at times when not allowed according to said selected schedule, wherein said controller further comprises programming to produce at least one water budget percentage without calculating reference evapotranspiration and wherein at least one environmental sensor is in communication with said controller, further comprising the steps of: d. automatically producing a water budget percentage based on input from said at least one sensor in comparison to stored environmental data; ande. automatically adjusting at least one station run time according to said water budget percentage. 36. A method of automatically adjusting landscape irrigation at a location comprising the steps of: a. establishing communication between a module and an irrigation controller at said location;b. said module automatically periodically producing a water budget percentage by comparing historical geo-environmental data for the location to current environmental data for the location;c. said module communicating said water budget percentage to said controller and automatically causing said controller to adjust watering according to said periodically produced water budget percentage. 37. The method of claim 36 wherein said step of adjusting watering comprises adjusting one or more station run times. 38. The method of claim 36 wherein said step of adjusting watering comprises altering watering days or intervals. 39. The method of claim 36 wherein said step of adjusting watering comprises altering watering schedules. 40. A method of automatically adjusting landscape irrigation at a location comprising the steps of: a. establishing communication between a module and an irrigation controller at said location;b. said module automatically periodically producing a water budget percentage by comparing historical geo-environmental data for the location to current environmental data for the location;c. said module communicating said water budget percentage to said controller and automatically causing said controller to adjust watering according to said periodically produced water budget percentage wherein said step of producing a water budget percentage is performed without calculating reference evapotranspiration. 41. The method of claim 40 wherein said stored geo-environmental data comprises historic evapotranspiration data. 42. The method of claim 41 wherein said current data is received from at least one environmental sensor. 43. The method of claim 42 wherein said at least one environmental sensor is selected from the group of: ambient temperature, soil temperature, soil moisture, solar radiation, wind, relative humidity, precipitation, and combinations thereof. 44. The method of claim 36 comprising the additional step of transmitting said water budget percentage wirelessly. 45. The method of claim 36 comprising the further steps of: c. providing at least one shut down sensor selected from the group of: a precipitation sensor, a wind sensor, and a freeze sensor; andd. said module automatically causing said controller to prevent watering according to input from said at least one shut down sensor. 46. The method of claim 41 comprising the further step of determining said location from manual input. 47. The method of claim 46 wherein said determined location is used to obtain historic geo-environmental data for said location. 48. The method of claim 36 comprising the further steps of: e. said module receiving at least three restricted watering schedules; andf. said module automatically causing said controller to also prevent watering when restricted according to one of said restricted watering schedules. 49. The method of claim 36 comprising the further steps of: e. said module receiving at least three restricted watering schedule; andf. said module automatically selecting an applicable one of said restricted watering schedules based on said location; andg. said module automatically causing said controller to also prevent watering when restricted according to said selected restricted watering schedule. 50. The method of claim 36 comprising the further steps of: e. said module receiving at least three restricted watering schedules;f. said module automatically selecting an applicable one of said restricted watering schedules based on said location; andg. said module automatically causing said controller to change at least one station start time so that irrigation occurs at times when allowed according to said selected schedule. 51. The method of claim 36 comprising the further steps of: e. said module receiving at least three schedules of restricted watering times;f. said module automatically selecting an applicable restricted schedule based on said location; andg. said module automatically causing said controller to change at least one station start time or watering day so that irrigation occurs at times or days when allowed according to said selected restricted schedule. 52. A method of automatically adjusting at least one watering schedule within an irrigation controller comprising the steps of: a. Plugging a module into said controller, said module comprising a microprocessor and programming;b. Establishing a communication link between at least one environmental sensor and said module;c. Said module automatically producing a water budget percentage based on input from said at least one sensor in comparison to stored geo-environmental data;d. Said module communicating said water budget percentage to said controller; ande. Said controller adjusting at least one watering schedule according to said water budget percentage. 53. A method of automatically adjusting at least one watering schedule within an irrigation controller comprising the steps of: a. Plugging a module into said controller, said module comprising a microprocessor and programming;b. Establishing a communication link between at least one environmental sensor and said module;c. Said module automatically producing a water budget percentage based on input from said at least one sensor in comparison to stored geo-environmental data;d. Said module communicating said water budget percentage to said controller; ande. Said controller adjusting at least one station run time according to said water budget percentage. 54. An irrigation controller comprising: a. A microprocessor;b. At least one environmental sensor in communication with said microprocessor;c. programming in said microprocessor to determine a water budget percentage without calculating reference evapotranspiration by comparing data from said at least one environmental sensor to stored historical environmental data within said microprocessor;d. said microprocessor capable of adjusting watering schedules based upon said comparison. 55. The controller of claim 54 wherein said microprocessor is capable of adjusting at least one station run time. 56. The controller of claim 54 wherein said environmental sensor is selected from the group consisting of: ambient temperature, soil temperature, soil moisture, relative humidity, wind, solar radiation, precipitation, and combinations thereof. 57. A system for automatically adjusting a watering schedule in an irrigation controller at a location comprising programming in said controller to automatically determine a water budget percentage without calculating reference evapotranspiration, programming in said controller to automatically adjust at least one watering schedule in said controller according to such water budget percentage, and an input in said controller for receiving current environmental data. 58. The system of claim 57 wherein said water budget percentage is based on current environmental data for said location in comparison to historical environmental data, and said historical environmental data comprises evapotranspiration data. 59. The system of claim 57 further comprising an input in said controller for receiving at least one schedule of restricted watering times, and programming in said controller to prevent watering when not allowed according to said restricted schedule. 60. The system of claim 57 further comprising an input in said controller for receiving at least one schedule of restricted watering times, and programming in said controller to change at least one station start time in said controller so that irrigation occurs at times when allowed according to said restricted schedule. 61. The system of claim 59 further comprising programming in said controller for selecting an applicable one of said at least one schedule of restricted watering times according to said location. 62. The system of claim 57 further comprising programming in said controller to accumulate water budget percentages and prevent irrigation until said accumulated percentages meet or exceed a threshold. 63. A system for automatically adjusting a watering schedule of a controller at a location through a plug-in device comprising programming in said plug-in device to automatically determine a water budget percentage, programming in said plug-in device to automatically adjust at least one watering schedule of said controller according to such water budget percentage, and an input in said plug-in device for receiving current environmental data. 64. The system of claim 63 wherein said automatic adjustment comprises changing at least one station run time. 65. The system of claim 63 wherein said water budget percentage is based on current environmental data in comparison to historical environmental data, and said historical environmental data is selected from the group consisting of historic evapotranspiration data, solar radiation data, relative humidity data, precipitation data, wind data, soil moisture, and combinations thereof. 66. The system of claim 63 further comprising an input in said plug-in device for receiving at least three schedules of restricted watering times, and programming in said plug-in device to prevent watering when not allowed according to one of said restricted schedules. 67. The system of claim 63 further comprising an input in said plug-in device for receiving at least three schedules of restricted watering times, and programming in said plug-in device to change at least one station start time in said controller so that irrigation occurs at times when allowed according to one of said at least one restricted schedules. 68. The system of claim 63 further comprising an input in said plug-in device for receiving at least three schedules of restricted watering times, and programming in said plug-in device for selecting an applicable one of said restricted watering times based on said location. 69. The system of claim 63 further comprising programming in said plug-in device to accumulate water budget percentages and prevent irrigation until said accumulated percentages meet or exceed a threshold. 70. A system for automatically adjusting a watering schedule of a controller at a location through an add-on device comprising programming in said add-on device to automatically determine a water budget percentage without calculating reference evapotranspiration, programming in said add-on device to automatically adjust at least one watering schedule of said controller according to such water budget percentage by breaking an output line from said controller, and an input in said add-on device for receiving current environmental data. 71. The system of claim 70 wherein said water budget percentage is based on current environmental data in comparison to historical environmental data, and said historical environmental data comprises historic evapotranspiration data for said location. 72. The system of claim 70 further comprising an input in said add-on device for receiving at least one schedule of restricted watering times, and programming in said add-on device to prevent watering when not allowed according to said restricted schedule. 73. The system of claim 70 further comprising programming in said add-on device for selecting an applicable one of said at least one schedule of restricted watering times. 74. The system of claim 70 further comprising programming in said add-on device to accumulate water budget percentages and prevent irrigation until said accumulated percentages meet or exceed a threshold. 75. An irrigation control device comprising a programmable module provided between an irrigation controller and at least one electronically operated valve, said module further comprising: a. a microprocessor and a power supply;b. at least one input for communication with a controller output;c. at least one output for communication with said at least one valve;d. at least one separate input for receiving a schedule of restricted watering times;e. at least one environmental sensor in communication with said microprocessor; andf. programming in said microprocessor to calculate a water budget percentage without calculating reference evapotranspiration, to disable said controller output according to said water budget percentage, and to disable said controller output at times when watering is not allowed according to said restricted schedule. 76. The method of claim 1 wherein a central unit having a microprocessor is provided separately from said controller, and said controller has an input, wherein the step of producing said water budget percentage is accomplished by said central unit, said step of modifying said at least one irrigation schedule is accomplished by said controller, and comprising the additional step of sending said water budget percentage from said central unit to said controller by wireless means. 77. The method of claim 1 wherein a central unit having a microprocessor is provided separately from said controller, and said controller has an input, wherein the step of producing said water budget percentage is accomplished by said central unit, said step of modifying said at least one irrigation schedule is accomplished by said controller, and comprising the additional step of sending said water budget percentage from said central unit to said controller. 78. The method of claim 4 wherein a central unit is provided separately from said controller, and said controller has an input, wherein the steps of producing said water budget percentage and modifying said at least one irrigation schedule is accomplished by said controller, and comprising the additional step of sending sensor data from said central unit to said controller. 79. The method of claim 11 wherein a central unit having a microprocessor is provided separately from said controller, and said controller has an input, wherein the step of producing said water budget percentages is accomplished by said central unit, wherein the steps of accumulating said water budget percentages and allowing watering to take place are accomplished by said controller, and comprising the additional step of sending said water budget percentages from said central unit to said controller. 80. The method of claim 14 wherein a central unit is provided separately from said controller, and said controller has an input, wherein the steps of producing said water budget percentages, and accumulating said percentages, is accomplished by said controller, and comprising the additional step of sending sensor data from said central unit to said controller. 81. The method of claim 20 wherein a central unit having a microprocessor is provided separately from said controller, and said controller has an input, wherein the steps of receiving at least one schedule and producing said water budget percentages are accomplished by said central unit, wherein the steps of accumulating said water budget percentages and preventing irrigation are accomplished by said controller, and comprising the additional step of sending said water budget percentages and a restricted watering schedule from said central unit to said controller. 82. The method of claim 29 wherein a central unit having a microprocessor is provided separately from said controller, and said controller has an input, wherein the steps of producing water budget percentages, receiving a plurality of schedules and automatically selecting one of said schedules is accomplished by said central unit, wherein the steps of accumulating said percentages and preventing irrigation are accomplished by said controller, and comprising the additional step of sending a restricted watering schedule and water budget percentages from said central unit to said controller. 83. The method of claim 20 wherein a central unit having a microprocessor is provided separately from said controller, and said controller has an input, wherein the steps of receiving at least one schedule and producing said water budget percentages are accomplished by said central unit, wherein the steps of accumulating said water budget percentages and preventing irrigation are accomplished by said controller, and comprising the additional step of sending said water budget percentages and a restricted watering schedule from said central unit to said controller. 84. The method of claim 23 wherein a central unit having a microprocessor is provided separately from said controller, and said controller has an input, wherein the steps of receiving at least one schedule is accomplished by said central unit, wherein the steps of producing said water budget percentages, accumulating said water budget percentages and preventing irrigation are accomplished by said controller, and comprising the additional step of sending current environmental data and a restricted watering schedule from said central unit to said controller. 85. The method of claim 34 wherein a central unit having a microprocessor is provided separately from said controller, and said controller has an input, wherein the steps of receiving said schedules and selecting a schedule are accomplished by said central unit, and the step of producing said water budget percentages is accomplished by said controller, and comprising the additional step of sending a restricted watering schedule and sensor data from said central unit to said controller. 86. The method of claim 34 wherein a central unit having a microprocessor is provided separately from said controller, and said controller has an input, wherein the step of receiving said schedules is accomplished by said central unit, and the steps of selecting a schedule and producing said water budget percentages are accomplished by said controller, and comprising the additional step of sending restricted watering schedules and sensor data from said central unit to said controller. 87. The method of claim 34 wherein a central unit having a microprocessor is provided separately from said controller, and said controller has an input, wherein the steps of producing said water budget percentages, receiving said schedules and selecting a schedule are accomplished by said central unit, and comprising the additional step of sending a restricted watering schedule and water budget percentages from said central unit to said controller. 88. The method of claim 34 wherein a central unit having a microprocessor is provided separately from said controller, and said controller has an input, wherein the steps of receiving said schedules and selecting a schedule are accomplished by said central unit, and the step of producing said water budget percentages is accomplished by said controller, and comprising the additional step of sending a restricted watering schedule from said central unit to said controller. 89. The method of claim 1 wherein a central unit having a microprocessor is provided, and a separate module plugged into said controller having an input is also provided, wherein the step of producing said water budget percentage is accomplished by said central unit, said step of modifying said at least one irrigation schedule is accomplished by said module, and comprising the additional step of sending said water budget percentage from said central unit to said module. 90. The method of claim 4 wherein a central unit is provided, and a separate module plugged into said controller having an input is also provided, wherein the steps of producing said water budget percentage and modifying said at least one irrigation schedule is accomplished by said module, and comprising the additional step of sending sensor data from said central unit to said module. 91. The method of claim 11 wherein a central unit having a microprocessor is provided, and a separate module plugged into said controller having an input is also provided, wherein the step of producing said water budget percentages is accomplished by said central unit, wherein the steps of accumulating said water budget percentages and allowing watering to take place are accomplished by said module, and comprising the additional step of sending said water budget percentages from said central unit to said module. 92. The method of claim 14 wherein a central unit is provided, and a separate module plugged into said controller having an input is also provided, wherein the steps of producing said water budget percentages and accumulating said percentages are accomplished by said module, and comprising the additional step of sending sensor data from said central unit to said module. 93. The method of claim 20 wherein a central unit having a microprocessor is provided, and a separate module plugged into said controller having an input is also provided, wherein the steps of receiving at least one schedule and producing said water budget percentages are accomplished by said central unit, wherein the steps of accumulating said water budget percentages and preventing irrigation are accomplished by said module, and comprising the additional step of sending said water budget percentages and a restricted watering schedule from said central unit to said module. 94. The method of claim 29 wherein a central unit having a microprocessor is provided, and a separate module plugged into said controller having an input is also provided, wherein the steps of producing water budget percentages, receiving a plurality of schedules and automatically selecting one of said schedules is accomplished by said central unit, wherein the steps of accumulating said percentages and preventing irrigation are accomplished by said module, and comprising the additional step of sending a restricted watering schedule and water budget percentages from said central unit to said module. 95. The method of claim 20 wherein a central unit having a microprocessor is provided, and a separate module plugged into said controller having an input is also provided, wherein the steps of receiving at least one schedule and producing said water budget percentages are accomplished by said central unit, wherein the steps of accumulating said water budget percentages and preventing irrigation are accomplished by said module, and comprising the additional step of sending said water budget percentages and a restricted watering schedule from said central unit to said module. 96. The method of claim 23 wherein a central unit having a microprocessor is provided, and a separate module plugged into said controller having an input is also provided, wherein the steps of receiving at least one schedule is accomplished by said central unit, wherein the steps of producing said water budget percentages, accumulating said water budget percentages and preventing irrigation are accomplished by said module, and comprising the additional step of sending current environmental data and a restricted watering schedule from said central unit to said module. 97. The method of claim 34 wherein a central unit having a microprocessor is provided, and a separate module plugged into said controller having an input is also provided, wherein the steps of receiving said schedules and selecting a schedule are accomplished by said central unit, and the step of producing said water budget percentages is accomplished by said module, and comprising the additional step of sending a restricted watering schedule and sensor data from said central unit to said module. 98. The method of claim 34 wherein a central unit having a microprocessor is provided, and a separate module plugged into said controller having an input is also provided, wherein the step of receiving said schedules is accomplished by said central unit, and the steps of selecting a schedule and producing said water budget percentages are accomplished by said module, and comprising the additional step of sending restricted watering schedules and sensor data from said central unit to said module. 99. The method of claim 34 wherein a central unit having a microprocessor is provided, and a separate module plugged into said controller having an input is also provided, wherein the steps of producing said water budget percentages, receiving said schedules and selecting a schedule are accomplished by said central unit, and comprising the additional step of sending a restricted watering schedule and water budget percentages from said central unit to said module. 100. The method of claim 34 wherein a central unit having a microprocessor is provided, and a separate module plugged into said controller having an input is also provided, wherein the steps of receiving said schedules and selecting a schedule are accomplished by said central unit, and the step of producing said water budget percentages is accomplished by said module, and comprising the additional step of sending a restricted watering schedule from said central unit to said module. 101. The method of claim 1 wherein a central unit having a microprocessor is provided, and a separate module installed on an output line of said controller having an input is also provided, wherein the step of producing said water budget percentage is accomplished by said central unit, said step of modifying said at least one irrigation schedule is accomplished by said module, and comprising the additional step of sending said water budget percentage from said central unit to said module. 102. The method of claim 4 wherein a central unit is provided, and a separate module installed on an output line of said controller having an input is also provided, wherein the steps of producing said water budget percentage and modifying said at least one irrigation schedule is accomplished by said module, and comprising the additional step of sending sensor data from said central unit to said module. 103. The method of claim 11 wherein a central unit having a microprocessor is provided, and a separate module installed on an output line of said controller having an input is also provided, wherein the step of producing said water budget percentages is accomplished by said central unit, wherein the steps of accumulating said water budget percentages and allowing watering to take place are accomplished by said module, and comprising the additional step of sending said water budget percentages from said central unit to said module. 104. The method of claim 14 wherein a central unit is provided, and a separate module installed on an output line of said controller having an input is also provided, wherein the steps of producing said water budget percentages and accumulating said percentages are accomplished by said module, and comprising the additional step of sending sensor data from said central unit to said module. 105. The method of claim 20 wherein a central unit having a microprocessor is provided, and a separate module installed on an output line of said controller having an input is also provided, wherein the steps of receiving at least one schedule, producing said water budget percentages and accumulating said water budget percentages are accomplished by said central unit, wherein the step of preventing irrigation is accomplished by said module, and comprising the additional step of sending said an accumulation signal and a restricted watering schedule from said central unit to said module. 106. The method of claim 20 wherein a central unit having a microprocessor is provided, and a separate module installed on an output line of said controller having an input is also provided, wherein the steps of receiving at least one schedule and producing said water budget percentages are accomplished by said central unit, wherein the steps of accumulating said water budget percentages and preventing irrigation are accomplished by said module, and comprising the additional step of sending said water budget percentages and a restricted watering schedule from said central unit to said module. 107. The method of claim 29 wherein a central unit having a microprocessor is provided, and a separate module installed on an output line of said controller having an input is also provided, wherein the steps of producing water budget percentages, receiving a plurality of schedules and automatically selecting one of said schedules is accomplished by said central unit, wherein the steps of accumulating said percentages and preventing irrigation are accomplished by said module, and comprising the additional step of sending a restricted watering schedule and water budget percentages from said central unit to said module. 108. The method of claim 20 wherein a central unit having a microprocessor is provided, and a separate module installed on an output line of said controller having an input is also provided, wherein the steps of receiving at least one schedule and producing said water budget percentages are accomplished by said central unit, wherein the steps of accumulating said water budget percentages and preventing irrigation are accomplished by said module, and comprising the additional step of sending said water budget percentages and a restricted watering schedule from said central unit to said module. 109. The method of claim 23 wherein a central unit having a microprocessor is provided, and a separate module installed on an output line of said controller having an input is also provided, wherein the steps of receiving at least one schedule is accomplished by said central unit, wherein the steps of producing said water budget percentages, accumulating said water budget percentages and preventing irrigation are accomplished by said module, and comprising the additional step of sending current environmental data and a restricted watering schedule from said central unit to said module. 110. The method of claim 34 wherein a central unit having a microprocessor is provided, and a separate module installed on an output line of said controller having an input is also provided, wherein the steps of receiving said schedules and selecting a schedule are accomplished by said central unit, and the step of producing said water budget percentages is accomplished by said module, and comprising the additional step of sending a restricted watering schedule and sensor data from said central unit to said module. 111. The method of claim 34 wherein a central unit having a microprocessor is provided, and a separate module installed on an output line of said controller having an input is also provided, wherein the step of receiving said schedules is accomplished by said central unit, and the steps of selecting a schedule and producing said water budget percentages are accomplished by said module, and comprising the additional step of sending restricted watering schedules and sensor data from said central unit to said module. 112. The method of claim 34 wherein a central unit having a microprocessor is provided, and a separate module installed on an output line of said controller having an input is also provided, wherein the steps of producing said water budget percentages, receiving said schedules and selecting a schedule are accomplished by said central unit, and comprising the additional step of sending a restricted watering schedule and water budget percentages from said central unit to said module. 113. The method of claim 34 wherein a central unit having a microprocessor is provided, and a separate module installed on an output line of said controller having an input is also provided, wherein the steps of receiving said schedules and selecting a schedule are accomplished by said central unit, and the step of producing said water budget percentages is accomplished by said module, and comprising the additional step of sending a restricted watering schedule from said central unit to said module. 114. A central broadcasting system comprising: a. Programming to determine a water budget percentage without calculating reference evapotranspiration;b. At least one remotely located irrigation controller having a microprocessor;c. A means for communicating a water budget percentage from said central broadcasting system to said at least one controller;d. Each controller microprocessor being capable of adjusting one of station run times, irrigation schedules, watering intervals, watering days, start times, and combinations thereof, according to said communicated water budget percentage. 115. The central broadcasting system of claim 114 wherein said communicated water budget percentage is received by a plug-in module to said at least one remote controller which communicates said water budget percentage to said controller microprocessor. 116. A method of affecting the irrigation schedule of at least one remotely located irrigation controller from a central location comprising the steps of: a. Providing a central broadcasting device with water budget determining capability that does not calculate reference evapotranspiration;b. Locating at least one remote irrigation controllers within communication of said central broadcasting device;c. Transmitting a determined water budget to said remote controllers; andd. Said at least one controller receiving said determined water budget and each such controller adjusting its watering schedule according to said determined water budget. 117. The method of claim 116 comprising the additional steps of: e. Providing said central device with restricted watering schedules;f. Said central device transmitting said restricted watering schedules;g. Said controllers receiving said restricted watering schedules, andh. Said controllers allowing irrigation according to said restricted watering schedules and said water budget percentage. 118. A method of using a controller, add-on or plug-in as a smart water device or as a time of use device comprising the steps of: a. Programming said device with historic geo-environmental data for a location;b. Providing said device with current environmental sensor data for said location;c. Automatically producing a water budget by comparing said historic data with said current sensor data at said location without calculating reference evapotranspiration;d. providing said device with restricted watering schedules including seasonal changes; ande. said device irrigating based upon one of said restricted seasonal watering schedules or said water budget. 119. The method of claim 118 wherein said programmed historic data includes evapotranspiration data. 120. The method of claim 118 wherein said provided sensor data is selected from the group of ambient temperature, precipitation, soil temperature, soil moisture, solar radiation, relative humidity, rain, and freeze sensors, wind, and combinations thereof. 121. The method of claim 118 comprising the additional step of identifying said restricted watering schedule by a location identifier selected from the group of: a zip code, latitude and longitude, water district, or municipality. 122. The method of claim 20 wherein said schedule of restricted watering times comprise drought stages. 123. The method of claim 33 wherein said schedule of restricted watering times comprises drought stages. 124. An irrigation system comprising: a. an irrigation controller having a microprocessor with a manual water budget feature;b. a separate apparatus having historical geo-environmental data;c at least one environmental sensor is in communication with said apparatus;d. said apparatus capable of automatically periodically determining a water budget percentage by comparing said historical geo-environmental data to current data from said at least one environmental sensor;e. said apparatus communicating said water budget percentage to said controller microprocessor by wired or wireless means; andf. programming in said controller microprocessor to automate said manual water budget feature with said periodically determined water budget percentage communicated from said apparatus. 125. The irrigation system of claim 124 wherein said at least one environmental sensor is selected from the group of a temperature sensor, a precipitation a sensor, a solar radiation sensor, a relative humidity sensor, a wind sensor, and combinations thereof. 126. The irrigation system of claim 125 wherein said at least one environmental sensor communicates with said apparatus by wired or wireless means. 127. The irrigation system of claim 125 wherein said historical geo-environmental data is selected from the group of: ambient temperature, solar radiation, evapotranspiration, relative humidity, wind, precipitation, soil moisture, soil temperature, extraterrestrial radiation factors, and combinations thereof. 128. An irrigation system comprising: a. an irrigation controller having a microprocessor;b. a module separate from said controller, said module having a second microprocessor programmed with historical geo-environmental data, said second microprocessor being in communication with said controller microprocessor;c. at least one environmental sensor in communication with said second microprocessor;d. said second microprocessor having programming for periodically determining a water budget percentage by comparing said historical geo-environmental data to current environmental data from said sensor and communicating said percentage to said controller microprocessor; andf. said controller microprocessor having programming for adjusting a member selected from the group consisting of a station run time, a watering day, a watering interval, a start time, and combinations thereof, according to said communicated water budget percentage. 129. An irrigation controller comprising: a. a microprocessor having a calendar and self-adjusting technology that is water budget percentage based, determined by comparing current environmental sensor data to historical geo-environmental data self-adjusting technology;b. at least one restricted watering schedule provided to said microprocessor; andc. said microprocessor being capable of operating by alternating between self-adjusting technology or said restricted watering schedule based on said calendar wherein said water budget percentage is determined without calculating evapotranspiration. 130. A method of automatically adjusting an irrigation schedule comprising the steps of: a. installing a separate module upon an irrigation controller with appropriate software changes to the instruction set of the controller to communicate with said module;b. providing said module with historical geo-environmental data;c. providing current environmental sensor data to said module from at least one sensor;d. said module determining a water budget percentage by comparing said historical geo-environmental data to said current sensor data in said module;e. communicating said water budget percentage to said controller; andf. said controller automatically adjusting an irrigation schedule according to said communicated water budget percentage. 131. The method of claim 130 wherein the step of adjusting an irrigation schedule includes a member selected from the group of: adjusting at least one station run time, adjusting at least one watering day, adjusting at least one watering interval, adjusting at least one start time, and combinations thereof. 132. The module of claim 130 wherein said environmental sensor data is provided by wireless means to said module. 133. A method of automatically adjusting an irrigation schedule comprising the steps of: a. installing a separate module upon an irrigation controller with appropriate software changes to the instruction set of the controller to communicate with said module;b. providing said module with historical geo-environmental data;c. providing current environmental sensor data to said module from at least one sensor;d. said module determining a water budget percentage by comparing said historical geo-environmental data to said current sensor data in said module;e. communicating said water budget percentage to said controller; andf. said controller automatically adjusting an irrigation schedule according to said communicated water budget percentage wherein said water budget percentage is determined without calculating reference evapotranspiration. 134. An irrigation system comprising: a. an irrigation controller having a microprocessor with a manual water budget feature;b. a separate apparatus having historical geo-environmental data;c at least one environmental sensor is in communication with said apparatus;d. said apparatus capable of automatically periodically determining a water budget percentage by comparing said historical geo-environmental data to current data from said at least one environmental sensor;e. said apparatus communicating said water budget percentage to said controller microprocessor by wired or wireless means; andf. programming in said controller microprocessor to automate said manual water budget feature with said periodically determined water budget percentage communicated from said apparatus wherein said water budget percentage is determined without calculating reference evapotranspiration.
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