Now Open For Registration! 

Working in partnership, GLASE, OptimIA, and LAMP are excited to announce the first annual Plant Lighting Short Course! This 6-week modular short course is designed to provide participants the opportunity to learn about all aspects related to the selection, implementation, and benefits of plant lighting systems.

In each sequential module, attendees will use interactive tools to define their specific lighting requirements, hear from industry experts about available horticultural lighting systems, and learn how to compare different lighting strategies. By the end of the course, participants will be equipped to make informed decisions about the best options to meet their lighting needs.

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Recordings Now Available

The photosynthetic activity of far-red photons was discovered 70 years ago, but has largely been ignored since then. Recent research has drawn new attention to the importance of far-red photons.

This short presentation will cover the history of research on photosynthetic responses to light spectrum, recent work on the importance of far-red photons, and a discussion of the implication of (not) extending the definition of PAR. There will be ample time for discussion following the presentation.

Register Here - August 26 • 2-3 p.m. EST

iUNU (“you knew”) is an agricultural machine vision company headquartered in Seattle, with satellite offices in California, Florida, and Toronto as well. Founded in 2013 and currently with over 40 employees across the world, the company leverages computer vision and machine learning to allow farms to better manage crop issues and optimize growth cycles. The LUNA system focuses on identifying growing maladies before the crop is affected and promotes better accountability of growing practices through the workflow management application.

In making the announcement, Adam Greenberg, CEO of iUNU, said: “Rising consumer demand is accelerating the growth of the greenhouse industry, but the massive shortage of both growers and manual labor requires a scalable machine vision solution to further produce supply. Having a renowned agronomy team to assist in deploying state-of-the-art technology like LUNA will have a profound impact on our constantly improving capacity to help growers increase quality, yields, and profits. 65% of growers are above the age of 55, and the shortage of qualified people is hitting the fast growing industry hard. Something has to give, thus the future is the centralized management of distributed facilities.”

CropWalk is an integrated pest management (IPM) company that was founded in 2019 and has an expanding team with employees located in key regions across North America, including their Founder and Director of Partnerships, Charlie McKenzie, in the US Southeast, and the CropWalk Director of Operations, Robert Shearer, and Director of Science, Education, and Strategic Development, Ayana Stock, along the US West Coast. 

They are a widely recognized name in the horticultural industry for their unbiased approach to empowering growers of high-value crops with the knowledge and resources to prevent and manage pests and plant pathogens. With plans underway to expand their crop care services, CropWalk is well-known for how they customize a unique suite of services for operations of various kinds, offering risk assessments, IPM program development, training sessions, the online CropWalk Academy, and more, including remote monitoring services, the capacity of which are now dramatically enhanced by iUNU’s LUNA system.

Charlie McKenzie, CEO of CropWalk, said: “We’ve always used remote monitoring technology to identify and mitigate conditions that foster plant pathogens. The mantra we live by at CropWalk is ‘Start Clean, Stay Clean.’ Working with the iUNU team and using LUNA, we can digitally walk a crop from anywhere at any time allowing our team to effectively prevent problems before they result in economic injury. Our clients want us around more often, with LUNA, we can be there all the time. It’s a win for growers, a win for CropWalk, and a win for iUNU.”

LUNA, iUNU’s chief product, is an AI tasked with connecting plants, facilities, and people through a single interface. LUNA runs on computers or mobile devices and turns commercial greenhouses into precise, predictable, demand-based manufacturers. LUNA was born in the heart of Seattle, trained in Silicon Valley and the greenhouses of Washington, and is accessible from everywhere.

The future of crop care in modern greenhouses that will feed families for generations involves both people’s human expertise and the best available technologies. The union of iUNU and CropWalk is great news for CEA crop producers seeking the advantage of cutting-edge artificial intelligence, computer vision, and machine learning coupled with industry-leading IPM & biological services. Two companies that were excelling independently have joined forces to set a new standard for the remote monitoring of crops. Services of both companies will still be available for clients independent of one another but will have expanded resources at their disposal.

iUNU’s acquisition of CropWalk helps both companies become more effective in their work towards an important common goal: reducing the cost of nutrient-rich food reaching urban centers while helping growers thrive.

Dates: October 14 - November 18, 2021
Time: Thursdays 2 p.m. - 4 p.m. EDT
Presented by: GLASE, LAMP, OptimIA

More Info and Registration

About the Course

Working in partnership, GLASE, OptimIA, and LAMP are excited to announce the first annual Plant Lighting Short Course! This 6-week modular short course is designed to provide participants the opportunity to learn about all aspects related to the selection, implementation, and benefits of plant lighting systems. In each sequential module, attendees will use interactive tools to define their specific lighting requirements, hear from industry experts about available horticultural lighting systems, and learn how to compare different lighting strategies. By the end of the course, participants will be equipped to make informed decisions about the best options to meet their lighting needs.

Speakers

Bruce Bugbee (Utah State University)
Erik Runkle (Michigan State University)
Roberto Lopez (Michigan State University)
Neil Mattson (Cornell University)
Marc van Iersel (University of Georgia)
Jim Faust (Clemson University)
Kale Harbick (USDA ARS)
A.J. Both (Rutgers University)
Paul Sellew (Little Leaf Farms)
Travis Higginbotham (Harborside Group)
Paal Elfstrum (Wheatfield Gardens)
Tessa Pocock (Shenandoah Growers)
Drew Koschmann (Walters Gardens)
Kenneth Tran (Koidra)
Mark Blonquist (Apogee)
Michael Eaton (Cornell University)
Trevor Burns (PL Lighting)
Joe Sullivan - (Franklin Energy)
David Hawley (Fluence Bioengineering)
Ben Campbell (University of Georgia)
Tim Shelford (Cornell University)
Erico Mattos (GLASE)

Special Thanks To Our Industry Partners

Join today

If you have any questions or would like to know more about GLASE, please contact its executive director Erico Mattos at em796@cornell.edu

By the end of the course, participants will be equipped to make informed decisions about the best options to meet their lighting needs.

Event Webpage

The University City company has received a $250,000 grant to conduct research at the National Renewable Energy Laboratory in Colorado.

by Harold Brubaker

07-12-21

Crops in greenhouses — an increasingly popular way to supply year-round fresh greens and other produce to places with cold winters — are most productive when they receive the right amount of light at the right time.

But there’s a downside. Greenhouses are energy hogs and typically generate more gasses than traditional field agriculture because of their lighting and heating needs. Those are terrible characteristics for a burgeoning industry at a time of growing concern over global warming.

GrowFlux, a Philadelphia agricultural technology start-up that is trying to make the industry more efficient, won a $250,000 grant last week from the Wells Fargo Innovation Incubator for research at the National Renewable Energy Laboratory (NREL) in Colorado. The aim is to reduce energy consumption in greenhouses by fine-tuning the amount of artificial light that crops receive.

Simple timers are traditionally used to turn lights on and off in greenhouses, said Eric Eisele, GrowFlux’s chief executive, and cofounder. “They’re not dialing in the light in accordance with when the crop is actually using light most efficiently,” he said. “It results in a fair bit of energy that’s wasted.”

The GrowFlux system — to be further developed with the help of researchers at NREL and the Donald Danforth Plant Science Center in St. Louis — measures the natural light available and then adjusts the artificial light to add more when needed.

GrowFlux estimates that it can cut energy use by 20% to 30%.

While the grant, funded by the Wells Fargo Foundation, involves GrowFlux’s lighting controls, the University City company has a broader target with sensors that monitor carbon dioxide levels, humidity, temperature, and other factors that determine how well plants grow.

“They were one of the very first companies that were trying to essentially make farms like ours smart farms by using technology,” said Ajit Mathew George, founder and managing partner at Second Chances Farm in Wilmington, an indoor vertical farm that employs formerly incarcerated individuals.

“You don’t think of indoor vertical farms as being a place where technology plays an important part,” said George, who uses a GrowFlux app on his phone to monitor Second Chances Farm. “It does, and the more it does, the better our production is.”

Investor interest in indoor agriculture surged last year, with $929 million going into 41 deals in the United States, according to PitchBook Data Inc. That’s twice the amount invested the year before. Most of the money went into producers rather than into makers of components and technology like GrowFlux.

Eisele, 35, and Alexander Roscoe, chief technology officer, founded GrowFlux in 2017. Both are Drexel University graduates.

Eisele’s background is in interior lighting for humans. He worked for seven years in the research group at KieranTimberlake, a Philadelphia architecture firm. Rosco, 36, worked at Comcast on the build-out of national internet architecture.

GrowFlux’s first products, launched in 2018, were horticultural lights with built-in wireless technology. “The lighting space got very competitive in horticulture due to legalization of cannabis,” Eisele said.

The start-up, which now employs four, was competing with “the likes of Philips and General Electric and Osram,” Eisele said. GrowFlux dropped its lights in 2019 but kept developing its controllers.

Eisele and Roscoe declined to disclose their annual revenue but said they have raised close to $2 million from investors. The company has products in more than 100 farms, including indoor cannabis producers and greenhouses growing food like tomatoes and strawberries. The products are also used overseas, in Iceland and in an indoor vertical farm in Singapore that grows strawberries, Eisele said.

Trish Cozart, NREL’s program manager for the Wells Fargo Innovation Incubator, which in the past has worked with companies involved in traditional farming, said that over the next 30 years, global food production will have to increase by 60% to meet demand. NREL is part of the U.S. Department of Energy.

“It might not be possible to meet that demand through field-grown agriculture. Indoor agriculture is going to play a part. We don’t know how big of a part,” she said. But because indoor agriculture consumes so much energy, “we want to figure out how to combat that using innovative companies,” Cozart said.

Published July 12, 2021

• Harold Brubaker

• I write about the business side of health care and the nonprofit sector.

July 6, 2021 

Eindhoven, the Netherlands – Signify (Euronext: LIGHT), the world leader in lighting, is supplying Walters Gardens with the Philips GreenPower LED toplighting compact to expand their existing lighting installation. Walters Gardens is a market leader in the ornamental industry from Zeeland, Michigan, in the United States.

They first trialed Philips GreenPower LED toplighting in 2014 - one of the first growers in North America to install Philips horticulture LED grow lights over ornamental crops, with the aim to jump-start their spring perennial production.  

As a result of the trial’s success, Walter’s Gardens partnered with Signify again, when expanding their lighted growing areas in 2019 - 2020, with the Philips GreenPower toplighting compact.

“It was a really easy decision to go with the Philips LED toplighting compact”, says Aren Philips, finishing lead grower at Walters Gardens. “The tops are fuller, the roots are more active, we are able to finish our hostas product 1 to 2 weeks ahead of schedule.”

Together with the high efficacy of the toplighting compact, and the easy 1:1 replacement of the HPS, leading to a great ROI, Walters Gardens knew the expansion would pay off.

Learn more about the Philips LED grow lights for floriculture here.   

--- END ---

For more information:

Global Marcom Manager Horticulture at Signify

Daniela Damoiseaux

Tel: +31 6 31 65 29 69

Email: daniela.damoiseaux@signify.com

www.philips.nl/horti

About Signify

Signify (Euronext: LIGHT) is the world leader in lighting for professionals and consumers and lighting for the Internet of Things. Our Philips products, Interact connected lighting systems and data-enabled services, deliver business value and transform life in homes, buildings, and public spaces. With 2020 sales of EUR 6.5 billion, we have approximately 37,000 employees and are present in over 70 countries. We unlock the extraordinary potential of light for brighter lives and a better world. We achieved carbon neutrality in 2020, have been in the Dow Jones Sustainability World Index since our IPO for four consecutive years and were named Industry Leader in 2017, 2018 and 2019. News from Signify is located at the Newsroom, Twitter, LinkedIn, and Instagram. Information for investors can be found on the Investor Relations page.

June 28, 2021

Eindhoven, the Netherlands – Signify (Euronext: LIGHT), the world leader in lighting, has signed a partnership agreement with Hortipar, an expert in realizing lighting projects for the horticultural sector worldwide. Hortipar is based in ‘s Gravenzande, the Netherlands, and operates mainly in North America, Canada, Eastern Europe, and the Netherlands.

Hortipar will now add Philips GreenPower LED grow lights to their global portfolio. Focussing on quality, flexibility, knowledge, and expertise, Hortipar offers their customers a complete solution for their greenhouse from the beginning till the end of a lighting project. With their independent advisors and team of dedicated experts, Signify is proud to add Hortipar to the global partnership network of Philips Horticulture LED.

“We are excited to be a partner of Signify and offer the range of Philips GreenPower LED grow lights to our customers”, said Aad van Ruijven, director at Hortipar. “Sustainability and innovation are of great value to us and to our network. Our customers expect the highest quality, and that we offer them the full package for their lighting installation, together with high-end advice and project management. The expertise of the team at Signify and their Philips GreenPower LED grow lights fit perfectly within these expectations and in our ambitions for the future.”

“Adding Hortipar to our global network of certified Philips Horticulture LED partners is something we are proud of”, said Udo van Slooten, Business Leader Horticulture at Signify. “According to our estimates, about 30% of the world’s greenhouse surface will be lit by 2025, and LED technology will light more than half of that surface. Therefore, we are continuously pursuing further development of our Horti LED partnerships worldwide, and Hortipar is a valuable addition.”

Signify continues to expand its Horticulture partner network, further demonstrating its commitment to lead the horticulture industry as the innovative LED lighting systems provider for greenhouses and indoor farming. 

--- END ---

 For further information, please contact:

Global Marcom Manager Horticulture at Signify

Daniela Damoiseaux

Tel: +31 6 31 65 29 69

E-mail: daniela.damoiseaux@signify.com

www.philips.com/horti

About Signify

Signify (Euronext: LIGHT) is the world leader in lighting for professionals and consumers and lighting for the Internet of Things. Our Philips products, Interact connected lighting systems and data-enabled services, deliver business value and transform life in homes, buildings and public spaces. With 2020 sales of EUR 6.5 billion, we have approximately 37,000 employees and are present in over 70 countries. We unlock the extraordinary potential of light for brighter lives and a better world. We achieved carbon neutrality in 2020, have been in the Dow Jones Sustainability World Index since our IPO for four consecutive years and were named Industry Leader in 2017, 2018 and 2019. News from Signify is located at the Newsroom, Twitter, LinkedIn and Instagram. Information for investors can be found on the Investor Relations page.

June 15, 2021

·     Provides better steering of the plants

·     Optimizes winter growth

·     Helps growers realize a stabile production pattern with high yield and good quality strawberries

Eindhoven, the Netherlands – Signify (Euronext: LIGHT), the world leader in lighting, has worked together with Fragaria Innova to develop specific light recipes for strawberries, resulting in a steady production pattern with high yield, and good quality strawberries in wintertime. The joint research over the past year helps to further optimize the winter production of the so-called ‘June bearers’, a strawberry cultivar known for relatively short peaks in production.

Within Fragaria Innova, progressive strawberry growers commit themselves, together with external partners, to innovation surrounding the themes of growing under light and plant health. For growing under light, Fragaria Innova and market leader Signify conduct a multi-year program with participating growers/propagators. At one of the production companies, a special compartment has also been equipped with separate climate control, this enables the testing of several growth- and light strategies for multiple cultivars under full LED. One of the main goals of the research is realizing a (more) stable production pattern during wintertime.

Current winter productions usually take place with June bearers with a short production period of 8 to 10 weeks, after which a new planting in another section takes over production to create a stable, flat production. Unlit cultivation dominates before- and after the winter production.

“Extra growth light is needed to realize sufficient yield and quality in winter”, according to plant specialist Peer Hermans, who conducts the research on behalf of Signify. “The trials have shown that you can influence the plant build-up somewhat with specific light recipes, for which LED is ideally suited.” By accurately tuning the light intensity and spectrum offered to the developmental stage of the plant, you can optimize the leaf surface and stretching of the flower trusses and leaf stalks. A better plant build-up can benefit the production. The idea is to raise the production quality through light optimization.  

Grower Marcel Dings from Brookberries, co-initiator behind Fragaria Innova, noticed some influence on the plant build-up, but the extra assimilates that came with it, went mostly to the crop and less to the fruits. Dings: “Next season will focus on how we can further optimize the division of the assimilates in the plant, and how we can get the assimilates to the fruits”. The grower notices that there are a lot of variables at play, such as: cultivars, planting times, cultivation goals, light spectra, light intensity, and the balance between natural daylight and artificial lighting. “The benefit of this new generation of LED grow lights is that we can play with lighting efficiently and that we can finetune the recipe to our own wishes and possibilities. Within this project, together we can achieve faster and more progress. I am satisfied with the results of this first year, but there is definitely room for further optimization. Hopefully, we can keep this going in the coming years.”

Grower Dave Linssen, a participant within Fragaria Innova (cultivar: Malling Centenary), had a trial with different spectra at one company location, planted in August just like his unlit crop. “The lit plants went into production earlier in winter, as expected. When it came to kilos and plant build-up, we hardly noticed any difference between the light spectra”, he concludes. “We may need to tinker a little to get the ideal light recipe for our company. It seems obvious to me that growing under LED is a desired addition.”

 Based on these encouraging results, the trial set-up for the coming season will be determined. Spectrum research and testing different cultivars will be part of this research. For more information on growing strawberries with LED grow lights, please go to www.philips.com/horti.

--- END ---

For further information, please contact:

Global Marcom Manager Horticulture at Signify

Daniela Damoiseaux

Tel: +31 6 31 65 29 69

E-mail: daniela.damoiseaux@signify.com

www.philips.com/horti

About Signify

Signify (Euronext: LIGHT) is the world leader in lighting for professionals and consumers and lighting for the Internet of Things. Our Philips products, Interact connected lighting systems and data-enabled services, deliver business value and transform life in homes, buildings and public spaces. With 2020 sales of EUR 6.5 billion, we have approximately 37,000 employees and are present in over 70 countries. We unlock the extraordinary potential of light for brighter lives and a better world. We achieved carbon neutrality in 2020, have been in the Dow Jones Sustainability World Index since our IPO for four consecutive years and were named Industry Leader in 2017, 2018 and 2019. News from Signify is located at the Newsroom, Twitter, LinkedIn and Instagram. Information for investors can be found on the Investor Relations page.

 About Innoveins | Fragaria Innova

Innoveins is an ecosystem where organizations cooperate at the cross-over between plants and technology to develop innovations through co-creation and bring them to the market.

Within Innoveins, Fragaria Innova unites ambitious strawberry growers to jointly tackle challenges in the areas of labor, upscaling, efficiency, plant health and resilience, biodiversity, growth media, product quality, continuity, delivery reliability and smart farming.

While celebrating its 125 years of existence this year, Certhon is far from done developing and expanding within the horticultural market. There have been a lot of developments for the company in the last few years. For example, Certhon established its own Innovation Center to research the optimization of technologies in the field of indoor farming. With a team of technology experts and agronomists, Certhon always tries to find ways to improve cultivation methods. Another development is the partnership between DENSO and Certhon that has been established last year. This collaboration is meant to accelerate the technologies used in horticulture.

We also see that projects are becoming more and more complex, large-scale, and international. Certhon is already active all over the world: from Europe to the Middle East and from Asia to North America. Because the demand for fresh greenhouse produce is still on the rise in the North American market, Certhon works to realize a stable presence in the United States. That’s why Timo Kleijwegt and Fred van Veldhoven have joined Certhon to rejuvenate and bring in experience to serve this growing market optimally. This, combined with dedicated local people and a support team based in the headquarters in Poeldijk, the Netherlands, entrepreneurs in North America can rely on the best Certhon has to offer and 24/7 support.

Turn-key greenhouse projects
For expansion of an existing greenhouse, new (indoor) facility, or turnkey set up, Certhon has all the knowledge, know-how, and technologies under one roof to enable entrepreneurs to produce local, fresh food. All in accordance with the local regulations and requirements, and the wishes of the customer. One of Certhon’s solutions is the SuprimAir greenhouse, which is a semi-closed greenhouse that provides optimal growing conditions for various crops like tomatoes and peppers, but also ornamentals like orchids.  

“In fact, Certhon doesn’t just design and construct a greenhouse, but creates the optimal climate and conditions to realize the best results,” says Fred van Veldhoven, who recently joined Certhon as International sales manager. “Certhon has its own developed system to obtain a complete and updated backtrack of the climatological conditions of a particular area per hour!” continues Fred. “All available data has been brought together and presents a reliable picture of the local situation. Future developments are being forecasted and extremes are being analyzed. This way, the right facility can be calculated, designed, and built for anything, anywhere.”

The American market is probably the most dynamic and demanding in the world and the consumers are used to have access to high-quality food, flowers, and ornamental plants. “Entrepreneurs choose for the total solution approach of Certhon, so they only have to turn the key,” concludes Fred.

State-of-the-art indoor farms
Besides traditional greenhouses, indoor farming has become a professional segment that develops faster in the United States than anywhere else. In some cases, these facilities are complementary to the greenhouse, but mostly these are stand-alone setups. The legalization of cannabis production in various states in the US and Canada has boosted this development. However, more and more entrepreneurs discover the benefits of fully controlled indoor food production, just around the corner.

Also within the larger agglomeration areas where fresh food is more expensive, indoor farming is part of the supply chain. Recently, Timo Kleijwegt joined Certhon as sales manager for the US market to respond to this development. Timo: “In our Innovation Centre, we have several indoor cells that are all designed differently so we can test which systems are working better for different purposes.

One of the crops we are testing and that is very interesting for indoor farming, are strawberries. Certhon has developed a unique growing concept for indoor strawberry production, which is highly profitable. Besides all the benefits that come with indoor growing, we see enormous positive results in yield and taste of growing strawberries indoors. At the moment, the final trials are being concluded. If anyone is interested in the results, they can contact me for a one-on-one presentation.”

Certhon will be present at key events in the US and Canada to share the latest developments, including the PMA in New Orleans in October. “We are looking forward to talking to ambitious entrepreneurs there,” Timo concludes.

May 17, 2021

·       When you compare different lighting designs, make sure to compare apples with apples.

·       These are the 5 things to check when comparing lighting designs for LED grow lights.

Eindhoven, the Netherlands – As a grower, you invest in supplemental LED grow lights because they power the yield and quality of your crops. In fact, the rule of thumb is that 1% light output equals 1% crop yield. So, it is vital that your LED lighting investment delivers the full performance you paid for.

The performance is determined by the light intensity and light uniformity of the LED grow lights you use. If the installed light intensity is lower than what has been designed, there will be less yield. If the uniformity is inconsistent, individual plants will grow and develop at different rates and there will be uneven production in your greenhouse.

Before you start

When you compare different lighting designs, make sure to compare apples with apples. This means taking 3 things into account:

1.     Verify the credibility of the performance claims that manufacturers make

2.     Make sure that DIALux calculation software is used for the lighting design. This calculation software is independent and commonly used in the horticulture market.

3.     Check which input parameters have been used for each lighting design. It is easy to tweak the input parameters and give the impression of a more positive light level and uniformity within the lighting design. So which parameters are crucial?

Most important input parameters to check

•     Is the right product specified? Check if the exact product that you have selected for your project has been used in the lighting design; with the right light output (PPF in µmol/s) and spectrum (blue/red/white/far red/…)

•     Are your specific design values used like the average light level at your crop (PPFD in µmol/m2/s) and the overall light uniformity?

•     What are the standard settings? The height of the grow light and crop (free height), reflection factors, and size and position of the area that is used in the uniformity calculation have an impact on the average light level and overall uniformity.

#1 Check the free height

The first input parameter to check is the free height specifying the distance between the LED module and the head of the crop. The free height can seriously impact the overall uniformity value. In case of high-wire tomato crops, with a limited free height of 1.50 to 2.50m, realizing a good overall uniformity value can be a challenge. An optimistic free height or calculating uniformity on floor level as if there is no crop will positively impact the overall uniformity value.

The free height is calculated by measuring the eventual top of the crop and the mounting height of the LED grow light.

#2 Check the reflection factors

Another important parameter to check, are the reflection factors used in the lighting plan. A reflection factor indicates the amount of light that is reflected by walls and other objects in a space. DIALux calculation software has originally been designed for indoor spaces like offices, where you will get reflection off the walls, ceiling, and floors that impact the light level on your desk. To avoid being too optimistic about the outcome, the reflection values in DIALux are set at 0% for a greenhouse lighting design, because the glass in a greenhouse does not reflect the light from the grow lights.

#3 Check the area that has been used to make light intensity calculations.

The next thing to check is the defined calculation surface. The size of the calculation area and the position of the grow lights within that area will seriously impact the average amount of active photons that reaches the surface of the crop (PPFD value in µmol/m2/s). When comparing lighting design results from different manufacturers, make sure that the calculation surface shows an equal number of maximum (peaks) and minimum (dips) light intensity values. Only then you receive a realistic average PPFD value in the lighting design.

In the below example, you will see two positions of a calculation area within the same light plan, which will generate far better average light intensity values in the B situation, because the light intensity is calculated with an area that shows more grow light (peaks), and consequently less areas with the minimal amount of grow lights, which will not represent the reality after installation

Position of measurement grid defines the outcome of average light intensity

#4 Check the size of the calculation surface

Another important factor is the size of the calculation surface that will impact the overall uniformity value. When comparing lighting design results from different manufacturers, make sure the same calculation surface has been applied.

To represent a real-life situation, a calculation for the full compartment area should be made that includes the edges of the greenhouse. In case of a typical production area, a centred area is used. You may understand that a full compartment will generate lower uniformity levels, because of the lower light intensities at the edges. So, make sure you always compare either full compartments or smaller areas.

#5 Check the used uniformity

The final parameter to check is the uniformity being used. Uniformity can be expressed in different ways. When you run the DIALux lighting design software, it provides you with different types of uniformity. When comparing lighting design results from different manufacturers, make sure the same type of uniformity is applied. For a horticulture application, we prefer to express uniformity as the average light intensity divided by the maximum light intensity, which represents real-life situations best.

 In Summary

When comparing lighting designs there are lots of tweaks that suppliers can possibly make to finetune their plan. In case you want to make a proper comparison, you have to take a few parameters into account.

-       Is the specified product with the right spectrum and efficiency used in the calculations?

-       Is the right light level for your crop used and the right overall light uniformity?

-       Are the settings comparable:

o   Is the free height correctly defined?

o   Are the reflection factors set to 0%?

o   Does the measurement grid have an even number of light and dark spots in it.

o   Are you comparing full compartment or small centered area numbers?

o   And is the defined uniformity similar in the lighting designs?

 Read our other blog and learn how to evaluate the performance claims of an LED grow light.

 Grow with the pros

You want to be sure to get a rapid return on your investment and have all aspects of your project carried out professionally. With Signify, your project is in experienced hands. Signify is the global leader in the lighting sector and has built up a substantial track record in more than 1000 projects in the horticultural lighting market since 1995. This includes over two decades of dedicated experience developing tailor-made, LED-based light recipes that help growers speed up growth, increase yield and improve the quality of plants. With cutting-edge LED innovations at our command, we can custom-build a science-based solution for you.

Pascal van Megen is an application engineer at Signify with a background in mechanical engineering. As an application engineer, Pascal ensures that growers are provided with high-end horticulture lighting designs. He is providing internal and external training to customers and partners in the application of the Philips LED Horticulture products and systems. He acts as a consultant to customers and engineers, to drive continuous improvement of Philips LED lighting solutions. 

--- END ---

 For further information, please contact:

Global Marcom Manager Horticulture at Signify

Daniela Damoiseaux

Tel: +31 6 31 65 29 69

E-mail: daniela.damoiseaux@signify.com

www.philips.com/horti

About Signify

Signify (Euronext: LIGHT) is the world leader in lighting for professionals and consumers and lighting for the Internet of Things. Our Philips products, Interact connected lighting systems, and data-enabled services, deliver business value and transform life in homes, buildings, and public spaces. With 2020 sales of EUR 6.5 billion, we have approximately 37,000 employees and are present in over 70 countries. We unlock the extraordinary potential of light for brighter lives and a better world. We achieved carbon neutrality in 2020, have been in the Dow Jones Sustainability World Index since our IPO for four consecutive years, and were named Industry Leader in 2017, 2018, and 2019. News from Signify is located at the Newsroom, Twitter, LinkedIn, and Instagram. Information for investors can be found on the Investor Relations page.

"Our expansion will enable us to offer our sustainably-grown salads to more Swedish households throughout the year, so we are looking forward to an exciting time," says Andreas Wilhelmsson, CEO of Ljusgårda. 

In April, the first batch of salads was harvested in the company's new premises – and already now, Ljusgårda can deliver significantly more locally-grown salad to Swedish households, all year round. When the new 7000-m2 indoor farm, of which 2500 m2 growing area, is completed in the summer, Ljusgårda will become one of Europe's largest vertical farms. 

"We are delighted to help Ljusgårda to produce local, climate-smart salads, says Henrik Nørgaard, Nordic Commercial Director of Agriculture at Signify[1]. "Ljusgårda shares our vision of a sustainable transformation within agriculture and is focusing in particular on quality and flavor."

Supporting the expansion 
Andreas continues, "Signify has extensive experience of advanced lighting solutions and works with other large-scale indoor farms. They provide us access to lighting experts who can help us to continuously improve production. Signify is also one of the few suppliers with the capacity to deliver in line with our growth plan. Together we are expanding our facility in Sweden. Signify’s controllable light spectrum enables us to optimize the light for cultivation and produce the highest quality crops," Andreas continues.  

More than 70% of the fruit and vegetables consumed in Sweden today are imported by truck, ship, or plane from other countries. With the aim of making food production more sustainable, Swedish vertical farmer and salad producer Ljusgårda plans to increase its production 20-fold and expand its cultivation capacity to produce at least 60 tons of salads a month, which is the equivalent of around 1 million bags.

Signify is helping the Swedish vertical growers to expand their production facility in Tibro. By expanding its cultivation area from 300 m2 to 2500 m2, Ljusgårda will be able to supply fresh, locally produced salad all year round. Signify is providing the company with its latest high-tech solutions: Philips GreenPower LED production modules and the Philips GrowWise control system. These allow the light spectrum and lighting levels to be controlled, resulting in improved quality and higher yields per square meter.

As a result, Ljusgårda can ensure that its salads are tasty and nutritious. LED lighting also makes it simpler to predict growth levels, which means that it is easier for Ljusgårda to adapt its production to market demand during the season. The lighting is managed by the Philips GrowWise control system to schedule growth cycles well in advance and to allow for greater automation. 

Making an impact
Henrik adds, "This is important to Signify because of our strategic goal of helping our customers accelerate the use of sustainable farming to improve agriculture’s impact on climate change. By using the latest lighting systems in vertical farming, Ljusgårda can supply salads that meet the highest food safety standards. The right lighting also results in plants of a higher quality and a higher percentage of crops being consumed, reducing food waste.'

"Additionally, by helping Ljusgårda to grow locally we contribute to significantly reducing the food miles these salads have to travel before making it to Swedish consumers. We are therefore proudly taking part in the journey from the first green shoots to more consumers being able to enjoy Swedish salads all year round," Henrik states. 

Today, Ljusgårda's salads are sold in more than 60 ICA supermarkets, mainly in the Swedish regions of Västra Götaland and Småland. With the expansion of the facility and production on a much larger scale, Ljusgårda aims to supply sustainable Swedish salads to stores throughout Sweden.

Supporting food availability through horticulture LEDs illustrates Signify's commitment to supporting good health and wellbeing (SDG3). It is key to Signify's commitment to doubling the percentage of our revenues for brighter lives, which benefit society, to 32%. "This is part of our Brighter Lives, Better World 2025 program, which was launched in September 2020." 

For more information:

Signify

Daniele Damoiseaux, Global Marcom Manager Horticulture

daniela.damoiseaux@signify.com
www.philips.com/horti

For more information:
Ljusgårda
info@ljusgarda.se 
www.ljusgarda.se 

Sources used: 
[1] Climate-smart agriculture is an integrated approach to managing landscapes—cropland, livestock, forests, and fisheries—that addresses the interlinked challenges of food security and accelerating climate change.

11 May 2021

May 6, 2021

Myths surrounding ‘white light’ – Do you need ‘white’ light to grow better crops?

An interview with our plant specialist

·       There are several myths surrounding the specific light spectra used for growing crops and, more specifically, the use of white, green, or broad-spectrum light.

·       This article is the second in a series of interviews with Signify’s Esther de Beer, manager of the team of plant specialists at Philips Horticulture.

·       In this interview, we asked the question: Do you need ‘white’ light to grow better crops?

Eindhoven, the Netherlands – Light is perhaps the most important consideration for optimizing plant growth in a greenhouse or vertical farm. There are several myths surrounding the specific light spectra used for growing crops and, more specifically, the use of white, green, or broad-spectrum light. This article is the second in a series of interviews with Signify’s Esther de Beer, manager of the team of plant specialists at Philips Horticulture. In this interview we asked the question: Do you need ‘white’ light to grow better crops?

Interested in the first interview with Esther, where she answers the question if green light penetrates deeper into the canopy? Read it here.

First of all, what do we mean with white and green light?

When talking about light for plants, we often distinguish four basic colors: blue (400-499nm), green (500-599nm), red (600-699nm), and far-red (700-799nm). Purple light is actually a combination of red and blue light. Basically, you will get white light when you add enough green light to this red/blue light. Therefore, we will focus on the question of whether you need green light to grow better crops.

How efficient does a plant use green light for growth?

In the first interview it is explained that blue, red and green light are absorbed equally by a plant canopy and only far-red light is absorbed significantly less. But are all these colors used equally for growth?

In the early 1970’s, McCree measured the photosynthetic efficiency as a function of wavelength for a large number of plants. These data show a large commonality between the plants and has been averaged to what is now known as the “McCree curve”, see figure 1 below.

This shows that green light is used for photosynthesis, but at a lower efficiency when compared to red light. Since this early work, many researchers have found similar results. [Hogewoning 2012, Paradiso 2011]

For overall plant growth, not only the process of photosynthesis is important, but also other processes which, for instance, influence the shape of the crop. Therefore, for practical applications it is relevant to evaluate the total crop growth rather than only zooming in on photosynthesis.

So, what is the effect of green light on the crop? 

We have found that several crops have significantly higher fresh weight when actually grown without green light. For other crops, however, the amount of green light has no effect on the fresh weight. Also, we have found that to steer the shape of the crop, blue and far-red light are far more effective than green. Let me share some examples from our research.

At the Philips GrowWise Center, we have run a trial where we have grown eight RijkZwaan Salanova lettuce varieties under light spectra with both 0 and 20% green light, but with the same photon flux and percentage of blue light. The graph below shows the relative fresh weight of these crops, comparing the growth under both spectra with 0% green and 20% green light.

As you can see in this graph, not all lettuce varieties react the same. There are two varieties (RZ1 and RZ2) that grow slightly better under the spectrum with 20% green. However, most varieties have significantly higher fresh weight (even up to 20% more fresh weight for RZ8) when grown without green light.

The small effect which green light has on the growth of a crop is confirmed by an extensive academic study by Snowden, who compared the growth of 7 diverse plant species under 8 different spectral compositions: “In contrast to the significant effects of blue light, increasing green light in increments from 0 to 30% had a relatively small effect on growth, leaf area and net assimilation at either low or high PPF”. [Snowden 2016]

A second example from our own research is related to medicinal cannabis. In this trial, two different cultivars were grown under three different light spectra with 0%, 6% and 36% green at the same supplemental light level (600 µmol/m2/s).  Here, in addition to looking at the flower weight, we also looked at the quality of the crops.  

The graph on the right in Figure 3 below shows the dry flower weight for two different cultivars, whereas the graph on the left shows the percentage of active compounds, which are the key factor in determining the product quality for medicinal cannabis. 

The graph on the right shows that the dry weight remains the same for all three spectra, again confirming that the amount of green light has little effect on growth. However, the active compounds reduce substantially when the green content increases. Since these crops are grown specifically for their medicinal compounds, this leads to a preference of light spectra which contain little or no green.

To summarize: in our studies, we find that different crops require different light spectra for optimal growth. However, in most cases there is no benefit in adding more than a few percent of green; both for the yield and for the quality of the crop.

So, if green light has so little benefits, why use it?

That needs some further clarification; all of the above results describe the use of light by the crop, comparing yields at the same photon flux. However, they do not take into account how much electrical energy is needed to create this light. Since there are big differences in efficacy (mmol/Joule), this of course has a huge impact on the total energy usage. 

Red LEDs give far more photons per electrical Watt (μmol/W) compared to blue and green LEDs.

Our research shows that a spectrum with approximately 6% green light is sufficient for good color recognition by people and is 30% more energy efficient when compared to a ‘sun-like’ spectrum, which contains approximately 40% green light.    

At Signify, we want to provide our end customers with the optimal lighting solution to grow their crops in the most sustainable way. Green light is much less efficient than blue and red LEDs. Only a limited amount of green can be considered for most lighting applications as only a small amount of green light is required for good color recognition by people and as crops do not need a high amount of green light to grow well.

Esther de Beer is the manager of the plant specialist team at Signify horticulture LED solutions. She spends her days trying to make LED grow lights more effective. In this series of articles, she explains facts and fiction with regards to white light and how research has shown which light spectrum helps crops grow better.

 References:

Hogewoning S.W., Wientjes E., Douwstra P., Trouwborst G., Van Ieperen W., Croce R.  and Harbinson J., 2012.

Photosynthetic Quantum Yield Dynamics: From photosystems to Leaves. The Plant Cell 24: 1921-1935.

Paradiso, R., Meinen, E., Snel, J.F.H., De Visser, P.H.B, Van Ieperen, W., Hogewoning, S.W., Marcelis, L.F.M., 2011.

Spectral dependence of photosynthesis and light absorptance in single leaves and canopy in rose. Scientia Horticulturae 127: 548-554.

McCree, K.J., 1972.

The action spectrum, absorptance, and quantum yield of photosynthesis in crop plants. Agricultural Meteorology 9: 191-216.

Snowden, M.C., Cope, K.R, Bugbee, B., 2016

Sensitivity of seven diverse species to blue and green light: interactions with photon flux. Plos One 11(10): e0163121. Doi: 10.1371/journal.pone.0163121

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For more information:

Global Marcom Manager Horticulture at Signify

Daniela Damoiseaux

Tel: +31 6 31 65 29 69

Email: daniela.damoiseaux@signify.com

www.philips.nl/horti 

About Signify

Signify (Euronext: LIGHT) is the world leader in lighting for professionals and consumers and lighting for the Internet of Things. Our Philips products, Interact connected lighting systems, and data-enabled services, deliver business value and transform life in homes, buildings, and public spaces. With 2020 sales of EUR 6.5 billion, we have approximately 37,000 employees and are present in over 70 countries. We unlock the extraordinary potential of light for brighter lives and a better world. We achieved carbon neutrality in 2020, have been in the Dow Jones Sustainability World Index since our IPO for four consecutive years, and were named Industry Leader in 2017, 2018, and 2019. News from Signify is located at the Newsroom, Twitter, LinkedIn, and Instagram. Information for investors can be found on the Investor Relations page.

'Where in recent years vertical farming enthusiasts have perhaps been mainly qualified as hipsters with a rather expensive hobby, this new branch of horticultural sport is steadily on the rise and traditional growers are also finding their way to the multi-layer installations.'

They see opportunities in using techniques from vertical cultivation, for example in propagation. “It is not just about improving the quality of the young plants, but above all about the controllability of the cultivation, and thus the speed and quality,” says Koen with Mechatronix.

What is the most expensive greenhouse there is? That would be an empty greenhouse, and that is exactly where, according to Koen van Mechatronix, opportunities lie for vertical farming. “In lettuce cultivation you see many nurseries working with fully automated cultivation systems. With mobile gutters, they can use the available space in the greenhouse as efficiently as possible. However, it remains difficult to adjust the speed of the preliminary cultivation to the available space in the pond. By replacing traditional, unexposed or illuminated cultivation with cultivation that is more controllable in a multi-layer system, you can plan much more precisely how many plants to set up. Accurate to the day, you know how many plants are ready to go in,” he says.

The lighting company developed a multi-layer cultivation system together with Meteor Systems: an automated track, including spray booms. In the past quarter, intensive testing was already carried out with a grower who works with floating gutters. “We have 120,000 cuttings up in the test setup. Multi-layered, of course, because otherwise, it would be too expensive in terms of floor space. Now you can grow enough cuttings on a few square meters to fill 1 / 3rd of the garden,” he shows.

The controlled cultivation makes it possible to use the entire cultivation system more intensively, which shortens the payback period and the depreciation period. “You can get more heads of lettuce from your expensive greenhouse,” Koen summarizes. “In addition, you always send exactly the same quality plants to the pond, which also gives you more control over your outgrowth. If you still adhere to the correct lighting strategy, you can start making a perfect prediction on your planning. This wasn't possible before. ”

Further opportunities
In herbs there are also opportunities for hybrid cultivation, where part of the cultivation will takes in an indoor or multi-layer cultivation system and the outgrowth will take place "as usual" in the greenhouse. “In the classic, fast-growing herbs, a full indoor cultivation is soon done, but in the woody herbs it is purely the rooting that takes place in a VF installation,” says Koen. “Total cultivation is too slow for this. Your turnaround time is too long and that makes the investment per m2 too expensive, but rooting often goes perfectly in a VF system.” In the same way, plant breeders use the techniques in part of the propagation, for example, to improve healing after grafting or to speed up cultivation from mother plants. "Ultimately, propagation is about the controllability of a known phase of the propagation."

All in all, this means that there appear to be more and more surprising opportunities for vertical farming, also in Europe. “The first major projects are starting to arrive, although we also see that people here are even less familiar with the possibilities and often depict it as expensive cultivation,” says Koen. “And of course an economic assessment must always be made. It will not be the case that complete crops will be placed indoors here tomorrow - there is always a reason to look at the sun. Where possible we use the sun, and where necessary the lighting. ”

For more information:
Koen Vangorp  
MechaTronix 
koen@mechatronix-asia.com
www.horti-growlight.com

8 Apr 2021

April 6, 2021

Eindhoven, the Netherlands – Norwegian consumers are currently eating fruits and vegetables that have traveled thousands of kilometers from Southern Europe before they reach the shelves in Norwegian stores, which results in more imported food and a greater carbon footprint from its transport, compared to locally-grown crops. Now, Miljøgartneriet, Norway's largest nursery, together with its partner LOG and Signify’s horticulture LED department, are taking the first steps in shortening the farm to fork distance by growing tomatoes and peppers year-round locally, under LED lights. 

The goal is to increase opportunities for local production and reduce the climate impact that comes from importing foreign produce. Signify has supplied Philips GreenPower LED toplighting compact for the 70.000 square meter greenhouse in Naerbø, Rogaland, Norway. With LED lighting, Miljøgartneriet gets the best possible conditions in the greenhouse. This is important since the lighting affects the plants' photosynthesis, and that makes proper lighting extremely important for how well the plants grow and thrive.

For many years, Signify has studied lighting and plants and has found the perfect lighting recipe for tomatoes, peppers, cucumbers, and other fruits and vegetables. Miljøgartneriet can therefore provide the plants with the right spectrum and light intensity at the right time. In this manner, they can control growth, planning and not least of all, increase productivity.

"Many supermarket chains want to be able to offer their customers fresh and tasty fruits and vegetables with a significantly lower carbon footprint than those that come from Southern Europe. This is something we can provide all year, thanks to our cooperation with Signify," said Kåre Wiig from Miljøgartneriet. "We chose Signify because they can do more than just providing LED lighting. We have a good, close cooperation with their plant experts in order to get the most out of the lighting solution so that the vegetables get the best possible growing conditions. This means that we can easily adjust production as we get better at growing vegetables and Signify can also bring in different experts if necessary."

Miljøgartneriet has installed Philips GreenPower LED toplighting compact, in combination with the GrowWise control system. This makes it possible to dim the lights so that growers can provide even light levels throughout the day and production cycle. Growers can also dim the lights when necessary. Either to save energy or when there is sufficient daylight.

Innovation in horticulture

Miljøgartneriet starts with 1 hectare of tomatoes and 0.4 hectares of peppers,and intends to eventually expand this. The vegetables are already being harvested now and on their way to the stores throughout Norway.

Even though Signify has worked witFphilh LED lighting for greenhouses since 2012, there are many producers that are still not ready for the newest greenhouse lighting technology. Henrik Nørgaard, who is the Commercial Operations Manager for Agriculture at Signify, hopes that this cooperation with Miljøgartneriet, which is one of the leading actors in the market, can inspire other growers to install Signify Horti LED lighting and increase production.

"We are really proud that Miljøgartneriet sees the potential of cultivating with our lighting. Our lighting solutions should be seen as a cornerstone of production. We start with defining what is grown, the physical framework of the greenhouse and the production goal, and based on this we create an optimal mix of micromoles, spectrum and timing; the light recipe, together with the grower. With the solution, we can avoid the overuse of both water and electricity, as well as the environmental burden with transport from Southern Europe, and instead can get fresh, locally-produced vegetables in Scandinavia year-round," said Nørgaard.

Supporting food availability through Horti-LED illustrates Signify's commitment to supporting good health and well-being (SDG3) and is the key to their commitment to double the percentage of earnings for a brighter life that benefits society, to 32%, as part of the program Brighter Lives, Better World 2025, that they launched in September of 2020.

--- END ---

For more information, please contact:

 Global Marcom Manager Horticulture at Signify

Daniela Damoiseaux

Tel: +31 6 31 65 29 69

E-mail: daniela.damoiseaux@signify.com

www.philips.com/horti

Signify Nordics, PR Manager

Anne-Cathrine Tjørnehøj

Tel: +45 40330806

E-mail: anne-cathrine.tjornehoj@signify.com

About Signify

Signify (Euronext: LIGHT), a world leader in lighting for the professional market, the consumer market, and lighting for the Internet of Things. Our Philips-products, Interactive lighting systems, and data-activated services add value to businesses and transform private homes, buildings and public spaces. In 2020, we had sales of 6.5 billion EUR and approximately 38,000 employees in 70 countries. We utilize the full potential of light to offer a brighter life and contribute to a better world. We were carbon-neutral in 2020 and have been on the Dow Jones Sustainability World Index for four consecutive years since our listing. WE were also named Industry Leader  in 2017, 2018 and 2019. News from Signify is availabel at Newsroom, Twitter, LinkedIn and Instagram. Investor information is available on the Investor page.

17 March 2021

Posted in Blog by monique

By Abhay Thosar, Ph.D., director of horticulture services for Fluence by OSRAM

Previously published in the February 2021 issue of Inside Grower.

Population growth and urbanization are forcing global food production to a crossroads. Overall, migration to high-density areas increases access to health care, higher-paying jobs, education, and other socio-economic opportunities. But it also places more strain on existing infrastructure and demand for resources, leading to greater water scarcity, energy consumption, waste, and, perhaps most importantly, threats to the food supply, prices, and quality.

The economically disadvantaged will be the first to pay the price of increased urbanization. As prices increase and access to quality food sources decreases, the nutritional health of poor populations will decline. Over the next several years, the responsibility of bridging the gap between projected food supply and demand in urban areas will largely fall on vertical farms, an industry that is expected to nearly quadruple by 2025 to about $16 billion. The COVID-19 pandemic could accelerate that growth rate even further.

The vertical farming industry still has challenges to overcome. Production costs remain relatively high and, as a young market, knowledge gaps in operational best practices in critical areas like facility design and environmental conditions threaten long-term sustainability and profitability. The evolving economic dynamic with supermarkets is forcing vertical farms to scale quickly as they attempt to grow and supply a wider variety of crops while maintaining the buyer’s standards around produce size, quality, and nutritional value.

And, as we look to the future, new innovations in lighting strategies, facility design, cultivation best practices, and automation mean that vertical farming operations have to be constantly adapting and seeking new operational advantages. This is just as true for new market entrants and relatively established players alike, and each will be critical to not only maintaining profitability, but ensuring that food production in urban areas can increase with demand.

With that in mind, here are three critical factors vertical farmers need to consider to meet market expectations, improve efficiency and ultimately grow, cultivate and distribute larger quantities of quality food to more people in a smaller area.

Facility design as a function of market demand

The history and growth of the vertical farming market are largely driven by two trends at the consumer and buyer levels. A decade ago, consumers asking questions about how, where, and when their food was grown was practically unheard of. Things are different today. People want to know the provenance behind the food they buy and ensure it is chemical-free and safe to eat. Every product has become more than a label, it’s become a story that consumers want to hear, and one that has an equally significant impact in where they shop and what they buy.

Supermarkets have taken notice. Beyond that, though, vertical farming operations have given supermarkets one more option in addition to the existing supply chains on which they’ve relied for food production and distribution. Vertical farms play an even more important role during large-scale disruption events like the COVID-19 pandemic or massive recalls. As a result, supermarkets—which value the consistent supply of produce above all—are turning to their local vertical farming operations and, in some cases, even investing in them directly. The increased attention, however, comes at a cost (literally and metaphorically). Supermarkets are demanding that the vertical farms supplying them grow a wider variety of crops—lettuce, tomatoes, cucumbers, leafy greens, microgreens, herbs—more consistently while also meeting unique specifications around weight, aesthetic, nutritional value and a variety of other factors that are ultimately dictated by the vertical farm’s environment and the grower’s expertise.

Vertical farmers are quickly realizing they need to expand their portfolio from potentially a handful of crops to a few dozen or more, raising a range of questions on how to design or retrofit their facilities and adjust environmental conditions that favor any given crop.

The first decision many vertical farmers face is the growing technique that will be most scalable and viable for their operation. Hydroponics, aeroponics and aquaponics have all emerged as viable options with varying degrees of success, but they’re far from interchangeable.

In the end, there is no universal solution for every vertical farm. Cultivators should closely consider their buyers’ expectations, and how those expectations might change over time. Then, cultivators must assess the full range of their crops’ needs and how each might respond differently to various environmental factors and lighting strategies.

Strike a balance between environmental factors

The next set of factors governing facility design, investment and day-to-day operations should always be the environmental conditions themselves.

How air flows into and across each rack of a vertical farm is one of the most unique and important challenges vertical farms have to solve. Ignoring or failing to closely monitor airflow is often a death blow to entire sections of crops and to profitability, yield, and consistency as a result. Air movement helps to maintain temperature, humidity, and transpiration at each rack, and lack of it creates wide temperature swings or large gaps between crops at the bottom and crops at the top. It’s an incredibly fragile balance to strike. Everything from the number of access points into a warehouse—there should only be one access point—to HVAC and circulation systems affect air movement.

As a best practice, the maximum difference between the temperature at the top-most rack and the bottom-most rack should be no more than two degrees Fahrenheit. In practical scenarios, cultivators facing large temperature fluctuations can also consider placing crops that prefer relatively warmer temperatures—such as basil, oregano, chives, sage or thyme—at the top and simply let the laws of thermodynamics do the rest.

Carbon dioxide enrichment is a slightly easier condition to manage but no less important and changes based on temperature and lighting strategy. CO2 enrichment, too, can fluctuate based on the number of access points into a warehouse (again, there should only be one). Enriching a cultivation environment with carbon dioxide stimulates photosynthesis and plant growth, the rate of which is critically dependent on the difference between CO2 concentrations in the air and in the leaf cells.

The law of diminishing returns puts a cap on the amount of carbon dioxide cultivators should be introducing. CO2 is by no means the only factor governing plant growth, but vertical farms have the advantage of being able to closely monitor and control CO2 levels. To do so properly, however, they shouldn’t shy away from significant investments in both handheld devices—which allow cultivators to measure carbon dioxide levels at each rack, each plant, and each leaf—but also large-scale control systems that can measure and track CO2 throughout the entire warehouse.

Humidity levels govern a plant’s transpiration rate and the aperture sizes of its stomata, ultimately affecting how much water it moves from its root zone to release back into the warehouse. When a plant’s stomata open, they release water while also collecting carbon dioxide, making the balance of humidity, temperature, and carbon dioxide all the more crucial. Different plant types in different growth stages have different transpiration rates, adding even more complexity to how a vertical farm is designed and managed. The most common way to express humidity is relative humidity, the percentage of water vapor in the air at a given temperature compared to the total amount of water the air can hold at that temperature. In vertical farming, however, vapor pressure deficit (VPD) is the more accurate way to gauge humidity’s effect on plant growth. VPD remains an interesting discussion among researchers as the industry seeks to understand the differences between VPDs for air and leaves as well as exact VPD calculations.

Every environmental factor in a vertical farm affects the others to some degree. Nearly everything can be controlled; it’s both the advantage and the challenge native to the market. No factor, however, is more important to photosynthesis than its primary driver: light. Each factor—CO2, temperature, airflow, humidity, fertilizer, irrigation, VPD—need to be fine-tuned with changes to light quantity and quality to optimize plant performance and response.

Designing an effective lighting strategy

The design and implementation of an effective lighting strategy is and always will be the primary driver of your vertical farm’s success. In environments as complex as vertical farms, identifying the correct light intensity, spectra, photoperiod, and configuration will determine how other environmental factors work together to optimize a facility for plant yield and quality.

The first of these, the fixtures themselves, carry more implications for vertical farms than other cultivation spaces; in a vertical farm, plants receive no other source of light. The sun isn’t the safety blanket that it is for greenhouses. This simple and obvious fact means that vertical farmers have to find efficiencies in ways others don’t, which can manifest across a variety of operational metrics. Light efficacy, for instance, becomes more important. Most vertical farms are located in urban areas and are likely paying a premium for electricity. Maximizing micromoles per watt and reducing energy waste becomes more than a sustainability initiative, it’s critical to overall profitability.

Similarly, vertical farms operating warehouses measuring in the tens of thousands of square feet need fixtures with a good form factor without sacrificing light intensity. The right configuration means vertical farms can squeeze more racks into their facilities while also putting the lights closer to the plants for better results.

Beyond the hardware specifications, lighting design and strategy consist of several key factors: light intensity, light quality (or spectra), and light bar configuration. Each should be rooted in a facility’s overarching goals—typically defined by the consumer or buyer. Lighting strategies can be customized by crop, yielding specific plant chemistries or changes in biomass. Differences in spectra and light intensity can affect a crop’s coloration, shelf life, taste, and smell. Desired crop characteristics should be determined upfront in conjunction with the prospective buyer, therefore guiding a lighting designer to identify the optimal strategy to accomplish a facility’s goals.

Light quantity is the first and foremost aspect when it comes to optimizing the productivity of the crop. It is important to target the correct mols/day for each crop. Light quality (or spectra) is defined by measuring light’s wavelength in nanometers (nm). Wavelengths of light that drive photosynthesis are primarily found within 400 to 700nm—a range identified as photosynthetically active radiation (PAR). In a vertical farming environment, broad, white light has proven effective for tissue culture, propagation, and vegetative growth—while also serving the more practical function of making it easier for human eyes to diagnose and observe crops day in and day out. As the body of research into LED applications has expanded, it’s become clear that lighting strategies need to shift based on the growth stage. The days of bombarding plants with the same intensity and spectra are quickly fading. More and more research is showing that different cultivars respond to different lighting strategies at different stages of their maturation. More nuanced, customized lighting strategies are increasingly leading to tangible business outcomes for cultivators: longer shelf life, improved aesthetic, enhanced nutritional value, faster cycle times, and higher yields.

LED improvements will continue to drive costs down, while more in-depth research will discover and confirm a new set of lighting strategies and operational best practices to help vertical farmers meet future market demand for increased food production while also improving profitability. Overall, the future for vertical farms is bright and ripe for even broader innovation. Automation—the final frontier of food production—will mean even greater control of agricultural environments. That future is on the horizon. For now, though, vertical farms just need to stick to what they can control, which is pretty much everything else.

About Abhay

Abhay Thosar is the director of horticulture services at Fluence by OSRAM, where he is responsible for managing a team of horticulture specialists that enhances how cultivators grow their crops, optimize their lighting strategies and increase profitability in their operations. He holds a Ph.D. in plant physiology from Gujarat Agricultural University and spent more than a decade at leading greenhouses and nurseries throughout the U.S.

More and more LEDs are going from purple to white. Is there any difference among the countless white LED light options on the market, in addition to fluorescent? Cool white, warm white, full-spectrum white, fluorescent, white with UV and far red, etc. How to evaluate these choices? 

In this free webinar, we break down the differences among different types of white horticultural lighting. We will present the results of comparative plant trials we conducted using a variety of our own and other LED providers’ luminaires.

Spectra appearing white to human eyes contain a variety of spectrum colors, including green. Humans can distinguish them in terms of their temperature (e.g. warm white and cool white) and CRI (color rendering index) which determines how realistic objects appear under them.

Plants however can have dramatically different reactions to light that appear nearly the same to us. The example here shows the difference in biomass accumulation from three light sources that look exactly the same!

This webinar is aimed at growers and researchers trying to understand which kind of light to illuminate their growth chambers, indoor farms, and greenhouse compartments with.

Register for the webinar here.

Contact Valoya sales here - sales@valoya.com 

About Valoya

Valoya is a provider of high-end, energy-efficient LED grow lights for use in crop science, vertical farming, and medicinal plant cultivation. Valoya LED grow lights have been developed using Valoya's proprietary LED technology and extensive plant photobiology research. Valoya's customer base includes numerous vertical farms, greenhouses, and research institutions all over the world (including 8 out of 10 world’s largest agricultural companies).

Additional information:

Valoya Ltd, Finland

Tel: +358 10 2350300

Email: sales@valoya.com

Web: www.valoya.com

Facebook: https://www.facebook.com/valoyafi/

Twitter: https://twitter.com/valoya

Part 2 of 5] This is the second post in a 5-part series on the differences between vertical farms and greenhouses, and the considerations that will help farming entrepreneurs decide which is right for their situation.

Last week, in the first article of this series, we discussed the basic differences between vertical farms and greenhouses, including why location is such an important factor in the decision. In short: The location of a farm governs how much space will be available for it, and the source of the energy it will use.

That last part is what you might call “the elephant in the room” when it comes to indoor farming: Energy demand, and the main reason we care about it – carbon emissions. So let’s talk about that today.

Carbon Footprint Factors: Electricity (But Not Only)

One of the leading critiques of vertical farming is that replacing natural sunlight and open-air with LED bulbs and climate control requires electricity – lots of it.

“If the source of the energy is not renewable,” points out Henry Gordon-Smith, the CEO of Agritecture, an independent consultancy that helps clients decide between vertical farms and greenhouses, “Then vertical farms have enormously more carbon footprint than greenhouses.”

But the opposite is also true – where renewables are available, vertical farming can greatly reduce the carbon footprint of foods that are normally trucked long distances, or flown in from overseas.

For example, “Norway could be huge for vertical farming, because they just have so much cheap, renewable energy,” Gordon-Smith suggested.

When you tally the emissions reductions from shorter transport distances, the reduction in fertilizer use (fertilizer production is highly carbon-intense, and Controlled Environment Agriculture uses it much more efficiently than outdoor farms), plus the reduction in food waste, it’s clear that artificial light and conditioned air inside vertical farms are not the only carbon footprint factors to consider.

Bringing the Sun Indoors: Changing Electricity Costs for Farms

Lighting is one of the biggest expenses for a vertical farm, for obvious reasons – each layer in the farm needs its own LED “suns.” Agritecture Designer, a consulting software created by Gordon-Smith’s company, estimates the need at roughly 10 LEDs per square meter.

That’s a useful figure to get started, but given the variability between types of LEDs, a more precise estimate would be about 100 watts of LED power per square meter, according to Gus van der Feltz, another CEA industry expert. Van der Feltz is a co-founder and Board Member of Farmtech Society in Belgium, and project leader for Fieldlab Vertical Farming in the Netherlands.

With these lamps operating 12 to 18 hours a day in most vertical farms, the power usage from LEDs accounts for 50 to 65% of the electricity bill.

The exact amount depends on several factors: The relative efficiency of the LEDs used, compared with the efficiency of other systems in the farm (such as climate control), as well as the light requirements of each individual crop. (For example, the total electricity required for growing light-loving strawberries in an iFarm, for example, is about 117 kWh per month for each square meter of growing space, while arugula needs only about 52 kWh.)

But whether you opt for a greenhouse or a vertical farm, you’ll be growing local produce, which means your farm may be eligible for subsidies or another form of reduced electricity rate. Be sure to check with your local government and electricity providers.

It’s also important to note that greenhouses increasingly rely on LEDs as well, especially during winter in northern climates.

This may be only supplemental light, and it will vary with the location, seasonality, and how much light each crop requires – but greenhouses are still not as energy-intensive as vertical farms.

“It takes a lot of energy to produce food (with vertical farms),” says Ramin Ebrahimnejad, vice-chair of the Association for Vertical Farming, and an expert on multiple types of urban farming.

“But,” he adds, “most vertical farms in the developed world already use renewable energy. In the long term, that’s not going to be a challenge for the industry”.

As our electricity sources become more renewable (and as LED technology improves, as we’ll discuss below) energy-intense vertical farming will become both more sustainable – less carbon-intense – and more affordable.

And we can see this evolution happening in real-time: In 2020, Europe produced more electricity from renewables than from fossil fuels for the first time.

The Cost of LEDs for Vertical Farms vs Greenhouses

LEDs themselves are another major OpEx factor in vertical farming. And even though the cost per bulb varies widely, along with the efficiency, the LEDs in a vertical farm generally have to be replaced every five to 10 years, according to the Agritecture Designer software.

However, just as the cost and carbon footprint of electricity are becoming less of a hurdle for indoor farms, the LED situation is also evolving quickly.

An idea that’s become a modern certainty is that technology gets cheaper over time. As the environmental economist William Nordhaus studied in the 1990s, the declining cost of light over the centuries – from candles, to oil lamps, to ever-more-efficient light bulbs – has been changing the world and fueling innovation for millennia.

Something similar is happening with LEDs – up to a point. Moore’s Law famously predicted computing power doubling every year, and Haitz’s Law now forecasts that the cost per lumen for LED light will fall by a factor of 10 each decade, while the light produced increases 20-fold.

However, as Van der Feltz points out, this cannot continue forever and is more limited by the laws of physics than Moore’s Law. Currently, a well-designed horticultural LED system can be up to about 55% efficient – meaning 55% of the energy put in becomes photons, which plants use to grow, and 45% becomes heat. Fifty-five percent efficiency is already impressive when compared with incandescent light bulbs, for example, where energy input produces 5% light and 95% heat.

But still, for the purpose of CEA and especially in vertical farms, the remaining 45% of the energy that becomes heat is often – though not always – useless.

“In greenhouses,” Van der Feltz explains, “the additional heat is typically not all bad. Especially since auxiliary greenhouse lighting is mostly used in the darker and cooler winter months, and there are usually plenty of options for ventilation in case it gets too warm.”

But vertical farms heat up quickly, and as closed systems where opening a window is not an option, any extra heat from LEDs must be balanced with air conditioning or creatively repurposed. Van der Feltz says some indoor farms have been designed to divert excess heat to warm an adjacent building, for example.

So LED performance can still improve marginally, but not exponentially. Van der Feltz says experts estimate that another 25% efficiency improvement is possible, but LEDs will never be able to produce light energy out of thin air.

Whatever the limits of Haitz’s Law, it’s still true that while electricity and LED light bulbs are the most expensive part of a vertical farm today, they’re also the area where improvement is most imminent. (Innovation, and the laws of supply and demand, are constantly bringing down the costs of both, regardless of how much efficiency improvement is still technologically possible.) So operating a vertical farm should still become increasingly affordable over time.

Improved technology and reduced costs for LEDs are especially good news for the potential to grow even more crops in vertical farms, as different plants use different parts of the light spectrum.

iFarm is already a leader in the industry when it comes to research and development for expanding the crop selection available to vertical farmers. As LED technology improves, we’ll be able to take those efforts even further.

Other Energy Costs: Climate Control Needs in Vertical Farms vs. Greenhouses

The high energy costs of lighting a vertical farm are obvious, but the demands of climate control are often not as clear.

Since vertical farms are closed systems, with little to no air exchanged with the outside, they must be constantly cooled and dehumidified. About 20% of the electricity used on a vertical farm is for air conditioning, while dehumidifiers account for 10%.

The need for both of these increases with each layer added to a vertical farm, in order to counter the effects of plants transpiring and increasing the heat and humidity of the system.

In temperate regions, greenhouses can save energy by using natural ventilation, as the Agritecture Designer program explains: Sidewalls can roll up to allow cool air in, while hot air escapes through vents at the top of the greenhouse. Greenhouses can also opt for an evaporative cooling system, which is still more energy efficient than a fully climate-controlled system but does add humidity – another element to be controlled.

But it’s also important to remember that greenhouses are more sensitive to outside temperatures, and therefore, the operational expenses of climate control and/or the time needed for crops to mature will vary more than they will with vertical farms – especially in cold, Northern climates.

Next, in Part 3, we’ll discuss additional cost considerations for vertical farms and greenhouses, beyond electricity.

To learn more about starting a profitable vertical farming business, reach out to our friendly team at iFarm today!

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09.03.2021

Five Years of Feeding Tomorrow’s Cities

Ellis Janssen, Director city farming at Signify explains: “At the GrowWise Center, we believe in vertical farming. Over the past five years, we have helped hundreds of entrepreneurs and pioneers all over the world discover how they can feed tomorrow’s cities and grow plants faster, in a more sustainable way."

Jarno Mooren, Signify's plant specialist vertical farming with tomato crops cultivated at the GrowWise Center

"We work closely with our customers and partners, looking at all aspects of the business case: whatever a grower’s needs are, we can translate them into a dedicated recipe for growth. To achieve this, our team of plant specialists, application engineers and key account managers look at the most important aspects that determine the set-up of a farm so they can give the grower dedicated advice in making the best decisions," Ellis states.

She adds, "We have learned a lot over the past five years, and as we are evolving our customers are evolving as well. They want the best solutions for their specific needs. At the GrowWise Center, we support them wherever we can. The world continues to change, and we will change along with it. Through this all, and by combining the latest technology, business insights and plant expertise, we can help growers make their business successful and future-proof."

"At the GrowWise Center, we are proud of all that has been accomplished in vertical farming over the past five years, and we are excited to see where we can take the dreams and ambitions in vertical farming in the future," Ellis notes.

Global Marcom Manager Horticulture at Signify

Daniela Damoiseaux

Tel: +31 6 31 65 29 69

E-mail: daniela.damoiseaux@signify.com

www.philips.com/horti

About Signify

Signify (Euronext: LIGHT) is the world leader in lighting for professionals and consumers and lighting for the Internet of Things. Our Philips products, Interact connected lighting systems and data-enabled services, deliver business value and transform life in homes, buildings, and public spaces. With 2020 sales of EUR 6.5 billion, we have approximately 38,000 employees and are present in over 70 countries. We unlock the extraordinary potential of light for brighter lives and a better world. We achieved carbon neutrality in 2020, have been in the Dow Jones Sustainability World Index since our IPO for four consecutive years and were named Industry Leader in 2017, 2018, and 2019. News from Signify is located at the Newsroom, Twitter, Linked In, and Instagram. Information for investors can be found on the Investor Relations page.

By Mike Martens, Senior Manager, Illumination Marketing at Osram Opto Semiconductors, North America

The global pandemic has turned the world upside down, bringing unprecedented change to the way we live, work and play. But the crisis has also paved the way for important new innovations. For instance, massive disruption to the global supply chain is now compelling many nations to ramp up their indoor and urban farming efforts to secure their food supply and feed their people.

Take the desert nation of the United Arab Emirates. Amid the ongoing pandemic, the country is experiencing something of a food crisis. That’s why it recently announced a $100 million investment in cutting-edge indoor farming facilities that can help feed its population. The effort will include the creation of the world’s largest vertical farm to help solve the challenge of local food production.

A key component of vertical farming is LED technology. In places across the globe where farmland is limited, innovative LED lighting solutions offer a major advantage because they can provide the exact light composition that various plants need for ideal growth or to develop certain characteristics. Plants can also be grown in a very space-saving manner and with considerably higher yields thanks to these lighting solutions.

LEDs are more efficient

For decades, traditional high-pressure sodium (HPS) lamps were commonly used for greenhouses and other horticultural purposes but they bring with them many challenges. They have a short lifespan and are often only suitable for top lighting in greenhouses due to their high heat output.

This is a big problem for greenhouse owners because efficient energy use is essential to economic production. In traditional greenhouse and urban farming setups, HPS lights are often inefficient. They do provide light for plants, but it is often not the most efficient wavelength range because the lamps cannot be customized to provide ideal growing conditions for different types of plants.

HPS lights often generate a lot of heat , causing considerable evaporation and ultimately limiting crop yield. What’s more, due to this heat production, HPS fixtures often cannot be placed very close to plant canopy, preventing more efficient vertical-farm setups. After all, you don’t want to singe your produce.

The good news is that innovative LED technologies can alleviate many of these concerns. For starters, LEDs produce almost no radiated heat, allowing for the light fixtures  to be placed closer to plants and for plants to be stacked much higher, enabling farmers to grow more produce in smaller spaces while simultaneously reducing water costs.

LED lights also offer customizable wavelengths for different plants’ needs, allowing greenhouse operators and urban farmers to grow specific plants in their optimal conditions. For instance, LEDs can be tailored to supply light with a higher amount of red or blue content, generating exactly the wavelengths the plant, such as iceberg lettuce, tomatoes and basil need for optimal growth.

Urban farming is not a new phenomenon, but LEDs have the power to take it to the next level and more efficiently feed the world. In terms of sheer numbers, LEDs have an average lifespan of 50,000 hours compared to 8,000 hours for HPS lamps, making LEDS much more economical (and better for the environment). Indeed, vertical farms that leverage LED technology can achieve 40% energy savings compared to traditional lighting methods like HPS lamps. And due to the optimized light spectrum at 450, 660 and 730 nanometers, LEDs can provide the perfect lighting for all types of plants, allowing growers to adjust the lighting exactly to the needs of various crops.

LEDs grow healthier produce

LED are the most efficient lighting technologies to date for growing produce. They not only help produce fresh food in smaller spaces without the use of pesticides, they also make it easier for consumers in urban areas to obtain fresh and healthy food quickly, a must, considering the planet’s ever-growing population and ever-decreasing farmland.

Consumers in urban areas often rely on produce grown in faraway places that is brought to them on trucks using fossil fuels. This produce is often grown with pesticides to keep insects away, as well as fertilizers, so plants can be grown throughout the year, even in suboptimal conditions. All of these factors contribute to climate change and more polluted water sources. With horticultural LEDs,  these issues can be mitigated.

LEDs also provide optimal growing conditions in any environment with minimal water waste, while reducing the need for pesticides in indoor growing environments. Communities then have the ability to grow produce closer to home, which allows consumers to learn more easily what exactly goes into their food and greatly reduces the fossil fuel usage to get produce from the (urban) farm to their tables. Urban farming has great potential to make positive impacts on local environments and communities. It’s more sustainable and decreases communities’ reliance on foods shipped in at great cost from around the globe.

LEDs light the way

As we grapple with the many concerns facing our modern society, it is imperative to invest in efficient and time-saving technology of all types. LEDs are one of these technologies. Indeed, they light the way to the farms of the future. They will have an enormously beneficial impact on agriculture by dramatically increasing crop production and putting food on every table more efficiently.

The lighting company LumiGrow has ceased operations and is now out of business. 

LumiGrow was a company focused on LED lights, and it hit the headlines at the beginning of 2020 for the purple glow that illuminated the sky over Navajo County, Arizona, which was coming from a cannabis greenhouse where LumiGrow LEDs were installed. 

The company has not shared specific information as to why operations have been ceased. For sure, the global pandemic together with the fierce competition in the LED sector of horticulture have had an impact. 

Publication date: Tue 2 Feb 2021

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