Generating digital models of nutrients available to a crop over the course of the crop's development based on weather and soil data

What is claimed is: 1. A method comprising: receiving over a network at an agricultural intelligence computing system comprising one or more processors and digital memory, electronic digital data comprising a plurality of values representing crop data, soil data, and weather data for one or more fields; using digitally programmed logic of the agricultural intelligence computing system, creating and storing in the computer memory a digital model of water flow through the one or more fields over a particular period of time based, at least in part, on the plurality of values representing crop data, soil data, and weather data by performing, for each time step of a plurality of time steps: creating an initial estimation of water flow into the one or more fields based, at least in part, on a plurality of values representing moisture content in the one or more fields; updating the plurality of values representing moisture content in the one or more fields; wherein the agricultural intelligence computer system dynamically alters a size of each time step of the plurality of time steps based, at least in part, on one or more of moisture content, hydrologic gradient, or soil type of the one or more fields; using digitally programmed logic in of the agricultural intelligence computing system, creating a digital model of nutrient availability in the one or more fields over the particular period of time based, at least in part on the digital model of water flow. 2. The method of claim 1 , wherein the digital model of nutrient availability in the one or more fields models an amount of the nutrient in the soil that the crop is capable of accessing and utilizing over a particular period in time by: computing an initial nutrient availability at an initial point in time comprising a portion of the nutrients in the soil that the crop is capable of accessing over the particular period of time as a function of initial nutrient levels in the soil, initial soil composition, and initial soil moisture; computing uptake of the nutrient by the one or more crops over the particular period of time; computing nutrient loss over the particular period of time to the atmosphere; computing nutrient loss over the particular period of time through leaching; computing a difference between the initial nutrient availability and the nutrient loss to the atmosphere and through leaching before the uptake of the nutrient by the one or more crops over the particular period of time after the particular point in time. 3. The method of claim 1 wherein creating and storing the digital model of water flow through the one or more fields includes determining one or more shape parameters for a hydrology curve by creating a plurality of curves that fit known parameters and selecting a particular parameter for the hydrology curve that minimizes a sum of square differences between a wilting point of the hydrology curve and a field capacity of the hydrology curve. 4. The method of claim 1 further comprising: using digitally programmed logic, determining that the digital model of water flow through the one or more fields contains one or more unrealistic moisture profiles; based on the determining, homogenizing moisture content over a soil profile of the one or more fields. 5. The method of claim 1 further comprising: creating one or more watering recommendations based, at least in part, on the digital model of water flow through the one or more fields and the plurality of values representing crop data, soil data, and weather data for one or more fields; sending the one or more watering recommendations to a field manager computing device. 6. The method of claim 5 further comprising: creating one or more watering recommendations; generating instructions for an application controller based on the one or more watering recommendations and sending the instructions to the application controller; wherein the instructions cause the application controller to control an operating parameter of an agricultural vehicle to implement the one or more watering recommendations. 7. The method of claim 1 : wherein the plurality of values representing crop data, soil data, and weather data for one or more fields include input data received from a field manager computing device comprising crop type, soil type, soil composition, and tillage methods applied to the one or more fields; wherein creating and displaying the digital model of nutrient availability includes: determining an effect on nutrient availability in soil of the one or more fields from the soil composition; and determining an effect on nutrient availability in the soil of the one or more fields from the tillage methods applied to the one or more fields. 8. The method of claim 1 further comprising: creating one or more stabilizer recommendations based, at least in part, on the digital model of nutrient availability in the one or more fields and the plurality of values representing crop data, soil data, and weather data for one or more fields; sending the one or more stabilizer recommendations to a field manager computing device. 9. The method of claim 1 further comprising: creating one or more nutrient recommendations; generating instructions for an application controller based on the one or more nutrient recommendations and sending the instructions to the application controller; wherein the instructions cause the application controller to control an operating parameter of an agricultural vehicle to implement the one or more nutrient recommendations. 10. The method of claim 1 further comprising: determining an optimal amount of a nutrient for one or more crops associated with the plurality of values representing crop data; determining, based on the digital model of nutrient availability in the one or more fields, that a modeled amount of nutrient availability in the one or more fields is less than the optimal amount of the nutrient for the one or more crops; sending a notification to a field manager computing device indicating that the modeled amount of nutrient availability in the one or more fields is less than the optimal amount of the nutrient for the one or more crops. 11. The method of claim 1 further comprising: causing display on a field manager computing device of a nutrient availability graph which indicates at least: a current amount of the nutrient available to one or more crops of the one or more fields; a past amount of the nutrient available to the one or more crops of the one or more fields; a projected future amount of the nutrient available to the one or more crops; an uncertainty in the projected future amount of the nutrient available to the one or more crops; and a fertility status of the one or more crops of the one or more fields which indicates whether a crop will meet its nutrient needs. 12. The method of claim 1 further comprising: causing display on a field manager computing device of event information which includes, for a particular event: a date of the particular event which affects the nutrient available to the one or more crops; a description of the particular event which affects the nutrient available to the one or more crops; and an indication of a magnitude of an effect on the nutrient available to the one or more crops from the particular event. 13. The method of claim 1 , further comprising: sending, over a network to a field manager computing device from the agricultural intelligence computing system, nutrient availability data indicating an availability of the nutrient in the one or more fields over a course of development of the one or more crops based on the digi