“If you eat, you’re in agriculture.”
That old adage is more true today than ever before. It’s expected that by 2050 our world population will approach 10 billion. That’s double what it was only thirty years ago in 1987. Increased land, water, and resource use for the growing population competes directly with farming needs to feed that population. It’s fortunate that digitization is helping to connect agricultural concerns around the world. But what will the future of farming look like?
How will digitalization effectively transform agriculture?
Though robotic farming may seem far-fetched, it’s here today. Much like yesteryear’s use of satellites for precision agriculture, the additional data provided through the Internet of Things (IoT) allows us to grow more food with fewer resources on less land. With analytics, a farmer in Kenya uses a drone to release beneficial insects in a problem patch. A Kansas wheat farmer helps keep the water table pure by only fertilizing areas in need. Yields are boosted without waste through very specific irrigation management. Total corn production savings can reach 4.5% with yield mapping, 2.4% with GPS soil mapping and 2.7% with guidance systems. Here are some recent innovations we’ve helped bring to life.
What does palm oil’s future look like?
Planting a palm oil plantation requires strong long-term planning. But what does the future hold for this important crop? As palm oil’s popularity has grown, so have the industries it services. Biofuels, cosmetics, and other industries are all impacted by palm oil production in addition to its traditional uses in food. Fortunately, there’s a strong push to improve sustainability in the palm oil industry.
Most palm oil production in the past has been based on overall yields. But tomorrow’s plantation can determine production by every plant. IoT technology allows tracking the exact growing conditions of the palm tree. This means its exact needs are met to maximize yield and minimize waste. But how does this happen?
Aerial photos play a vital role in this process. Drones, planes, and satellites provide imagery to help producers make smart decisions in oil palm plantation management. Sensors provide climate, soil condition, and other data. This collection of data and strong analytics options let the producer manage stressed areas while boosting production in other parts of the plantation.
This process is being moved forward through collaboration across multiple sectors. Research, genetics, machinery, inputs, and the farmer all work hand-in-hand to provide more palm oil with less waste and a more sustainable environmental impact.
The future is sweet with sugarcane production
Though it’s still one of the world’s top sweeteners, sugarcane has also branched out recently into the biofuel and electrical production sectors. A single ton of sugarcane produces 120 kilograms of sugar, 85 liters of ethanol and 25 kilowatt-hours of electricity. But the tropical origins of the plant means it’s always been planted in developing countries with plenty of land and labor. That made it a cheap crop to grow.
Today’s population growth is limiting sugarcane production. This means more care must be taken in crop techniques and inputs to provide maximum results on minimal land. To complicate matters even further, the land it is raised on is often very different. This requires different approaches to achieve these results.
Different climates require the use of different techniques and methods. Ratoon planting allows the crop to be grown from the prior year’s plant stubble. But the number of years can vary greatly. Production-leading Brazil replants new cane every 5 or 6 years. As second-highest producer, India’s climate demands planting new cane every two or three years.
Hand harvesting uses manpower and a sharp hand-tool while providing 500 kg per hour, with rising labor rates making this practice less profitable than in the past. Mechanizing the process allows manual labor to be focused in different area as a single harvester will handle 100 tons of sugarcane per hour. Except for on steep slopes, mechanical harvesting provides a more ecologically sound approach. Satellite-based tractor navigation uses permanent wheel tracks to maximize production while minimizing wasted time and fuel.
Combining sustainable farming practices with economical technological advancement allows us to grow as a people and as a planet. Smarter crop rotation, precision pesticide and fertilizer application, yield mapping and weed sensors are only a few of the advancements farmers will see in the years to come. IoT technology is expected to see a 20% annual compounded growth from 2015 to 2020. New agricultural business models are expected to see a 15%–25% growth in revenue above the industry average.
Farms that add IoT capabilities, Big Data analytics, and similar connected agriculture tools are making strong strides. Imagine yields 10%–20% higher than in the past. They’re also seeing an average increase in profits of 18%. Some farms have seen profit increases of up to 76%.
Learn how to bring new technologies and services together to power digital transformation by downloading The IoT Imperative for Consumer Industries. Explore how to bring Industry 4.0 insights into your business today by reading Industry 4.0: What’s Next?