129 lines
6.8 KiB
Plaintext
129 lines
6.8 KiB
Plaintext
\documentclass[10pt, draftclsnofoot,onecolumn]{IEEEtran}
|
|
\linespread{1}
|
|
\begin{document}
|
|
|
|
\title{Fenceless Grazing Problem Statement}
|
|
\author{
|
|
\IEEEauthorblockN{Danila Fedorin},
|
|
\IEEEauthorblockN{Ryan Alder},
|
|
\IEEEauthorblockN{Matthew Sessions}
|
|
}
|
|
|
|
\maketitle
|
|
\begin{abstract}
|
|
Automation is an increasingly important component of modern business. However,
|
|
as other industries rise up the ladder of automation, cattle farming
|
|
stagnates: farmers continue to personally herd their cattle in the
|
|
same ways they did decades ago, exerting needless time and effort.
|
|
We propose an automated, fenceless grazing system that would allow
|
|
for the management of cattle through a digital interface, rather than
|
|
through physical labor. This system will consist of a collar
|
|
worn by individual farm animals that is capable of emitting loud
|
|
noises and administering mild shocks in order to control their
|
|
behavior.
|
|
\end{abstract}
|
|
|
|
\pagebreak
|
|
\section{Introduction}
|
|
Automation is prevalent in our modern age. Consumer technology like cars
|
|
and computers is assembled in enormous, largely automated factories, optimized
|
|
for utmost precision. Planting and harvesting is performed using specialized
|
|
machines that significantly decrease the time and effort required of the farmer.
|
|
Cattle farming, however, is diferent. To this day, the manipulation of herds
|
|
of cows is performed either by humans or by trained animals. Doing so
|
|
takes up a huge amount of time. At the same time, farmers list lack of labor
|
|
as the main limiting factor to their growth. The time and effort spent manually
|
|
herding cattle can be better used elsewhere, aleviating the labor shortage
|
|
and facilitating the growth of farms.
|
|
|
|
We propose a technology that can be used to automate the herding of cattle
|
|
largely without human or animal intervention. This technology is a specialized
|
|
collar, integrated with GPS, sound, and the ability to administer a mild shock.
|
|
Equipped with such a collar, the position of an animal will be well-known
|
|
through the GPS, and undesired behavior (such as leaving a particular area),
|
|
can be discouraged with an unpleasant sound, in some cases followed by
|
|
an electric shock. Together with the ability to specify desired locations
|
|
for a herd, this technology would allow farmers to control the animals
|
|
without physically being present, with various additional benefits.
|
|
|
|
\section{Solution Specifications}
|
|
\subsection{GPS}
|
|
The first component of our proposed solution is the integration of GPS
|
|
(Global Positioning System) into the collar. Through this, farmers
|
|
will be able to precisely track the locations of individual animals in a herd
|
|
without being physically present. This information, combined with
|
|
a description of the "allowed" area, can be used to judge whether or not
|
|
an animal is "out of bounds", and thus, if action should be taken to return
|
|
it to a desired location.
|
|
|
|
\subsection{Sound and Shock}
|
|
Simply knowing the location of an animal is not particularly helpful for
|
|
reducing the amount of human and animal labor that is needed for cattle
|
|
farming. The purpose of this project is to reduce such labor. To do
|
|
so, animals will be automatically discouraged from leaving an area
|
|
through the use of sounds and electric shocks. This can be done in
|
|
two stages. First, as the animal approaches an "out of bounds" area,
|
|
the collar's integrated speaker will produce an unpleasant sound.
|
|
The sound will get progressively louder as the cow approaches the
|
|
region boundary. At a particularly close distance, the device will
|
|
administer a shock, with the intention of discouraging further movemenent.
|
|
Should this be successful, farmer intervention will be unnecessary -
|
|
all the actions described above can be performed automatically by
|
|
the collar.
|
|
|
|
\subsection{LoRa}
|
|
It is one of the requirements for the product that the collar uses Long Range
|
|
(LoRa) technology to communicate with the controller and potentially
|
|
with other collars. LoRa can be used for long-range, low-power communication,
|
|
which is excellent for the type of product that were are developing. It is
|
|
important that the collar is able to support herds spread over wide
|
|
areas (to support big farms), and also be power efficient enough
|
|
to prevent the need for frequent maintenance. The client specifically
|
|
requested LoRa to be the protocol of choice.
|
|
|
|
\subsection{External Control System}
|
|
It is not difficult to imagine a situation in which the desired location
|
|
of a herd of animals changes. In such a case, the collars will need
|
|
to be adjusted to operate based on this new information. The third
|
|
component of our project is an interface that allows users to apply
|
|
changes to the operating parameters of the collar, performing adjustment
|
|
without having to be physically present with the cattle. In the best
|
|
case scenario, this interface will also allow users to monitor
|
|
in real time the location of the animals as they graze in a particular area.
|
|
|
|
The current idea for such a control system is a mobile app. Users
|
|
of this app will be able to modify the grazing boundaries of a herd through the
|
|
use of their mobile device.
|
|
|
|
\section{Performance Metrics}
|
|
Since this project specifies a physical device to be put onto animals,
|
|
the first metric to evaluate project completion is the existence
|
|
of a working prototype. At minimum, the working prototype should
|
|
be able to track the location of a farm animal, emiting a warning signal
|
|
(in the form of a sound and/or a shock) when the animal approaches
|
|
the boundary of the prescribed region.
|
|
|
|
Additionally, since an external control system (an app) is part of the project
|
|
specification, another performance metric is the usability of the client-facing
|
|
software. It should not be necessary for the client (likely a farmer) to have
|
|
an in-depth knowledge of the software or hardware that underlies the project.
|
|
Thus, the interface should be simple and intuitive. This can be evaluated
|
|
through a user study, presenting a completed application to a group of people
|
|
from the target demographic (farmers), and evaluating the outcomes of their
|
|
interaction with the software. Completion of the app will be achieved
|
|
when a client can successfully use the interface to perform actions
|
|
such as adjusting the grazing region and locating individual cows, with
|
|
the changes being reflected in the operation of the collar prototypes discussed above.
|
|
|
|
Finally, in order to determine whether or not the project has been completed,
|
|
it will be necessary to ensure that the prototype can be used in the field.
|
|
If a prototype is not fit for testing on real animals, it should not be
|
|
considered complete. Whether or not the proposed techniques are effective
|
|
at keeping cattle is another question - it's not outside the realm of
|
|
possibility that electric shocks and sounds are ineffective at manipulting
|
|
the behavior of farm animals. Thus, whether or not the device is effective
|
|
should not be a performance metric. However, to reiterate, it must
|
|
be possible to at least test it in the field.
|
|
|
|
\end{document}
|