Category Archives: Precision Agriculture

Automation, LandWISE 2015, Precision Agriculture, Sensing

Grape Vine Pruning Robot

LandWISE 2015 Presenter Tom Botterill

Tom Botterill
Tom Botterill, Research Fellow, Department of Computer Science, University of Canterbury.

Tom described advances in developing a viable grape vine pruning robot.  This work is through the MSI-funded project on “Vision Based Automated Pruning”.  Tom’s research interests include 3D reconstruction and modelling using computer vision.

Grape vines must be pruned every year in order to increase yield, prevent disease, and control excess growth. While some simple mechanical pruning systems are available, most of New Zealand’s winegrowers prefer to prune vines manually, even though hand-pruning is often the most expensive task in the vineyard.

To hand-prune a vine, the healthiest canes are selected and the rest are removed. For a robot to prune vines in this way, it must understand the 3D structure of the plant, it must be able to decide which canes to keep or remove, and it must be able to make the required cuts without damaging other canes.

Cane pruning a vine requires detailed recognition and selection
Cane pruning a vine requires detailed recognition and selection

A team at the University of Canterbury are developing just such a robot system. The system is mounted on a platform which straddles the vines and moves along the row, pruning as it goes. The robot uses three high resolution digital cameras to image the vines, then uses computer vision algorithms to make a 3D model of the vine from these images.

Given these vine models, an artificial intelligence system decides which canes to keep and which to cut. The artificial intelligence was “trained” to make good pruning decisions by providing it with examples of how pruning experts prune vines. To prune the vines, a six-jointed robot arm reaches amongst the canes and makes the required cuts with a spinning cutting tool.

The major technical challenges in the current system were building a 3D model of the complex vine structure, then reaching to cut the vines while the platform moves. After four years of development, the 3D models are finally complete and correct enough to make decisions about where to prune, however the dynamic robot arm control is still under development, so the robot must stop at each plant to make the cuts.

Our system has been made possible by rapid advances in computer vision and robot technology over the last decade, and it is close-to-working despite being far from the simplest way to automate pruning. The algorithms and techonology are now available to automate many harvesting, pruning and precision-agriculture tasks, and there are now no technical barriers to seeing all of these tasks automated out in the field.

This project is funded by MBIE and is a partnership between the University of Canterbury, NZ Winegrowers, Pernot Ricard NZ, Scott Technology, Lincoln University and the University of Otago.

Tom’s publications and more information: http://hilandtom.com/tombotterill/

Agronomy, Automation, LandWISE 2015, Precision Agriculture, Soil, Tillage

Tulloch Farm Machines

GoldTulloch Farm Machines will demonstrate their  Oekosem Rotor Strip-Tiller and Monosem NG Plus 4 planter combination at “The Farm of 2030” LandWISE Conference. 

Oekosem Rotor Strip-Tiller and Monosem Planter
Oekosem Rotor Strip-Tiller and Monosem Planter

The Oekosem Strip Tiller is a  Swiss product manufactured by Baertschi. Nick Gillot says it’s all about creating an optimal seedbed in rows, minimizing soil erosion and operating costs and simultaneously securing earnings over the long term.

Nick says the metering unit is a major component of the Monosem planter. With the new NG Plus 4 model, Monosem has conserved the the best of the NG Plus units and has added the operating comfort. Nick says adjustments are made easier so the planter can be perfectly adjusted to conditions to get optimal planting.

The machine was operating at the LandWISE MicroFarm Field Session on Day 2 of the Conference. The area put aside for the demonstration was in long term grass that had not been sprayed out – it was a good test.

More about “The Farm of 2030” Conference here>

Thanks to our Platinum Sponsors

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Agronomy, Automation, Drainage, Irrigation, LandWISE 2015, LandWISE People, MicroFarm, Nutrients, Precision Agriculture, Projects, Sensing, Soil

More adequate or less better sensor arrays and wireless networks

LandWISE 2015 Presenter – Gert HattinghInstalling the WINTEC wireless soil moisture sensor array
Installing the WINTEC wireless soil moisture sensor array

Gert Hattingh is Industry Research Champion at the Waikato Institute of Technology in Hamilton.

Gert’s current work involves finding ways to build more sustainable and energy efficient homes, finding better ways for the normal household to live sustainably, and evaluating new technologies.

Gert says the most burning question in any business venture is whether your actions will cost you money, or make you money.  Any decision you make in the production, marketing or operational sphere has an influence on this statement.  This paradigm has been a design key since Wintec have ventured into producing cost effective sensor arrays and wireless networks.

In the modern measurement world, there are three cost drivers – quality of the sensor(s), the cost of the network carrying the data, and the cost of making sense of and using the data.

Gert and colleagues started off by looking at the network and the data carrier first, and designed a generic sensor module to host and manage almost any sensor type.  They also developed a database model that would host any data from sensors, as well as the encryption and data quality protocols.

To date, their system can host the following type of sensors:  GPS, Air Humidity, Air Temperature (2 sensors), Air pressure, solar irradiation, wind speed, wind direction, soil moisture (various sensors), pH, conductivity, dissolved oxygen, oxidation-reduction potential, ammonia, CO2, methane, propane, NOX and some alcohols.

A single sensor module can carry at most thirteen sensors, with a practical thirty sensor modules per network.  This totals to 390 sensors per network.

This technology is being trialed at the LandWISE MicroFarm, gathering, transmitting and processing soil moisture information from an array of sensors.

Agronomy, LandWISE People, Precision Agriculture, Soil

Planting Precisely – John Chapman

LandWISE 2015 Presenter, John Chapman

JohnChapmanJohn Chapman is the Product Specialist for seeding and cultivation equipment at Power Farming.

John spent 15 years managing farms in Suffolk and Norfolk in the UK after graduating with an MSc in Farm Management.

His  experience with rotations involving many different crops involved many cultivation techniques, as well as a wide range of cultivators and drills to achieve quality seed beds and successful crop establishment in all sorts of conditions and soil types.

Success from precision planting does not come from one or two well made decisions but from a whole host of factors that come together to produce a successful crop.

It is critical to check all areas where the seed drops from to the point where it hits the ground that there are no points at which the seed may catch or have its trajectory affected.

Ensure that seed plates are clean and free from any grooving that has occurred. Badly grooved seed plates have the potential to be distorted and loose vacuum.  The seed needs to be of the optimum quality to singulate well. Even size and condition is essential.  Seed size directly relates to the seed plate chosen.

Forward speed is where in most cases the wheels fall off the wagon. Forward speed has a direct correlation to spacing through the planter’s ability to cope with the speed.

Although drilling depth is of vital importance for even seed germination and emergence it will be affected by the soil conditions, forward speed, varying conditions across the paddock and the state of the coulters.

Agronomy, Automation, LandWISE People, Precision Agriculture, Sensing

Robotic vision systems for real-time crop management

LandWISE 2015 Presenter – Cheryl McCarthy

Cheryl-McCarthyCheryl McCarthy is a researcher at the National Centre for Engineering in Agriculture, University of Southern Queensland based in Toowoomba.

As inputs costs continue to rise, on-farm productivity gains will come from greater sophistication in managing inputs like labour, water, chemicals and energy. Robotics is enabling the development of farming equipment and systems that can precisely sense and control to manage inputs and save labour.

NCEA is conducting a range of research projects that integrate autonomous sensing and control with on-farm operations, to robotically manage inputs within a crop. Major projects are being conducted in on-farm automation for weed spot spraying, adaptive control for irrigation optimisation, and remote crop surveillance using cameras and remotely piloted aircraft.

Cheryl is developing machine vision and sensing systems for agriculture. Machine vision-based weed detection systems have been developed for the sugar, cotton and pyrethrum industries. A Depth and Colour Segmentation process enables weed detection and a new processing technique enables the vision systems to operate at commercial ground speeds of 10-15 km/h.

Optimal irrigation strategies for overhead and surface irrigation systems are being investigated in projects for the cotton and horticultural industries. Trials in the cotton industry at sites on the Darling Downs and Central Queensland have demonstrated 10-30% water savings with 10% increase in yield, as well as labour savings, when using adaptive and automated irrigation systems which combine soil and crop monitoring sensors and variable rate applicators, together with software to calculate optimal irrigation amount.

Insufficient sampling for diseases or pests in crops and pastures can lead to misdiagnosis of the presence or level of infestation in a field, or uniform application of pesticide in a field where infestation is not distributed uniformly. Similarly, field conditions, including crop growth, water stress and weed coverage, vary spatially and require frequent monitoring to optimise management.

NCEA is developing technology that will couple rapid, field-scale data collection from RPAS with automated data and image analysis to automatically diagnose unhealthy areas of crop (see below).

3D model of cotton crop generated by RPAS and photogrammetry software
3D model of cotton crop generated by RPAS and photogrammetry software
Agronomy, Automation, MicroFarm, Precision Agriculture, Sensing, Soil

Aerial Mapping at the MicroFarm

Centre for Land and Water residents, AltusUAS are creating detailed farm and crop maps of the LandWISE MicroFarm.

Altus Unmanned Aerial Solutions specialises in the manufacture of professional UAS systems for wide-ranging applications. They build and operate systems of high specification with features including built in redundancy, custom control interfaces and integrated emergency parachute. They offer platforms with class leading flight performance as well as all-weather capabilities.

AltusMissionNDVI
An AltusUAS Quadcopter sets off on a mission to map the MicroFarm

Even a simple aerial image is highly informative – the view from above changes perception immensely!

MicroFarm fields and Green Shed meeting venue - image captured by AltusUAS
MicroFarm fields and Green Shed meeting venue – image captured by AltusUAS

At the MicroFarm, they are using their technologies to survey the site, photogrammetry to process imagery and further analysis to create a 3D model of the MicroFarm and crops.

A composite image created from many overlapped photographs taken from a GPS guided UAV - the basis for a 3D MicroFarm model
A composite image created from many overlapped photographs taken from a GPS guided UAV – the basis for a 3D MicroFarm model
A zoom-in on part of the image showing the Green Shed and corner of a crop of mustard
A zoom-in on part of the image showing the Green Shed and corner of a crop of mustard

 

View a flythough of the model (it looks like a video of the site) on YouTube here>

AltusMicroFarmVideoImage

As well as terrain models/topographic maps, they can produce detailed NDVI information.

We are using this information to understand our site in much more detail. With individual pixels as small as about 4cm, we can zoom in practically to individual leaf scale. Do we need that? Not for many applications, but it does raise new possibilities around pest and disease identification and definitely enable us to view individual plants.

To receive updates sign-up for the LandWISE E-newsletter and follow @LandWISENZ on Twitter (see the right sidebar).

Precision Agriculture

PAANZ Update

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LandWISE is a foundation member of the Precision Agriculture Association of New Zealand – PAANZ. Our Manager, Dan Bloomer, is a member of the PAANZ Committee which is working to build the organisation.

Dan says PAANZ has established itself, and is now developing resources to help farmers, industry, regulators and the community understand how precision agriculture can play roles increasing productivity while minimising resource use and environmental foot prints.

PAANZ has a wider coverage than the traditional LandWISE focus on cropping, viticulture and horticulture. As a pan-sector body, it aims to link industry and users across the spectrum, and to take a lead on generic issues.

The PAANZ website has a number of useful resources including case studies and news page. See more at http://www.precisionagriculture.org.nz/

PAANZ2

Agronomy, Automation, Irrigation, LandWISE People, MicroFarm, Nutrients, Precision Agriculture, Projects, Sensing, Soil, Tillage, Water

The Farm of 2030

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The 2015 LandWISE Annual Conference attracted record numbers. It’s theme looked forward 15 years to contemplate what a farm might look like in 2030.

We are most grateful for the strong support of our many sponsors, a vital feature for bringing such events to the community.Sponsor_Sheet_600

 

You can see the full programme here>

RobertFitch2 TristanPerez1 Cheryl-McCarthy

Three speakers, Robert Fitch, Tristan Perez and Cheryl McCarthy, travelled from Australia to help lead discussions.

Tom Botterill PeterSchaare Ian Yule

Add Tom Botterill, Peter Schaare and Ian Yule

GertHattingh John Ahearn JohnChapman

Gert Hattingh, John Ahearn and John Chapman

BruceSearle200 FinlaysonChristina_200x200 geoff-low-res-e1423206134526

Bruce Searle, Christine Finlayson and Geoff Bates plus others from New Zealand and see the wealth of knowledge and experience available.

You can see all speakers and their biographies here>

On Day 1, presenters discussed sensing, control and robotics. Developments in this area are proceeding remarkably fast, with prototype machines finding their own way around farms, identifying weeds by species and applying custom treatments including sprays only to leaves. Additional presentations on pasture and plant quality detection, grapevine pruning and fruit quality analysis made it a full informative day.

At the end of the day, delegates formed small teams to design their dream agricultural robots – an excellent way to consolidate information. The key however, was identifying what their robots should do (not how) and describing the constraints under which it would need to operate.

As soon as you state a “how” you limit the options that can be considered in determining the final design. Maybe it shouldn’t be a 4-wheeled rover, but an aerial vehicle, or even a ground crawler. Get the specifications right, and the design will identify itself.

AgBot - image from Queensland University of Technology
AgBot – image from Queensland University of Technology

Day 2 began with discussions around variability. Identifying what variability exists, where it is and whether it justifies custom management is a critical starting place. Speakers also focused on managing two important farm  inputs to ensure the right job is done – seed placement and fertiliser application.

Day 2 was completed at the LandWISE MicroFarm at the Centre for Land and Water. There were demonstrations of in-field nitrogen testing, a soil pit to examine, a robot pulling a urine patch detector, a one pass strip-till and planting machine, testing fertiliser spreaders and UAVs.

AltusMissionNDVI
An AltusUAS UAV takes off at the Centre for Land and Water, a mission to collect data at the LandWISE MicroFarm

Something for every forward thinking agriculturist!

More on-line here>

 

Agronomy, Automation, LandWISE People, Precision Agriculture, Tillage

AndWeeder

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Long-time LandWISE member, Andy Lysaght is featuring on Rural Delivery with his mechanical weeder for squash and other crops.

Andy Lysaght

Agricultural contractor Andy Lysaght has invented a machine to weed squash and similar crops mechanically.  Client Gareth Holder, who was paying significant amounts of money for hand weeding of his squash crops, encouraged him to design something mechanical.  About a week later Andy came back to Gareth, and said: “Come and play with this.”

 

Andy has won two major national awards with his Andweeder; the Ravensdown Innovation Award at the National Horticultural Field Day in Hastings, and the Launch NZ Innovation Award at National Fieldays.

Judges said the Andweeder is a step change for the industry, converting an intensive manual process to an automated precision one.

Andweeder (C)
Andweeder Image (C) Plant Detection Systems

A comparative 10ha weeding trial between the Andweeder and human weeders saw the three-row machine take 6 hours 45 minutes, compared with 125 hours by hand.

Andy says: “We are doing our best to get away from chemicals.  We can’t keep doing what we are doing and the rest of the world doesn’t want it either.”

To see Andy on TV, watch Rural Delivery Series 11, Episode 4 on 28 March 2015. First screening, Rural Delivery on TV One, Saturday at 7.00am.  Repeats on TV One Sunday at 6.00am and Heartland channel Sunday at 6:30pm, Monday at 12.30am, 12.30pm and 6.30pm

Automation, Precision Agriculture, Sensing

Design-a-Bot Workshop

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New at LandWISE Conference 2015 was a special session where small groups have a chance to specify their “dream farm robot”.

Mammoth Robot - a reconfigurable robot for row crop monitoring (University of Sydney image)
Mammoth Robot – a reconfigurable robot for row crop monitoring (University of Sydney image)

The point of the Design-a-Bot workshop session was to fully explore things farmers would like automation to assist and where they perceive value will be created. Along with that, it was a great way to ensure our understanding of the sensing, automation and associated technologies was on-track. 

A number of world leading researchers in these fields were presenters at “The Farm of 2030” and others attended as delegates.  They will circulated around the design teams, listening, learning and offering their combined wisdom.

The key was not knowing how to make it work. Specification means knowing what you want it to do and the constraints under which it must operate. Starting to think about how before you know exactly what can severely restrict the creative thinking that ultimately identifies the optimal designs to achieve your dreams.