GRAIN HARVESTING LOGISTICAL TRACKING – UTILIZING GPS DATA TO BETTER UNDERSTAND GRAIN HARVESTING EFFICIENCY

Cheyenne Eunice/ Cox Simmons (18431367)

29 April 2024

<p dir="ltr">Precision agriculture has been around for many, many years but as technology has rapidly grown with the population, farmers are looking for more ways to improve their operation with the help of these tools. These tools help farmers manage, understand, and decide when, how and what should be done regarding the tough decisions in the field based on their machinery statues. The tools that utilize GPS location and provide farm managers with useful information and feedback on large scales of value in the Harvesting and planting operation. With previous works done focusing on identify state machine activity utilizing GPS location data with the use of loggers and algorithms this study carries on from one field to the next identifying the truth data set for each and the accuracy of the algorithm. The goal is to add a more realistic view to the states identifying turning and transporting throughout the harvesting operation in truth data and from algorithm results. Also diving into truck activity with lower standard GPS tracking to see how accurately they can be predicted to complete the harvesting cycle from vehicle to vehicle. Overall, the combine and grain cart held at 88% accuracy for labeling all state activity during the harvesting operation for multiple fields, while for the model algorithm with the grain trucks having an overall accuracy of 94%.</p>

Agricultural land management

Agricultural land planning

grain harvest

crop technology

grain movement

AGRICULTURE SYSTEM

grain management

crop management decisions

harvesting decisions

Digital Soil Mapping of the Purdue Agronomy Center for Research and Education

Shams R Rahmani (8300103)

07 May 2020

This research work concentrate on developing digital soil maps to support field based plant phenotyping research. We have developed soil organic matter content (OM), cation exchange capacity (CEC), natural soil drainage class, and tile drainage line maps using topographic indices and aerial imagery. Various prediction models (universal kriging, cubist, random forest, C5.0, artificial neural network, and multinomial logistic regression) were used to estimate the soil properties of interest.

Agricultural Land Management

Agricultural Land Planning

Sustainable Agricultural Development

Agronomy

Digital soil mapping (DSM)

Organic matter content

Cation exchange capacity

Natural soil drainage classes

geostatistical methods

Cubist modeling

Random Forest models

Universal Kriging

C5.0 or see5 modeling

Artificial neural network

Tile drainage lines

Soil spatial variation

Plant Phenotyping

Aerial Imagery

digital elevation model (DEM)

terrain attributes

Soil and Landscape

Very poorly drained

poorly drained

somewhat poorly drained

moderately well drained

User's accuracy

producer's accuracy

kappa coefficient

Multinomial logit regression

Tile Probe

topographic wetness index

Topographic Position Index

slope height

cross sectional curvature

Relative slope position

channel network distance

SSURGO soils data

internal validation

external validation