Category Archives: Irrigation

LandWISE NEWS June 2012

Conference 2012

The 10th Annual Conference was our biggest gathering with over 160 attendees. We extend our thanks to the speakers, sponsors, trade supporters and delegates that made the event such a success. There were some important issues up for discussion by excellent speakers and we have received very positive feedback.

2012 saw our first Focus on Viticulture, an extra day dedicated to wine growing technologies. Keynote Rob Bramley started the conference and was well supported by the remaining speakers. Rob and Tim Neale both made a number of presentations over the three days, and we are very grateful for their high quality inputs.

The second day investigated implications of the National Policy Statement for Fresh Water Management. Thanks to Land and Water Forum Chair Alistair Bisley, HBRC CE Andrew Newman, LandWISE Chair Hugh Ritchie and the others who presented clear outlines of the concepts, process and possible future.

The field event at Hugh Ritchie’s farm was also extremely well received and we thank Hugh and the other presenters for their work setting everything up – a significant undertaking. The Anderson Road block was transformed into a precision farmer’s perfect sandpit for the day.

Live demonstrations of Trimble surface levelling and Keith Nicole’s GPS tile laying were of much interest. These drainage options were supported by Precision Irrigation’s variable rate irrigation fitted to the towable pivot on-site. and Hydro-Services showing soil moisture monitoring options including neutron probes and electronic sensors and telemetry from WaterForce.

New Board Members

Long term Board members, David Clark and Chris Butler, retired this year.

We have two new Board members, both from Pukekohe. Paul Munro from Peracto and Brent Wilcox from AS Wilcox were elected at the AGM.

LandWISE News March 2012

LandWISE 2012 – 10th Annual Conference May 2012

Put the 22, 23 and 24 May 2012 in your diary for the 10th Annual LandWISE Conference.

The title is Site Specific Management: growing within limits. We are looking at the changing requirements for farming, in particular the increasing need to demonstrate that farming has minimal environmental impact. Look for a focus on soil water management, irrigation, monitoring and drainage.

For the first time we also have a day focused on Smart Viticulture. This builds on current LandWISE work with local viticulturists investigating the benefits, costs and logistics of applying zonal management using precsion viticulture techniques.

  • People with viticulture interests will find Day 1 extremely useful. They will also see there are great presentations on the other days.
  • LandWISE traditionalists be assured; Days 2 and 3 follow the usual pattern. But do have a look at the Day 1 programme – you’ll find a lot there that can give you completely new ideas.

The draft programme and more details are available here http://www.landwise.org.nz/events/landwise2012/. This page will be updated as conference draws nearer, and you’ll receive direct messages too.

Conference registration is available on-line. As usual, discounted rates for members.

Conference Platinum Sponsor

We are very pleased to announce Eastern Institute of Technology as a new Platinum Sponsor for Conference 2012. There are strong cross-overs between an institute such as this and LandWISE with our focus on upskilling for the primary industry sectors.

EIT has a very strong viticulture and wine programme, and is also active in agriculture and horticulture in Hawke’s Bay and the East Coast/Tairawhiti.

Key Speakers

We are also delighted that Rob Bramley from CSIRO in Adelaide will be one of our key presenters. Rob is well known for his precision viticulture work, but is also very experienced in broadacre crops.

Tom Botterill from the Geospatial Research Centre at the University of Canterbury will talk about machine vision and robot pruning. More announcements coming soon . . .

 

Driverless Tractor

LandWISE Member Matt Flowerday from GPS-It sent a link to this site for a new driverless tractor.

A few of you have expressed interest in autonomous tractors – so with a favourable exchange rate and a $US 150,000 price tag, here’s your chance.

It’s interesting for a few reasons:

  • The 225 kW tractor can be controlled in real-time from a base station with a remote control device that can be up to 40 km away. The master base station can handle up to 16 operating tractors at one time.
  • Hew can couple units together for more power, like train locomotives
  • It uses twin laser unit called LIPS (Laser Imaging Position System) rather than GPS (we need to learn more about LIPS)
  • Power is diesel electric with a 15 to 25% better fuel economy than conventional systems

Australian Conferences

Dan attended the SPAA Precision Agriculture Australia Expo in Port Lincoln, South Australia and the precisionagriculture.com.au Conference in Maroochydor, Queensland in February.
Speakers discussed nutrient tests we don’t use, plants we seldom grow, pests, diseases and weeds that remain thankfully foreign, and yields most New Zealand farmers would consider disastrous. They talked of soil electromagnetic sensors, pH sensors, biomass sensors, protein sensors, animal trackers and robots. Of precision farming in Canada, Scotland, England, New Zealand, Queensland, New South Wales, Victoria and South Australia.

The messages were strikingly familiar. In essence; know and look after your soil, monitor your crop, and apply inputs where they give the best returns.
At both events, the farm was the focus; the technologies merely tools to help manage better. Much, much better.

A couple of areas to watch:

  • UAV proliferation. There are more and more self-flying ‘toy’ planes and helicopters suited to crop inspection tasks. With increasingly light and quality cameras, and return to base GPS guidance they have great potential. There are a few issues yet with processing the data, and like all sensor things, ground trothing is still needed.
  • RFID Tags. The advances in electronic tagging have been very fast, and new applications are only now being realised. With new technologies, the range of some devices has become quite extraordinary, offering ability to track items or animals at increasing distances. Cheaply.

A Guide to Smart Farming

Our Guide to Smart Farming book has been the subject of tremendous acclaim from farmers, industry, researchers and teaching staff in New Zealand and overseas. Thanks for the feedback!

About 7,000 copies were printed, and we’ve only 300 left in stock, so that’s a lot that are out there and, from what we hear, being read.

Purchasing copies:

A Guide to Smart Farming was distributed free to people in the LandWISE Community. Extra copies are available through TradeMe at $29.90 plus post including GST. Search TradeMe guide smart farming and it will pop up.

See the Table of Contents here>

Smart Farming the Game to be in

This article first appeared in The GROWER magazine in December 2011

Dan Bloomer, LandWISE

A Guide to Smart Farming

“New Zealand has a unique ability to supply quality produce to a rapidly increasing global market,” says Hew Dalrymple. “But to do so sustainably requires new approaches to farming and new skills for those on the land.”

A book published in December contains a wealth of information that will help. A Guide to Smart Farming has case studies of farmers using new technologies, and expert articles explaining how the technologies work.

The book encapsulates learning which is the result of many years’ collaboration, especially between LandWISE, the Foundation for Arable Research, Horticulture New Zealand, and Plant & Food Research. At its core are Sustainable Farming fund projects, Advanced Cropping Systems and Holding it Together.

View the Table of Contents here>

Advanced Cropping Systems

Advanced Cropping Systems followed twelve farmers assessing precision farming technology. Perhaps not surprisingly, the focus for some shifted in the three years of the project.

FAR’s Tracey Wylie worked with Tim Macfarlane mapping weed infestations with a canopy sensor. Their weed map did not correlate very well with the weed problem, but a soil map did.  As Tracey and Tim say, “We need to take all the information we have into account, we can’t assume a single tool will tell us what we want to know.”

Travis and Nigel Sue fitted RTK-GPS and autosteer for their fresh vegetable operation. Now the rows are dead straight and perfectly spaced every time. They have labour and input savings, and no land is wasted. “We should have had it years ago,” they say.

A half-paddock trial of permanent beds for onions, potatoes and cereals at A.S Wilcox and Sons controlled traffic on the paddock and saved soil, oil and toil. Already expanded to 40ha, they are now focused on rolling the new system out across the business.

Hugh Ritchie wants easy data transfer between GPS devices and computer programmes to avoid double and triple data entry, avoid errors, and increase efficiency. Unfortunately a solution does not look imminent! Sjaak Wolfert is leading a major EU project on this topic. “This is a global problem. There is no single standard for data exchange in agriculture, and manufacturers are slow to use those that are available,” Sjaak says.

In partnership with Keith Nicoll, Hugh has made major advances with precision drainage installing plastic pipe with a gravel envelope. The equipment maps the paddock using RTK-GPS, calculates the drain gradients, and controls the laying machinery automatically, removing costs from the operation.

Holding it Together

Holding it Together focused on retaining soil and soil quality. Plant & Food scientist Paul Johnstone led the Fresh Vegetable Product Group, Potatoes New Zealand, LandWISE project. “There are many practical things we can do to look after this key resource,” he says.

Scott Lawson is one of several crop farmers using furrow dyking in their wheel tracks. “It is normal practice for us now,” he says. “We were getting crop loss after rain or irrigation when water ran along wheel tracks and drowned out crop. The furrow dyker keeps the water where it lands while it soaks in.”

Antonia Glaria worked with Paul on a range of cover crop options for fresh vegetable growers. They found maize could recapture lost nutrients including nitrogen. “We’ve studied maize in a number of situations,” says Paul. “It is a very deep rooted crop, and a great scavenger of nutrients. In some cases, all the nutrients needed can be obtained from deep in the soil – nutrients that would otherwise leach and cause problems down the track.”

A Guide to Smart Farming is a great publication,” says Hew Dalrymple. “Every cropping farmer should get a copy and read it. It will help them maximise opportunities and make sure our land and water is in the best condition for the next generation.”

Orders

Copies of the book A Guide to Smart Farming are available from LandWISE for $NZ 29-95 plus postage: Click here or contact us via info@landwise.org.nz

New Zealand and Australian residents can order copies and pay on-line by credit card via TradeMe. Search for Guide to Smart Farming

Feedback

Please feel free to post feedback – does the book give good information? What could be added or updated?

 

LandWISE 2011 Conference on farmer’s successes with technology

As published in Grower June 2011

Dan Bloomer and James Powrie – LandWISE Inc.

“Agriculture is the business to be in,” Hew Dalrymple told 115 delegates at the 9th LandWISE conference in Havelock North. Hew painted an exciting picture of high global demand for food and outlined some of the technologies he is adopting to be a better producer.

Chinese food consumption growth and diminishing area of agricultural land (8.33 million ha lost in the last 12 years) are just two drivers he presented.  Hew quoted David Stroud, chief executive officer of New York-based hedge fund TS Capital Partners: “China’s increased demand for agricultural commodities will mean an increase in prices for the entire world market. China can outlast any other bidders for the commodities it desires.”

One example: China, the world’s biggest grain producer, was a net exporter of soybeans until 1995.  This year, it’s forecast to import 57 million tons, or almost 60 percent of global trade in the oilseed used in animal-feed and tofu. Hew says this is setting the scene for NZ farmers to gain from exports.

Four AGMARDT sponsored experts from Australia addressed the conference. Professor David Lamb showed Precision Ag has moved steadily forward in Australia. He spoke on precision pastures and livestock, and the ways researchers are interpreting tracked animal behaviour to better manage farm systems.

David also described recent work with plane mounted crop sensors, capturing crop information from 150 feet, and how smart engineering is trying to use on board sensors to adjust aerial application rates in real time.

“Just because you can, doesn’t mean you should!” Steven Raine, Professor of Irrigation from Southern Queensland, opened the irrigation and drainage session with a review of precision irrigation. He pointed out that you can precisely apply irrigation to a whole paddock as one block. He challenged farmers to look at real returns from investment, rather than adding to a stable of toys.

Steven showed how really smart irrigation systems not only manage application, but measure, monitor and determine needs automatically with little input from farmers. This needs a high level of knowledge of soils, weather and crops, computer modelling and process controls. But your system must be working correctly in the first place, before expensive smart technologies will add value.

The how-to of successful Precision Agriculture was covered by Tim Neale and Andrew Whitlock from Australia.  They covered farm software, precision drainage design and controlled traffic farming with Australian examples and comments on NZ practices as they had seen in their travels prior to conference.  They were impressed by the New Zealand farmers they met. “We don’t know anyone in the world who has gone as far as you, with precision ag in potatoes and onions,” they told AS Wilcox delegates.

Simon Wilcox spoke about their experience starting with the LandWISE Controlled Traffic trial at Pukekawa.  GPS guidance has given them savings from the paddock to logistics, and in the processing plant, with better structured soil staying in the paddock instead of riding in the truck to the factory. “The washing plant loves it,” said Simon.

Emma McCracken described how she and husband Peter have paced their investment in technology at Wai-Iti Fresh in Canterbury.  They are new adopters, with RTK-GPS, new irrigation types and other technology being adopted in the past two years.  Emma described their plans to build on this base, and use such tools to address their challenges with soil quality, water use, drainage and crop yield.

Sjaak Wolfert leads a European Union research program to enhance the use of on farm data. Based at Wageningen in Holland, he described the challenges of data compatibility between brands.  The same difficulties we find in New Zealand are faced globally by farmers. Sjaak invited aligned efforts and assistance from LandWISE in spelling out farmers’ requirements of the technology industry.

Massey University has formed a joint Centre for Precision Agriculture with Lincoln University. Professor Ian Yule outlined where this fits with the advancement of Precision Agriculture in New Zealand. He spoke about paths to managing your farm at the highest practical resolution. Using sensors and fertiliser as examples, he explained the goals and difficulties of managing variability in time and space as crops develop.

Plant and Food research Scientists Bruce Searle and Steven Trolove brought zonal management of nutrients into perspective, relating soil measurements to crop wants, and translating complex nutrient mapping into farmer application decisions.

It was exciting to see how success with technology is becoming the norm across a range of sectors and to hear farmer’s plans for more.

And it’s not just for the big farms. Brothers Travis and Nigel, and father Gordon Sue, grow fresh vegetables on 70 ha of land in Levin. Travis explained the successes his family has had with auto-steer precision; cutting costs and making better use of their land.  He explained how they plan to make their site more productive by managing traffic better. “We should have had it [RTK-GPS] years ago,” says Gordon.

The conference was generously supported with the platinum sponsor being CASE IH NZ Ltd.  AGMARDT provided funding for Professors Steven Raine and David Lamb and Andrew Whitlock and Tim Neale to present at the conference also. For more detail on the conference and coming LandWISE events visit our website www.landwise.org.nz

Improving profits by reducing surface ponding

Ponding of surface runoff from rainfall and irrigation can reduce crop production. The ‘Holding it together’ project addresses this.

Plant & Food Research and LandWISE are working with growers on ways to reduce surface ponding, improve soil quality and increase returns.

MAF Sustainable Farming Fund, Fresh Vegetable Product Group, Potatoes NZ, Hawke’s Bay Regional Council, Horizons Regional Council, Auckland Regional Council, Environment Waikato and Ballance Agri-Nutrients have funded the project.

Runoff occurs when water infiltration is slower than application of rain or irrigation. In some soils, slow infiltration is due to texture, in others it is reduced by frequent tillage or compaction. Whatever the cause, runoff can pond for extended periods, in low-lying dips or field edges. This ponding can be damaging to crops.

Trials with onions have shown that even temporary ponding can reduce yields. Yield loss ranged from 60-80%.  Ponding also reduced the proportion of yield within the most profitable size range.

In one field, a leaky pipe resulted in ponding during irrigation. This area of 0.2 ha cost the grower $1,700 in lost income. The cost of fixing the pipe was $10.

A  similar-sized area was affected by ponding during spring rainfall. Resulting crop loss totalled $3,500 in lost income.

Other crops dislike wet feet too, especially during germination, emergence and early growth, when ponding can affect establishment and final yield outcomes.

Weeds and soil-borne diseases can also flourish in affected areas.  Mobile nutrients, such as nitrogen, are easily leached beyond shallow root zones, resulting in potential deficiency. In worst cases, crops require replanting.

The project also looked at the grower’s greatest asset – their soil. Soil condition proved to be poorer in ponded areas. In particular, aggregates became clumpy, and soils heavily compacted.  When aggregation and structure collapse, soils become poorly drained and aerated, access to nutrients and water is restricted, and this reduces yield.

Nutrients and productive topsoil also concentrate in ponded areas after runoff.  In ponded areas, soil Olsen P levels were as much as 75% higher than adjacent unponded areas. Organic matter levels were higher too. This can contribute to variability and input inefficiency over time.

Furrow diking is a tool to reduce surface runoff. Small soil dikes (dams) are formed in wheel tracks by a towed implement. Controlling runoff largely eliminates the impacts of ponding, meaning better returns.

Horowhenua grower, John Clarke has seen how effective diking can be. In the past, ponding has reduced yields in low-lying areas. Where they tested diking there was no standing water after heavy rain, this is a major improvement.

Hawke’s Bay grower Scott Lawson of True Earth Organics, is also an advocate. “Diking eliminates ponding damage and can reduce disease incidence. It’s standard practice now”.

Growers may also harvest more rainfall, as water has more soaking time and therefore more storage in the soil.

Scott Lawson notes that soils need to have good drainage. “sustainability of farming operations includes promoting good soil structure, by building organic matter levels, reducing cultivation and working to eliminate compaction”.

For more information on ‘Holding it Together’ projects or on implementing practices on-farm please contact Paul Johnstone (Plant and Food Research) or Dan Bloomer (LandWISE).

14th Annual Symposium on Precision Agriculture in Australasia

Albury NSW, 2-3 September 2010

Hosted by the Australian Centre for Precision Agriculture and SPAA Precision Agriculture Australia

Summary Report by Dan Bloomer and James Powrie, LandWISE Inc.

Presentations at the symposium tended to refer to practical applications of Precision Agriculture technologies with a research focus.  They ranged across topics from grains, to remote sensing, and from livestock to viticulture.

The opening by outgoing SPAA President Mark Branson, referred to population increases, tightening oil supply and environmental regulation, crop losses through climate change and future restrictions on synthetic fertilisers.   Precision Agriculture was offered as an opportunity for the farming industry to invest in technologies to address these challenges.

Note:  The names credited here are those of the speakers.  Other authors also contributed to most of the papers presented. We assume full papers will be made available through SPAA or ACPA websites.

Assessment of sugar cane yield monitoring technology

Troy Jensen- National Centre for Engineering in Agriculture

Systems were trialled for monitoring sugar cane yield.  Significant variation was noted between yield monitor types.  While we don’t grow sugar cane in NZ there may be implications for forage harvesters.

Are passive sensors passé

Eileen Perry- DPI Victoria

Passive sensors rely on sunlight as the source that is reflected, so there are issues dealing with readings as light conditions change. Active sensors have their own light source, so they get a stable result in changing light conditions – and can be used at night if desired. Passive sensors have a place in remote sensing. Satellites, for example, cannot supply active light so remain passive. Passive sensors are also being used in permanent positions to monitor temporal changes in crop status.

Some links to other information: Tetracam.com and headworkphotonix.com and Quantalab in Spain may be interesting to review.  The FLIR handheld imaging sensors for carotenoids and chlorophyll looks interesting: www.psi.cz/products/pocket-sized-instruments/plantpen.

Precision pastures

David Lamb- Precision Agriculture Research Group, University of New England

Experiments have been using GPS information to track pasture quality and grazing behavior.   By tracking what animals are doing when, i.e, moving, still or eating, they are gaining insight into which areas are most productive.  This enables improved understanding for integrated landscape management.  Tracking animals shows places where they are not grazing at all.  Pasture quality patterns show up, with different pastures preferred morning to afternoon.

RFID animal tags are also being trialled to enable automatic walkover weighing and fleece weight recordings to assess growth achieved in relevant parts of the paddock.  RFID eartags with GPS (estimated 3 year battery life) are about 2 yrs from market.

Other studies have investigated training animals to allow remote control using sirens. This will potentially enable isolated stock to be managed and encouraged to move to new paddocks by a farmer  anywhere on the globe.

UNEPARG research has now shown that Cropcircle sensors with enhanced LEDs can now be used up to 50m above the ground for improved (and safer) aerial biomass measurement.

Once biomass variability has been mapped using, for example, optical sensors or CDAX pasture meter they believe you can define transects within a field that give you a shortcut to getting whole paddock biomass estimates (truncated biomass transects).

David Lamb also noted LIDAR may augment the use of sensors by adding more detailed knowledge of biomass.  David Manktelow’s Hawke’s Bay work with orchard canopies was mentioned.

Why do grapevine yield and quality vary in time and space?

Andrew Hall- National Wine and Grape Industry Centre, Charles Sturt University

Andrew reported that their research showed there are big annual deviations in yield.  Data from a normal year predicts variability in other years better than same-season sampling in an off-year.  Spatial variation was found to be greatest early and late in season.   Understanding the effects on weather induced change on reproductive processes and carbohydrate dynamics within the plant appears to be the key to making accurate productivity forecasts. [See also Rob Bramley’s report]

Remote sensing applications for the Australian cotton industry.

Andrew Robson- Queensland Department of Employment, Economic Development and Innovation.

Much of this focused on review of different resolutions of available remote imagery. Some satellite imagery is relatively coarse but is cheap for large areas so may prove appropriate in the cotton industry.  Strategic purchase of imagery at only necessary resolution can save cost.

UAV technology with PA to improve productivity and sustainability of macadamia orchards

Leasie Felderhof- Skyview Solutions Pty Ltd.

Regulations are holding back use of UAVs (model aircraft with cameras) in Australia and in US.    A commercial pilot licence is required for UAVs!  A macadamia orchard of 100ha was mapped in 4 hours flying time.  Wind can limit flight potential.

Image quality can be very high (3cm pixel size) and can be used to show individual leaves and identify early stages of pest attack.  This is possible using relatively easily available cameras.  New photo stitching technology makes it possible to easily and rapidly create mosaics from individual images.

Preliminary cost analysis suggests that nutrition maps derived from aerial images can lower production inputs and increase profits in the macadamia sector.

Fixing low pH soils and solving drainage problems with PA in NSW and Victoria

Tim Neale- precisionagriculture.com.au

Farmers can gain more value from their GPS purchase by using their guidance system to create farm topography maps.    Drainage analysis and cut and fill maps can then be created from these.  Software advances allowed them to reduce soil moved to ensure drainage by 90% compared to traditional laser levelling techniques.

High resolution satellite images were being used to identify areas suspected of low pH.  They compared targeted sampling to grid sampling and decided that zones drawn from satellite imagery were a good intermediate step to start on variable rate liming.  A targeted approach to pH can reduce the number of samples required.

John Deere Industry Update

Andrew Bremner John Deere AMS

A number of new John Deere PA products are being launched for 2011.  Remote access to tractors equipped with new communications features, will allow for fleet management, diagnostics and online backup.

An Automated system for rapid in field soil nutrient testing

Craig Lobsey- Australian Centre for Precision Agriculture

This work is bridging the gap between conventional lab sampling and lab analysis and current proximal soil sensors.  Wet chemistry is desirable for measuring soil nitrate, and potassium and sodium.  But rapid processing is essential for on-the-go in-field analysis. The research goal was to get wet chemistry sample processing done in 30 seconds to make in-field processing economic.  They found (the cunning bit) that by carefully measuring the rate of change of the chemical reaction at early stages they were able to predict a result that would be gained by the reaction going to completion (which takes 30+ minutes).

SPAA Precision Ag Association Grower group project

Leighton Wilksch- SPAA Precision Agriculture Association

The Grower Group project is focusing on site specific crop management. SPAA has 16 farm discussion groups running, with three meetings a year are held per group.

SPAA also ran their first annual Advanced Training Courses in PA for advisors and key farmers (70 attendees).  People we spoke to said this was stunningly good. We’ll find out if we can arrange a New Zealand course if there is interest.

Wireless Sensor Networks

Rakesh Devadas- RMIT University, Melbourne

Effective calibration of remote sensing by satellites, aeroplanes etc needs ground based data.  A system was set up to capture continuous ground based measurements, to give data that coincides exactly with aerial and satellite observations.  To collect that data, the researchers built an in-paddock sensor network that was wirelessly connected to a base computer, so that when satellite image received they had the necessary data to calibrate the image.  This cost $2K per node.

Identifying scales at which yield and soil attributes are related

Brett Whelan- Australian Centre for Precision Agriculture

This statistical presentation looked at the resolution (density of sampling points) of data collection, and the analysis of that data to explain the causes of variability. The amount of variability seen in data can relate more to the amount of sampling than the actual variability present.  Some analyses can show highly correlated results, but only explain a little of the variability. By changing the scales, you may have lower correlation but explain more of the variability.

Integrating temporal variation into the management of spatial variability of Precision Viticulture

Rob Bramley- CSIRO

Work was completed at Stoneleigh Squires vineyard in Marlborough.  This was led by Marlborough Wine Research Centre’s Mike Trought with John Paul Praat also involved in the project.  They analysed spatial vineyard information gained over several years to quantify relationships.  EM appeared useful for describing soil variation but detected very low EC values over a very narrow range due to shallow stony soils.  EC was closely correlated with trunk circumference.

They used an array of Cropcircle sensors from side of canopy to derive the Plant Cell Density (PCD) index. This uses the same wave bands (near infrared and red) as NDVI, but is a simple ratio rather than the difference ratio used for NDVI index. In contrast to Australian work, vine vigour assessments did not correlate with yield.  The researchers believe this is due to the high degree of bud selection at hand pruning.  Australian vines are typically machine pruned.

With assistance from a panel of winemakers they determined a juice score based on soluble solids, juice pH and titratable acidity.  They then predicted the change in juice score through time using the proximally sensed vine vigour data.  This gave a spatial fruit quality and maturity map of the vineyard changing over time.  This allowed them to create a map showing the date on which optimum harvest score was attained.

“Identifying those parts of the vineyard that produce the best fruit, and the date for best balance of flavour and aroma is the holy grail of viticulture research” (Mike Trought)

Onion Precision Agronomy

Trevor Twigden- National Onion Labs

Trevor’s team has been working on nutrient and plant stress impacts on onion pungency, sweetness and shelf life. There is a significant price premium for “mild onions” (called “sweet onions” in USA) which are actually low pungency rather than sweet.

To avoid pungency growers must avoid plant stress as the chemical involved (pyruvic acid) results from a stress response. There is “Mild Onion Certification” in Australia – Australia’s only flavour certified fresh horticultural product on the market. The research has demonstrated that precision agronomy e.g. GPS mapping and GPS generated sample sites with infield onion pungency testing makes it feasible to isolate areas with low pungency onions.  The marketing system is fully traceable, so the industry can assure quality is not degraded by untested onions being represented as mild.

A very large amount of spatially referenced sampling has enabled the researchers to identify soil, nutrient and nutrient combination effects on pungency and on storage quality. Pungency and sugars are independent.  Industry belief was that higher yields caused low storability, but this work shows good nutrition (at all points across the full site) allows high yields (100+ t/ha) and good storability.

TopCon Update

Martin Keye- Topcon

The CropSpec optical sensor has been through numerous upgrades.  It is currently being widely used in Montana to manage protein levels in wheat, because protein premiums are at record highs.

New TopCon products have remote communications ability allowing on-line service and support. Farmers can see exactly where each machine is and where it has been, from the office computer. They can send prescription maps directly to the tractor and equipment.  Martin sees great future for such connectivity allowing access to weather data etc from the cab. The move to wireless connectivity avoids the need for USB data sticks (thumb drives) or swapping data cards to transfer data – this is seen by many as a vital improvement.

Developing capacity via paddock learning – growers and groups

Simon Craig- Birchip Cropping Group (BCG)

Simon reported that use of PA technology for guidance is widespread among BCG farmers, but use of PA information for input decisions has been rare. Barriers of initial investment and aging gear are being displaced by drivers of reduced input costs and risks. A major limitation is software compatibility between office system and various different equipment protocols.

The BCG has been working with farmers to reduce inputs where possible, delay inputs such as nitrogen until later in the season when seasonal forecasts and yield potential predictions are more reliable. They have taught farmers to use paddock strips: e.g. leaving out an input in a pass that crosses over representative zones then monitoring yield at harvest time. These are very effective for building confidence to push the boundaries with little risk to production. An example relevant to NZ maize, would be leaving out P in starter fertiliser. They noted the benefits of running inter-seasonal nutrient budgets, reflecting previous crop extraction and anticipated yields.

PA education and training modules

Brett Whelan- Australian Centre for Precision Agriculture

Brett and colleagues have prepared a series of training modules based on the 2006 GRDC PA Training Manual. They identify different levels of knowledge sought, and structure the material accordingly. Each module covers a separate aspect of PA, and starts with a general introduction, allows an interested person to access more detailed information, and includes references to very details references should those be wanted. This information is intended to be made freely available, downloadable or CD, and open for use by educators and advisors as they wish to generate their own resources.

Future Trends in PA

James Hassall- Farmer and Nuffield Scholar in Precision Agriculture

James is a very long term PA farmer who built his own auto steer system years ago, and other pieces of equipment since. James presented a view of the future of PA, based on his experience, his Nuffield research and hours sitting in his tractor thinking.  He says ISOBUS communication between tractor and equipment is coming. However some manufacturers think it is already becoming redundant as it won’t cope with the required volume of data moving between multiple sensors on the tractor and equipment.  He says manufacturers are sharing information and testing compatiblity between gear by holding ‘plugfests’.

James is building a robot to move through his fields. He suggested that in terms of technology, the 80s introduced the personal computer, the 90’s the internet. We are currently seeing miniaturisation, and the next decade will see widespread introduction of robotics.  He believes he’ll be able to use his robot for many applications, including soil sampling, protein monitoring, weed spraying and more.

He noted work by David Slaughter using a robot to drop micro-doses of herbicide onto weed leaves. The Danish researchers have combined optical colour and shape technology to identify weed species and apply different chemicals at specific rates using bubble jet printer technology.

James is convinced that wireless data transfer and diagnostics will change farm management. No more having data cards slip out of your top pocket into the spray tank. He is keen to upload maps from office to tractor to manage equipment. He employs a lot of casual labour and remote access can assist the farmer ensure correct operation, and help inexperienced operators easily.

Trade Displays (a sample)

Apogee

Apogee is a defence company which has moved into agriculture, bringing a different spin on technology. They are highly specialised in satellite radar which penetrates cloud and works at night and can provide a lot of information not available through standard light sensing from satellites.  Radar allows identification of different materials, through polarizing of signals. http://www.apogee.com.au

Trimble

Trimble was marketing their equipment range and their base station network services.

Leica

Leica had a display of their ag products along with video on their mining and construction products with laser driven drafting of existing structures and earthworks.

Crop-Optics

Crop-Optics had a display of Weedseeker and Greenseeker sensors (formally manufactured by Ntech, now owned by Trimble).  The display included a moving banner of maize plants being scanned by Greenseeker and showing calculated variable rate against the NDVI score changing as the plant images passed.  Contact Scott Jameson

PrecisionAgriculture.com.au

Tim Neale and Andrew Whitlock had their imaging, training packages and consulting services on display.

Outline Imagery

This is a South African firm now in Australia.  They have an easily mounted multi-spectral camera for aircraft.  Contact Andrew Coleman

LandWISE 2010 Conference – Know your Farm with Precision Ag

As published in Grower June 2010.

James Powrie and Dan Bloomer, LandWISE Inc.

“The life-cycle, right through to the end consumer, matters a lot if we are to capture value and climb out of the commodity trap”, says James Palmer, MAF Policy’s Director of Strategy Development. In his opening address at the LandWISE Conference, Palmer highlighted the challenges faced by agriculture in New Zealand. He noted that Precision Agriculture can help farmers to grow the natural capital and markets on which our economy depends.

Held in Havelock North, with a high tech field session at the Centre for Land and Water in Hastings, the conference attracted 130 delegates. Farmers, researchers and industry people congregated to learn more about the benefits of advanced farming systems for vegetable, arable and pasture crops.

New technologies such as GPS, crop sensors, imaging and communications are driving farming forward in Australia, reported Professor David Lamb from the University of New England, NSW.   Lamb, Leader of the Precision Ag Research Group described new applications in cropping, pastoral systems and viticulture and the use of crop sensors, satellite imaging and livestock tracking.  On the LandWISE Conference itself, he said, “This has been the most enjoyable event I have attended in many years.”

Fellow Australians,  Dr Eileen Perry and Dr Roger Mandel spoke about the physics of crop sensing, how Australian growers are making technology pay and also, perhaps most importantly, how to avoid its pitfalls. “Check very carefully what support you will be getting – I’d sooner have the next best technology with the best support,” said Mandel. “If you can’t get support when and where you need it, you’ll have a very expensive tool doing absolutely nothing,” he said.

LandWISE Manager, Dan Bloomer notes, “Australia has invested heavily in Precision Agriculture – probably owing to the very marginal nature of some of their farming, and their need to target inputs accurately and take special care of their soils and water.”    New Zealand growers are taking on Precision Ag as their profitability is challenged and environmental performance is becoming a key success factor. “Cost saving technologies like GPS, auto steering and high tech spraying and planting gear are getting cheaper while the other input costs are all going up.  Farmers are catching on fast, and once in, they wonder how they ever did without it,” he adds.

Fuel savings from 25-55% are being made in Controlled Traffic Farming operations. LandWISE is monitoring progress on farms producing onions, spinach and lettuce and maize cropping.  Plant and Food scientist, Paul Johnstone, and AS Wilcox Crop Supervisor Simon Wilcox told delegates about trials of permanent beds for onions and potatoes. After only one crop, measureable soil improvements and fuel savings are seen. AS Wilcox will greatly increase the area of Controlled Traffic Farming this year.

Reddy Pullanagari is a doctorate student at the NZ Centre for Precision Agriculture at Massey.  He has begun work with NZ Fresh Cuts Operations Manager Chris Butler, who spoke about CTF in salad cropping and crop sensing for nutritional management.

“Conferences are great, but we need more of this closer extension happening throughout agriculture,” says Bloomer.  “LandWISE works hard to improve communication between farmers, scientists and academics. We believe strongly in cooperative research efforts and excellent communication between farmers and researchers,” said Bloomer.  “And it seems to work well.”

Three scholarships enabled students to attend the Conference. Apatu Farms sponsored a leading Ag/Hort student from Lindisfarne college in Hastings.   LandWISE matched this to allow Sam Tod and Rowan Sandford to attend the conference free of charge.

Anna Gillum, an honours student from Massey University, also attended the conference on a scholarship from LandWISE, “It has confirmed for me that I have chosen the right industry.  It was nice to realise that my last 3 years of study, and this post grad year, will benefit me as well as give me an enjoyable future in this industry.”  she said.

AGMARDT provided travel assistance to the conference from Australia for Professor David Lamb, Dr Eileen Perry and Dr Roger Mandel.

Horticulture NZ Fresh and Process Vegetable Product Groups and Potatoes New Zealand were Gold sponsors of the LandWISE Conference.  They were in good company, with Waterforce, CASE IH, Trimble, Hawke’s Bay Regional Council, EECA, Foundation for Arable Research also leading sponsors of the event.

The LandWISE website www.landwise.org.nz contains information on current members, articles on precision agriculture and many resources and tools.  It is also a place to comment, chat and ask questions about where to go to learn more.

LandWISE membership puts you in touch with other innovative growers, industry folks and technologists, join at http://www.landwise.org.nz/join/

Visit the website to learn more, or contact James direct on 06 6504531 or 0272 757757.

Going High Tech at Holton Farm

As Published in ‘Grower’ Magazine February 2010.

Like many farmers who have adopted precision agriculture, Tim Macfarlane is using GPS to control his machinery.  This gives savings in time, fuel, labour, machinery and other input costs.

Tim farms Holton Farm near Kaiapoi.  He grows sweetcorn and pumpkin for the fresh market and seed crops including cabbage, clover, ryegrass and radish.  Peas, wheat and barley are grown for feed.

The first steps into precision agriculture came to the farm in the 1990s. A hired hand-held GPS was used to map paddock boundaries. Knowing true paddock sizes allowed for accurate ordering of seed and chemicals.

Now, GPS guides the tractor providing for more efficient cultivation, planting, fertilising and inter row cultivation.  It controls his spray boom too, switching nozzles on and off, section by section at exactly the right time.  Spraying is more precise and less overlapping of herbicide applications reduces chemical waste and yield reduction.

Leica RTK GPS is now used for all high accuracy guidance, with corrections coming from an on-site base station. This gives season to season accuracy of better than 2 cm. Farm operations are routinely logged with GPS and transferred into an integrated farm mapping and management program.

New technology keeps coming to Holton

GPS and auto steering is allowing a shift towards Controlled Traffic Farming (CTF) which Tim thinks will increase yields by reducing overall compaction.  CTF is also expected to provide other efficiencies. “As we grow in confidence with Precision Ag, endless possibilities are opening up to us,” says Tim.

GPS allows various types of captured data to be precisely located and mapped on the farm.  EM38 soil conductivity sensing is being used to map relative water holding capacity across the farm.  Greenseeker crop sensors are capturing differences in greenness across paddocks, helping decisions about weed control.  Yield maps are clearly showing how much crop was harvested from each part of a paddock.

EM38 scanning and mapping was conducted in 2009.  The intention is to gain understanding of soil depth, quality and water holding capacity.  This information will be used to plan rotations and decide whether to irrigate more of the property.

EM38 mapping also helps determine location and depth of old, forgotten drains, identifying areas where inversion and ripping might be practical.

Weeds and technology

Weed challenges are now focusing Tim’s attention on GPS based weed management practices. These offer alternative options for control and can increase efficiency in the use of chemical, fuel and other inputs.

Tim wants systems that allow him to determine weed type and density using sensing and GPS mapping tools.  Once the target is well understood, chemical rates and application methods can easily be varied. Already, GPS controlled boom switching is reducing overlap, providing accurate record keeping and proof of placement, and easy recording of chemical trial data.

When chemical tools are unavailable, the improved accuracy of RTK allows very efficient mechanical weeding. The accuracy lets Tim go later with the final inter row weeding pass and go closer to the planted crop. And RTK inter row weeding means less hand weeding in radish, sweetcorn, cabbage and pumpkin row crops.

The future of technology at Holton

Technology is giving gains at Holton.  Tim says, “As we learn more about technology, we learn more about our farm and how we can keep making progress. Over time and with good planning, precision ag ensures that huge benefits are gained in production, efficiency and economics for the entire operation”

Tim is an agent for Leica Geosytems Precision Ag products, Raven GPS and spray control equipment, and Farm Data software. These technology products are integrated into the farming system.  The GPS feeds operations and yield data into the farm software.  Farm software feeds data and map files back to the GPS.

If you would like to keep making progress on your farm and to understand Precision Agriculture better, you may like to join LandWISE and to attend the LandWISE conference in Havelock North on May 12th and 13th.  This year’s conference will be called ‘Know your farm – with Precision Ag’.

See www.landwise.org.nz for more information.

Guest Post: Dr Paul Johnstone (Plant and Food Research) on Improving Profits by Reducing Surface Ponding

Ponding of surface runoff from rainfall and irrigation can reduce crop production. The ‘Holding it together’ project addresses this.

Plant & Food Research and LandWISE are working with growers on ways to reduce surface ponding, improve soil quality and increase returns.

MAF Sustainable Farming Fund, Fresh Vegetable Product Group, Potatoes NZ, Hawke’s Bay Regional Council, Horizons Regional Council, Auckland Regional Council, Environment Waikato and Ballance Agri-Nutrients have funded the project.

Runoff occurs when water infiltration is slower than application of rain or irrigation. In some soils, slow infiltration is due to texture, in others it is reduced by frequent tillage or compaction. Whatever the cause, runoff can pond for extended periods, in low-lying dips or field edges. This ponding can be damaging to crops.

Trials with onions have shown that even temporary ponding can reduce yields. Yield loss ranged from 60-80%.  Ponding also reduced the proportion of yield within the most profitable size range.

In one field, a leaky pipe resulted in ponding during irrigation. This area of 0.2 ha cost the grower $1,700 in lost income. The cost of fixing the pipe was $10.

A  similar-sized area was affected by ponding during spring rainfall. Resulting crop loss totalled $3,500 in lost income.

Other crops dislike wet feet too, especially during germination, emergence and early growth, when ponding can affect establishment and final yield outcomes.

Weeds and soil-borne diseases can also flourish in affected areas.  Mobile nutrients, such as nitrogen, are easily leached beyond shallow root zones, resulting in potential deficiency. In worst cases, crops require replanting.

The project also looked at the grower’s greatest asset – their soil. Soil condition proved to be poorer in ponded areas. In particular, aggregates became clumpy, and soils heavily compacted.  When aggregation and structure collapse, soils become poorly drained and aerated, access to nutrients and water is restricted, and this reduces yield.

Nutrients and productive topsoil also concentrate in ponded areas after runoff.  In ponded areas, soil Olsen P levels were as much as 75% higher than adjacent unponded areas. Organic matter levels were higher too. This can contribute to variability and input inefficiency over time.

Furrow diking is a tool to reduce surface runoff. Small soil dikes (dams) are formed in wheel tracks by a towed implement. Controlling runoff largely eliminates the impacts of ponding, meaning better returns.

Horowhenua grower, John Clarke has seen how effective diking can be. In the past, ponding has reduced yields in low-lying areas. Where they tested diking there was no standing water after heavy rain, this is a major improvement.

Hawke’s Bay grower Scott Lawson of True Earth Organics, is also an advocate. “Diking eliminates ponding damage and can reduce disease incidence. It’s standard practice now”.

Growers may also harvest more rainfall with diking installed, as water has more soaking time and so more storage in the soil.

Scott Lawson notes that soils need to have good drainage. “sustainability of farming operations includes promoting good soil structure, by building organic matter levels, reducing cultivation and working to eliminate compaction”.

For more information on ‘Holding it Together’ projects or on implementing practices on-farm please contact Paul Johnstone (Plant and Food Research) or Dan Bloomer (LandWISE).

2010 LandWISE Conference

2010 LandWISE Conference

Know Your Farm – With Precision Ag, Havelock North, 12th & 13th May.

The LandWISE conference aims to be to the leading Precision Agriculture event in New Zealand each year.

You will get to meet other farmers, growers and industry people with an interest in Precision Agriculture.  And  hear world class speakers on these topics:

  • Precision Ag and the Big Wide World – MAF Director of Strategy Development – James Palmer, Professor David Lamb (UNE) and Dr Charles Merfield, will address the challenges and changes driving advances in Precision Ag. in NZ and worldwide.
  • Making Your Data Valuable – New ways farm data is enhancing farm profitability.  See how it is being collected and used to farm better.
  • Knowing and Growing Your Soil – Ways you can preserve and improve soil quality.
  • Managing Traffic in the Field – Updates on managing soil compaction, a technical session on tyre inflation and successful Controlled Traffic Farming in NZ.
  • Managing Variability – Demystifying crop sensors, agronomy tools and Variable Rate Technology to improve effectiveness with fertiliser and other inputs.
  • Precision Irrigation – How some NZ  farmers are managing water smarter to reduce the cost and environmental impacts of irrigation.

Members enjoy a discount, so if you are coming to the LandWISE conference, consider signing up, you will be in excellent company.

This year the LandWISE Conference will be followed by a one day Crop Sensor Workshop on 14th May 2010.  Places limited.

To receive a conference schedule, to register or to learn more about our activities, contact LandWISE for more information at info@landwise.org.nz