Applied Analytics for Business – Agriculture PDF

Summary

This presentation from Praxis Business School covers applied analytics for agriculture in India. It examines challenges such as climate change, resource constraints, and crop yields, and potential solutions leveraging data science. The presentation includes information on the Global Agricultural landscape and case studies on various technologies.

Full Transcript

Applied Analytics for
Business – Agriculture

Dr. Ravi Shankar
Prof – Data Science (AI -ML)
Dean – Enterprise Solutions & Academic Collaborations
https://www.linkedin.com/in/ravi-shankar-70584b1/
[email protected]

First

Session , 29th AUG, 2023

Introduction – Global Agri : Challenges & Solutions

Faculty Profile : Dr. Ravi Shankar
INTRODUCTION
• Background: PhD - Econometrics,
Entrepreneur, Start-up Mentor, Social
Impact Investor, Data Science Thought
Leader, Senior Venture Partner

• Current Focus: AI adoption in Business,
Deep Learning, XAI, ML Operations, Design
Thinking, OB & Strategy

• Sectoral Exposure: multiple sectors
straddling BFSI / Pharma / Manufacturing /
Retail / Tech

• Overall Experience : 30 Yrs.

Applied Analytics for Business - Agriculture: Learning Journey

Five sessions of 90 mins each
First session

Second session

Third session

Fourth session

Fifth session

Agri 4.0 & Agri Data

AI-ML
Applications in
Agri – use cases

IntroductionThe Global
Agricultural
Challenge &
Solutions

Agri & AgTech Indian Landscape

AgTech &
Agriculture in India

STRUCTURE & Learning outcomes…
The
Agricultural
Challenge

https://youtu.be/jF07b7IDxus

Solution

https://youtu.be/tQ5jADa0DAs
https://youtu.be/25sQYqviC28

Big Data in
Agri

https://youtu.be/GKfJU5rYHYo
https://youtu.be/4r_IxShUQuA
https://youtu.be/WKGQQXwZDQ4
https://youtu.be/Ks0lBuaqyjM

1.
2.
3.
4.
5.

Global Agri Challenge & Solutions
The intuition behind Big Data in Agri
Data Science in Agri
Challenges relating to application
Real world examples

Digitization in agriculture, precision agriculture,
drones and IoT in farming.

“Demonstration of ICT applications and Agri
informatics”

Speaker Profile : Dr. Ravi Shankar
INTRODUCTION
• Background: PhD –Agril Economics,
Visiting Prof Ai-ML, Entrepreneur, Startup Mentor, Social Impact Investor, Data
Science Thought Leader, Senior Venture
Partner

• Current Focus: AI adoption in Business,
Deep Learning, XAI, ML Operations, Design
Thinking, OB & Strategy

• Sectoral Exposure: multiple sectors
straddling BFSI / Pharma / Manufacturing /
Retail / Tech

• Overall Experience : 32 Yrs.
6

Structure

•
•
•
•

Motivation
Backdrop
Challenges & solution
Digitization of Indian Agriculture

• IoT in Indian Agriculture
• Use of Drones in Indian Agriculture
• Satellite Imagery applications in Indian Agriculture

• Natural Farming in India
• Role of AgTech Startup’s
• Summary

"We Didn't Run Out Of Television Screens And
Planes, We Ran Out Of Food."
The best Interstellar quotes not only sum up the
themes of the movie but are generally thoughtprovoking lines. Joseph Cooper (Matthew
McConaughey) and his daughter Murph (Jessica
Chastain) are only two of the highly intelligent
characters that make up the core cast of the movie.
With scientists, astronauts, and advanced robots as the
main characters, Interstellar is bursting with smart
dialogue about scientific and philosophical concepts.
In this thought-provoking Interstellar quote, the
school's principal (David Oyelowo) reminds Cooper
why farmers have become more important than
engineers in their world.

https://youtu.be/qhW1HfSuPVQ

Motivation
• Relevance of digitalization in India Agriculture cannot be overstated
• Indian Agriculture – facing unprecedented challenges
•
•
•

Growing population
Climate change
Resource constraints

•
•

Data driven decisions
Management efficiency

•
•
•

Reduce costs
Minimize environmental impact
Optimise farm operations

•

Integration of Digital Technologies & Data Management systems into farming practices & supply chains

• Solution – Digitalization
• Benefits - many

• KSF

The evolution of Indian
Agriculture – From
Scarcity to Optimisation….

Solution –
Digitization / Agri
5.0 Paradigm

Mid 21st Century –
Quality, Safety &
Optimisation

Traditional farming methods face multiple
challenges, including resource depletion and
environmental degradation. But with the
concept of digitization, the future of
agriculture looks promising.

Early 21st Century –
Efficiency related
challenges
1960’s & 70”s –
Green Revolution –
adequate quantities
Late 19th & early 20th
Century – Starvation &
Supply side constraints

Indian Agriculture: An Overview
1

Large Sector

2

Small Holdings

Indian agriculture is one of

Most farms in India are

the largest agricultural

small, with an average

systems in the world,

landholding size of less

contributing significantly to

than 2 hectares. These

the country's GDP and

small farmers struggle with

employing nearly half of the

a lack of resources,

total workforce.

unpredictable weather, and
market volatility.

3

Diverse Crops
India is home to a wide variety of crops, including rice, wheat,
cotton, sugarcane, and many more. The country is also a major
exporter of spices and fruits.

Challenges Faced by Indian Farmers
Unpredictable Weather

Limited Access to Resources

Indian farmers frequently face unpredictable

Many small farmers don't have access to

weather patterns and natural disasters that

modern farming technology, adequate

can damage crops.

irrigation, or quality seeds or fertilizers.

Market Volatility

Poor Infrastructure

Fluctuating market prices and lack of market

India's rural infrastructure, including roads

information often leave farmers without

and electricity, is often inadequate, making it

access to fair prices for their crops.

difficult for farmers to transport goods to
markets and access modern technologies.

THE AGRICULTURAL
CHALLENGE

A sobering statistic:
Food production must
increase 50-70 % by
2050 to feed a
projected population
of 9 Billion people
“The End of Plenty”

WORLD POPULATION

Alexandratos N, Bruinsma J.2012.World agriculture towards 2030/2050, the 2012 revision. ESA Working Paper No.
12-03, June2012. Rome: Food and Agriculture Organization of the United Nations (FAO)

AGRICULTURAL DEMAND

POPULATION
MORE PEOPLE

CONSUMPTION
HIGHER DEMAND / CAPITA

GREEN REVOLUTION

NORMAN BORLAUG
IS CREDITED WITH SAVING

1 BILLION LIVES

YIELD INCREASES

Ray DK, Mueller ND, West PC, Foley JA. 2013.Yield Trends Are Insufficient to Double Global Crop Production by 2050. PLoS ONE 8(6),
doi:10.1371/journal.pone.0066428.

crop yield must

I N C R EA S E

*

to meet demand

by 2050
Ray DK, Mueller ND, West PC, Foley JA. 2013.Yield Trends Are Insufficient to Double Global Crop Production by 2050. PLoS ONE 8(6),
doi:10.1371/journal.pone.0066428.

IT’S POSSIBLE

“I now say that the

world has the
technology… to feed
on a sustainable basis
a population of
10 billion people.”
Normal Borlaug

DATA SCIENCE MEETS

AGRICULTURE

NEXT REVOLUTION ?
GREEN REVOLUTION
1960 –

BIOTECH REVOLUTION
1980 –

GREEN DATA REVOLUTION
2010 –

INTENSIFY
Apply breeding, fertilization
to increase yields.

BIOTECH
Marker assisted selection.

OPTIMIZE
Apply data science to
optimize management.

DATA SCIENCE
How can it be built?

Computer Science

SCIENTIFIC DATA
SCIENCE

use software engineering to
enable domain science
maximizing use of data

Domain Science

What is important?

Statistics

How can predictions be made?

Annually
one-third
Working
withof crops are lost globally

27%

Loss in crops due to imbalance or lack of nutrients

Upto 40%

Loss in crops due to pest and diseases

20%

Loss in crops due to water stress

30%

Loss in the farm income.

33%

Land is already degraded and over 90% could
become degraded by 2050. SOC is ~0.5%.

0.3 m/yr

Declining water table in India.

Source: FAO. Global food losses and food waste – Extent, causes and prevention.

Existing
solutions
are not reaching farmers
Working
with

Precise

●
●
●
●

Drone
IoT sensors
Agri expert
Laboratory

Scalable
Required
solution which
is precise and
scalable

●

●

Standard package
of practices
Local retailers

●
●

Source: Lowder, S. K., Skoet, J., & Raney, T. (2016). The number, size, and distribution of farms, smallholder farms, and family farms worldwide.
World Development, 87, 16-29.

Globally, about 80% of
the farms are small and
marginal.
Currently available
solution are either
precise or scalable

Digital Agriculture : Integration of cutting edge
technologies (AI-ML | Big Data Analytics | IoT)

Identify the
problem

Data collection

Data analysis

Solution
implementation

Benefits of Digitization
Efficient resource management

Improved yields and quality

Digitization allows for precision agriculture,

Digital tools such as drones and sensors can

maximizing the use of resources and

monitor crop health and alert farmers to

minimizing waste.

potential issues.

Greater data visibility

Cost-effective

Digital records make it easier to track crop

Digitization reduces the need for manual

growth, soil moisture, and more.

labor, helping farmers save money and time.

Source: Niti Aayog – Role of Digital and AI Technologies in Indian Agriculture: by Tanay Mahindru

Challenges with AI/Digital
● Clean Data Sets
●

Lack of data sets – example – pest on leaves

●

Diverse data sets between public, private and govt
departments

●

Lack of normalized data sets

● Each state has different language and
units, which makes it harder for data
normalization.
● Acceptability & adoption
●

Who will pay for this, given so many small Farmers

●

Interoperable standards needed in Agristack being developed by various players

The Potential of Digital Agriculture
1

Climate-Smart Agriculture

2

The Internet of Things (IoT)

Digital tools can assist with weather

Sensors enable farmers to receive

forecasting and mitigation of climate-

up-to-date information about crop

related risks.

health and weather conditions,
improving decision-making.

3

Farm Management Software

4

Fintech for Farmers

Software like FarmERP helps

Startups like FarmFundr and Clover,

farmers optimize resources, manage

leverage fintech to provide loans to

inventory, and improve traceability

farmers for seeds, fertilizers, and

across the supply chain.

equipment, helping them overcome
financial barriers.

Areas that AI can solve - Full Supply Chain Summary View

Easy
Access to
Credit

Insurance
payout linked
to more
accurate yield

Early Pest
Detection

Early
Locust
Detection

Drone
based pest
spray and
monitoring

Precision
Farming

Farm
Monitoring and
Price/Yield
Advisory

Rental of
equipment

Farm
Inputs

Financing
Which crop
to sow
Advisory
Knowledge
Availability
on Social
media

Seed
Traceability

Farming

Selling and
Distribution
Product
Traceability
Aggregator
Marketplaces
for efficient
price discovery

Optimal
Harvesting
Calendar using
Price forecast

Farmer
Produce
Organizations

Farm-to-Fork Agri Value Chain

Sowing

Pre-Sowing
●
●
●

Farm
Inputs

●

Land
Preparation

●

Soil Testing

Machinery
Management
Sowing
Advisory

Crop Cultivation
●

Farm Monitoring

●

Transportation

●

Weather Advisory

●

●

Disease & Pest
Management

Yield
Management

●

Storage
Management

●

Packaging

●

Traceability

●

Irrigation and
fertigation
management

Post
Harvest

Harvest
●

Market Linkage

32
© Wolkus Technology Solutions Private Limited 2020

Nutritional Security
An Existential Threat

Malthusian Necessities of Life

Food, Shelter, Fiber, Fuel > 9 billion

Path Forward
• Transformative discoveries
– Internet of Agricultural Things
– Big Data

•
•
•
•
•
•

21st Century Extension
Farming systems
Education
Policies, regulation, marketing
Human dimensions
Communications

#InternetOfAgThings
In a world where population is expected to grow
significantly, natural resources become scarcer and
climate changes dramatically, we need to produce
much more with much less.

21st Century Farm

Supply Chain

•
•
•
•
•
•
•
•
•
•

On Farm Production
Soil Health, Water, Nutrients
Pests/Control
Energy
Traceability and Tracking
Supply Chain Management
Processing
Inspection
Transportation
Storage

•
•
•
•
•
•
•
•
•
•

Retailers
Inventory
Access
Smart Refrigerators
Food Safety
Ripeness
Shrink Wrap
Waste
Smart Services
Etc.

Food Waste and Food Loss

➢ Double food production in 40 years
➢ Cut loss/waste by half?
➢ Impact climate change
Adapted from Bonn2011 Nexus Conference: http://www.water-energy-food.org/en/news/view 255/understanding-the-nexus.html
http://phys.org/news/2014-06-date-contributes-food.html

Precision Foods
• Individual genome, epigenome, microbiome
• Plant/animal genome, epigenome, microbiome
• Wearable sensors
– FitBit, Apple Watch
– Athos, Hexoskin, Gymi
– Google contact lens

• Food analysis
• Lifestyle
• Behavior

Revolutionizing
Agriculture with ICT
and Agri Informatics
Discover how ICT and advanced informatics systems are transforming

agriculture and optimizing food production across the globe & in INDIA

Digitization in Agriculture: Transforming the
Way We Farm
Benefits 🌱

Challenges 🌾

Access to real-time data, better decision

From high implementation costs to data

making, and increased efficiency are just

management challenges, we explore the

some of the benefits of digitization in

main hurdles of digitization in agriculture

agriculture.

and how to overcome them.

Digital Indian Agriculture
• 2022 Union Budget:
•
•
•

Emphasis on Kisan Drones
Chemical free Natural Farming
PPP for delivery of digital & high tech services to farmers

• 2023 Union Budget : Focus on Digital Agriculture
•
•
•
•
•
•
•

Digital Agriculture Mission – with a primary focus on digital infrastructure, digital
extension services, digital finance and digital research and development
India Digital Ecosystem of Agriculture (IDEA)
Support in digital infrastructure development and improving its adoption by
farmers
Promoting data-driven ecosystem and digital services through Agri Stack
Incentivizing capital investments at farmgate levels to boost the MSME
segment and promote rural entrepreneurship
Promoting Agritech Startups
Focus on output linkage through e-commerce

Precision Agriculture: A New Paradigm
for Sustainable Farming

Definition

Examples

Precision agriculture is a science-based

From soil moisture sensors to drones, we

approach to farming that uses technology to

showcase the latest and most innovative

optimize crop yield while minimizing waste.

technologies driving precision agriculture.

Drones in Agriculture:
Applications and Benefits
1

Farm Planning 📝

2

Pest Control 🐛

Drones offer valuable

Drones can be equipped

insights into crop health,

with targeted spraying

which helps farmers make

systems to efficiently

better decisions to

deliver pesticides and

optimize crop production.

herbicides to crops while
reducing waste.

3

Mapping 🗺️
Drones can be used to create highly accurate maps of crop fields,
providing farm managers with invaluable information on soil
properties, groundwater, and weather patterns.

Internet of Things (IoT) in Natural Farming: Connecting Our
Farms to the Future
Implementation Challenges

Future Trends

From technical difficulties to data

From the use of big data and AI to

management issues, we explore

the development of new sensors

the main challenges of

and monitoring technologies, we

implementing IoT in natural

explore the exciting future of IoT

farming.

in natural farming.

1

2

3

Role and Impact

Case Studies

IoT is transforming natural farming

We showcase successful

by providing real-time data and

implementation stories from

insights, allowing farmers to

around the world, demonstrating

optimize yield and reduce costs.

how IoT can make a difference in
natural farming.

4

Case Studies of Successful Implementation:
How Leading Farms Are Harnessing the Power
of Technology to Boost Yield and Efficiency

FarmBot 🤖

BlueRiver
Technology 💦

John Deere 🔍

capabilities, FarmBot has

BlueRiver has created a

and data analytics solutions,

helped farmers reduce labor

breakthrough technology that

John Deere has become a

costs while boosting crop

uses computer vision and AI

leading name in precision

yield through highly precise

to deliver real-time

agriculture, helping farmers

planting and watering.

recommendations on crop

optimize yield and reduce

management, boosting yield

costs with ease.

With its fully automated

and reducing water usage.

With its advanced machinery

Conclusion: Key Takeaways and
Future Trends
What We've Learned 🧠

Looking Ahead 🔮

We've seen how ICT, agri informatics, and

We explore the exciting future of agriculture and

IoT are transforming agriculture and natural

natural farming, from the increased use of big

farming, bringing numerous benefits and new

data to the development of new technologies and

opportunities for growth.

applications.

Use of Drones in Indian
Agriculture
Indian agriculture is facing unprecedented challenges. This section will
explore how drones can be used to address these challenges and
revolutionize the industry.

Drones: The Capabilities and
Benefits
1

3

Aerial Imagery

2

Precision Agriculture

Drones capture high-resolution images

Drones can be equipped with sensors

that allow farmers to monitor crop

for better data collection, allowing

health, growth patterns, and identify

farmers to optimize their use of

problem areas.

resources and increase yields.

Faster and Cost-Efficient

4

Safety

Drones can cover large areas quickly

Drones eliminate the need for farmers

and accurately where traditional

to navigate tough terrain or handle

methods would be slower and more

chemicals, improving safety and

expensive.

reducing accidents.

Case Studies: Successful Drone Use in Indian Agriculture

Rice Farming

Drones were used to capture real-time data
on crop health, leading to a 30% reduction in
water usage and increased yields.

Tea Plantations

Drones helped assess soil moisture, leading
to precise irrigation, which increased
productivity and better tea quality.

Cotton Farming

Drones helped identify pest infestations,
leading to reduced chemical usage, cost
savings, and higher quality yields.

Wheat Farming

Drones equipped with multispectral cameras
collected data on soil variations, resulting in
targeted fertilization and increased yields.

Regulations and Permissions for
Drone Use in Agriculture
1

Current
Regulations

2

Challenges

3

Future Outlook

Operators face

The government is

India's Ministry of Civil

bureaucratic delays and

taking steps to

Aviation has issued

prohibitive costs in

streamline regulations,

guidelines for drone

obtaining necessary

encourage innovation,

operations, requiring

permits.

and increase

users to obtain the

accessibility to drone

necessary permissions

technology.

and licenses.

Costs and ROI of Drone
Implementation
Drone Costs

ROI

Entry-level drones for

Drones can help farmers

agricultural use start at

save on resources, reduce

While drone

around INR 1.5 lakhs, with

costs, and increase yields,

implementation in

high-end models that can

resulting in an estimated

agriculture requires an

cost over INR 40 lakhs

ROI of 13% to 150%

initial investment, it is a

depending on the size and

depending on the

long-term investment and

capabilities.

application and

can drive substantial

implementation strategy.

economic growth in the

Long-term
Investment

industry.

The Future of Drone Use in Indian
Agriculture
1

Enhancing Data Analytics
Improved analytical capabilities will lead to enhanced decision-making and more efficient
use of resources.

2

Solar-Powered Drones
With advances in solar-power technology, drones will become more sustainable and
reliable for operations over longer periods.

3

Collaboration
Farmers, drone manufacturers, and software industries will need to work together to
continue improving technology and ensure successful implementation in agriculture.

Conclusion
Drones offer immense
potential for Indian
agriculture

It's a revolution

It is time for the Indian agriculture sector to

the industry. In conclusion, drones are a game

embrace the change and adopt drone

changer in Indian Agriculture!!!

technology for better productivity and ecological
benefits.

Drone technology can help address the
challenges of Indian agriculture and transform

IoT in Indian Agriculture
Discover how IoT is revolutionizing the agriculture industry in India and
helping farmers tackle the challenges they face.

Introduction to IoT

Sensors

Automation

IoT devices in agriculture use sensors to gather
data on soil moisture, temperature, weather, crop
growth, and other factors.

IoT devices can automate tasks such as irrigation,
fertilizer application, pest control, and harvesting, freeing
up farmers' time and reducing costs.

Connectivity
IoT devices can be connected to smartphones,
computers, and other devices, allowing farmers to
monitor and control their farms remotely and access
important data in real time.

Cloud Storage
IoT devices can store data on cloud platforms, providing farmers with
accurate and detailed information that can be used for future
planning and decision-making.

How IoT is Being Implemented in Indian Agriculture

Smart Irrigation

Real-Time Weather Data

IoT devices can be used to

IoT devices can provide farmers

automate irrigation systems and

with real-time weather data that

control water usage, improving

can be used to make informed

crop yields and reducing water

decisions about crop

waste.

management.

1

2

3

Soil Monitoring

Pest Control

IoT sensors are used to monitor

IoT devices can be used to detect

soil moisture levels and nutrient

and control pests, reducing the

levels, allowing farmers to make

need for harmful chemicals and

data-driven decisions about

improving crop quality.

irrigation and fertilization.

4

Benefits of Using IoT in Agriculture
1

3

Increased Efficiency

2

Better Decision Making

IoT devices can automate many

IoT devices provide farmers with

farming processes, reducing the need

detailed and accurate data that can be

for manual labor and increasing

used to make informed decisions

efficiency.

about crop management.

Cost Savings

4

Improved Sustainability

By reducing water and chemical

IoT devices can help farmers reduce

usage, automating tasks, and

water waste, harmful chemical usage,

improving crop yields, IoT can help

and other unsustainable farming

farmers save money and increase

practices, leading to a more

profits.

sustainable approach to agriculture.

Examples of Successful IoT Projects in
Indian Agriculture
Gramophone

eKutir

Fasal

Gramophone is an IoT

eKutir is an IoT platform that

Fasal is an IoT device that

platform that provides

provides farmers with access

provides farmers with data on

farmers with access to real-

to certified seeds, fertilizer,

temperature, humidity, and

time weather data, soil

and credit, as well as

soil moisture, allowing them

analysis, and crop advisory

marketing channels for their

to make data-driven

services through their

crops.

decisions about irrigation,

smartphones.

fertilization, and pest
management.

Conclusion and Future of IoT
in Indian Agriculture
Overall, IoT has the potential to revolutionize Indian agriculture by
increasing efficiency, reducing costs, and improving sustainability. As
more farmers begin to adopt these technologies, we can expect to see
even more innovative IoT projects emerge in the coming years.

Satellite Imagery
in Indian Agriculture
Discover how Satellite Imagery is revolutionizing
the agriculture industry in India and helping
farmers tackle the challenges they face.

Solution:
mobile
app based on the satellite remote sensing technology
Working
with

Providing real time information based on the satellite remote technology for which
patent is pending.

Soil nutrient report
(NPK, pH and SoC)

Fertilizer dosage
recommendation

Source: Sat2Farm’s product information

Crop health
monitoring

Pest & disease
forewarning &
Diagnosis

●
●
●
●
●

Geotagging and instant information
No hardware required
No capex required
No needs to carry samples anywhere
Recommendations on optimal:

○
○
○

Pesticide/insecticide
Fertilisers
Irrigation

Sat2Farm: with
Easy to use for farmers
Working
Farmer geotag’s his farm

Server processes the satellite image

Using walk/draw option in App

Using cutting edge technology including
AI/Ml

01

02

Farmer registers in App
Get the login credentials of app

03

Satyukt team receives satellite images
for marked area
The raw historical/present data is fetched

Source: Satyukt, Sat2Farm app

04

05

Farmer get farm related information

Results
Working with

60 %

45 %

25 %

Increase in yield

Reduction in the cost

Increase in yield

Saved the crop by
pest/diz̄ sease

By applying optimal
amount of fertilizers

Source: FAO. Personal interactions with the farmers

Through finding the
appropriate problem

Results
Working with

The farmer from the Nagarkurnool district in the state of Telangana was
able to increase his crop yield by 60%.
The farmer from the Ramnagar district in the state of Karnataka saved
the cost on fertlizer by 45% through the rapid soil testing and dosage
recommendations.
The farmer from the Bijnor district in the state of Uttar Pradesh was able
to find the appropriate problem which was the lack of nitrogen rather
than any pest or disease as contemplated by many locally. He was able
to increase the yield by 25%.
Source: FAO. Personal interactions with the farmers

Summary
andwith
way forward
Working
➢ It is possible to estimate information from satellite remote sensing for the
management of:
–
–
–

Water resources
Nutrients
Pest/diseases

➢ Currently used solutions are useful only for a fraction of farmers.

➢ It is possible to bring precision farming for every farmer.
➢ It is possible to combine modelling and observations to solve agriculture
problems.
Source: Tomer, S. K. et. al (2016)

AgTech Startups: Best Suited to Turbocharge Digital Agri in India
AgTech, a sub-sector of Agritech, focuses on developing technology to solve agriculture challenges and
improve the efficiency of farming processes.

1

Domain Expertise 🌾
AgTech startups have vast
knowledge and experience
in the agriculture domain,
which enables them to
innovate efficiently.

3

Innovation 💡

2

Up-to-date with
Technologies 🔬
AgTech startups are always
updated with the latest
technological
advancements and tailor it
to the Agriculture Industry
needs.

AgTech startups are known to create breakthrough technologies
and provide unique solutions to the challenges faced by farmers.

Conclusion
The digitization of natural farming has the potential not only to revolutionize agriculture but to

make it more sustainable and eco-friendly. The successful integration of digital tools with natural
farming methods has the potential to improve yields, increase resource efficiency, and provide
more nutritious food for the world’s population.

Grow More, Grow
Better

Up to 40% increase
in yield.

Up to 60% reduction
in pesticide usage.

Up to 50% reduction in
water usage for irrigation.

Reduction in usage of
non renewable fuel
resources.

Accurate usage of
fertilizers required.

Forbes Asia
30 under 30
Improvement in soil
health with less usage of
fertilizers.

#BigData in Agri

CHALLENGES
DATA CHALLENGES

LEARNING CHALLENGES

Spatio‐‐TemporalData

Latent Features

Sparse Data

Curse of Dimensionality

Missing Data

Multi-‐task Learning

Noisy Data

EASY! RIGHT?

unfortunately, no

DATA POTENTIAL
one season, one crop, one country
YIELD MONITOR DATA

14B OBSERVATIONS

REMOTE SENSING DATA

260B OBSERVATIONS

WEATHER DATA

20B OBSERVATIONS

FEATURE ENGINEERING
LATENT SPACE

Genetics, Environment,
Practices Soil Processes

Nutrient Processes
Crop Processes

Yield

Zea mays (corn)

LATENT FEATURE SPACE

Environment, Genetics and Practices
Engineered
Features

{

Physical Processes
Yield Outcome

}

Learned
Features

CAUSAL DESCRIPTION

THE ROLE OF DEEP

LEARNING

FEATURE LEARNING
yield

genetics, environment and practices

hidden
layers

physical
models

soil processes

genetics, environment and practices

Deep Neural
Network

nutrient processes
crop processes

yield

Hierarchical
Dimensionality
Reduction

SPATIAL DATA
CONVOLUTIONAL DBN

Hierarchical representation of spatial data
High-dimensional, scalable visible layer
Unsupervised hierarchical learning

Lee, Honglak, et al. "Convolutional deep belief networks for scalable unsupervised learning of hierarchical
representations." Proceedings of the 26th Annual International Conference on Machine Learning. ACM, 2009.

MULTI-TASK LEARNING
y

Hidden layers (latent features) shared
across tasks
Multi-task informs latent features

w

Hidden
Layers

DEEP NEURAL NETWORK

genetics, environment and practices
deep neural network in multi-task setting

Deng, Li, Geoffrey Hinton, and Brian Kingsbury. "New types of deep neural network learning for speech
recognition and related applications: An overview." Acoustics, Speech and Signal Processing (ICASSP), 2013
IEEEInternational Conference on. IEEE, 2013.

MISSING DATA
DEEP BELIEF NETWORK

Greedy layer-wise training algorithm
Robust to noisy inputs
Generative process (MRF)
Alternating Gibbs sampling in deep belief
network

Hinton, Geoffrey E., Simon Osindero, and Yee-Whye Teh. "A fast learning algorithm for deep belief nets."
Neural computation 18.7 (2006): 1527-1554.

OTHER APPLICATIONS
Crop identification

Practice classifications

Disease detection

Remote sensing

Image segmentation /
clustering

Nutrient deficiency
detection

Cloud detection

Environment classification

additional applications of deep-learning in agriculture

POSSIBILITIES

PROTECT & IMPROVE
REDUCE RISK

INCREASE YIELDS

Goal: optimize global food production

PROTECT & IMPROVE
The Climate Corporation aims to help farmers around the world
protect and improve their farming operations & profitability.

TWI

Yield Potential

TotalWeatherInsurance:parametric
supplemental crop insurance product

Yield Expectation
TWI

PROTECT

Government subsidized loss-adjusted
insurance program, integrated risk
management

Profitability
GROWER APPLICATIONS

MP

MP

GROWER APPLICATIONS
Collection of grower management advisors
using agronomic and climatological models

IMPROVE

Challenges with AI/Digital
● Clean Data Sets
●

Lack of data sets – example – pest on leaves

●

Diverse data sets between public, private and govt
departments

●

Lack of normalized data sets

● Each state has different language and
units, which makes it harder for data
normalization.
● Acceptability & adoption
●

Who will pay for this, given so many small Farmers

●

Interoperable standards needed in Agristack being developed by various players

Big Data: Milieu
•
•
•
•
•
•
•
•
•
•
•

Analytics
Informatics
Evidence-Based Tools
Meta-Analysis and Synthesis
Complex Systems
Computational Sciences
Data Engineering
Data Mining
Cloud Computing
Implementation and Evaluation
Data Security and Cybersecurity

•
•
•
•
•
•
•
•
•
•
•

Predictive Modeling
Data Visualization
Decision Analytics
Embedded Systems
Machine Learning
Multidimensional Data
Network Science
Sensor Networks
Spatial Analytics
Bandwidth
Cyberphysical Systems

Big Data: Opportunities
Open Data is a powerful,
evidence-‐based tool for long-‐
term sustainable development
by improving economic
opportunities for farmers and
health of consumers.
Open access to research, meta-‐
analysis, and open publication
of data are vital resources for
nutritional security.

Big Data: Challenges
• Ownership
– Open Ag Technology Systems

•
•
•
•
•
•
•
•
•

Decision Support Tools
Cost
Bandwith
Quality
Curation
Disambiguation
Connectivity
Cybersecurity
Storage

We are drowning in information, while starving for
wisdom. The world henceforth will be run by
synthesizers, people able to put together the right
information at the right time, think critically about
it, and make important choices wisely.
E. O. Wilson, Entomologist, Author, Pulitzer Prize Winner
ASSIGNMENT – A five page note on
Wilson’s seminal contribution in
creating a global database

Big Data in sustainable agriculture
• Big Data can support resilient agri-food systems under uncertain
climate variability and change.
• Big Data has a huge potential in the dry areas where resource use
efficiency is below its actual potential
• But they can only deliver if applied to Inclusive Farming Systems

+

+
Better integration

Better measurements

Better modelling

Resilient Systems

Thank you