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− | <p class="about-para">Adaptability was a major issue with the existing plant growth infrastructure within the University and, in fact, with many traditional growth facilities. We designed the NH-1 to combat this. The NH-1 is controlled entirely by an Arduino micro-controller. The Arduino offers a low-cost, easy-to-use solution to control and adapt the function of the LEDs. The Arduino also offers an open-source electronic prototyping platform and offers plenty of opportunities for further development of the NH-1, in terms of user interface and interaction. All the code and the IDE are freely available online and the UNO board can be purchased online from Arduino for less than £20. The Arduino language is based on C/C++ so it is incredibly easy to become familiar with, especially if you already have experience with C/C++ but if not there is a wealth of resources online that can help with this. We have designed a guide to using the IDE and included some examples of the capabilities of the NH-1. Some of the features that you can incorporate include:</p> | + | <p class="about-para">Adaptability was a major issue with the existing plant growth infrastructure within the University and, in fact, with many traditional growth facilities. We designed the NH-1 to combat this. The NH-1 is controlled entirely by an Arduino micro-controller. The Arduino offers a low-cost, easy-to-use solution to control and adapt the function of the LEDs. The Arduino also offers an open-source electronic prototyping platform and offers plenty of opportunities for further development of the NH-1, in terms of user interface and interaction. All the code and the IDE are freely available online and the UNO board can be purchased online from Arduino for less than £20. The Arduino language is based on C/C++ so it is incredibly easy to become familiar with, especially if you already have experience with C/C++ but if not there is a wealth of resources online that can help with this. We have designed a <a href="https://static.igem.org/mediawiki/2018/f/f1/T--Newcastle--SoftwareGuide.pdf">guide to using the IDE</a> and included some examples of the capabilities of the NH-1. Some of the features that you can incorporate include:</p> |
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<li>Solid colours across the system</li> | <li>Solid colours across the system</li> |
Revision as of 12:25, 25 September 2018
Alternative Roots
Software
NH-1
Software
Adaptability was a major issue with the existing plant growth infrastructure within the University and, in fact, with many traditional growth facilities. We designed the NH-1 to combat this. The NH-1 is controlled entirely by an Arduino micro-controller. The Arduino offers a low-cost, easy-to-use solution to control and adapt the function of the LEDs. The Arduino also offers an open-source electronic prototyping platform and offers plenty of opportunities for further development of the NH-1, in terms of user interface and interaction. All the code and the IDE are freely available online and the UNO board can be purchased online from Arduino for less than £20. The Arduino language is based on C/C++ so it is incredibly easy to become familiar with, especially if you already have experience with C/C++ but if not there is a wealth of resources online that can help with this. We have designed a guide to using the IDE and included some examples of the capabilities of the NH-1. Some of the features that you can incorporate include:
- Solid colours across the system
- Cyclically varying colours (rainbow) in the system
- Linear gradients of colours across the system
- Colours can be defined by RGB, HSV values or HTML standard
- Brightness can be varied, for example to simulate a day/night cycle or a gradual sunrise/sunset
The list goes on as the possibilities with the NH-1 are incredibly varied. This makes it the ideal system for plant-based experimentation, with the added bonus that the system is completely contained and portable. The end result is a highly adaptable, semi-autonomous system that is simple to code and even easier to run.
Additional Support
ACKNOWLEDGEMENTS
We would like to thank these people for helping us along the way. We have been supported by people from a diverse range of disciplines in every aspect of our project.Induction Talks
- Dr. Jem Stach
- Dr. Jon Marles-Wright
- Dr. Thomas Howard
- Dr. Kenneth Taylor
- Dr. Harold Fellermann
- Dr. Martyn Dade-Robertson
- Professor Rachel Armstrong
- Professor Phillip Wright
- Dr. Dana Ofiteru
- Dr. Maxim Kapralov
- Dr. Angel Goni-Moreno
- Dr. Nicholas Aldred
- Dr. Vasilios Andriotis
- Dr. Ilke Turkmendag
Subject Specific Support
- Dr. Alice Banks (Chemotaxis)
- Dr. Maria Del Carmen Montero-Calasanz (Endophyte Development)
- Bradley Brown (Wiki Development/Community Modelling))
- Josh Isaac (Biosynthesis Pathway Modelling)
- Aidan Clamp (Biosynthesis Pathway Modelling)
- Connor Barker (Biosynthesis Pathway Modelling)
- Dr. Martyn Dade-Robertson (Human Practices)
- Professor Rachel Armstrong (Human Practices)
Stakeholder Engagement
- Professor Chris Tapsell (KWS Seeds)
- Richard Ballard (Growing Underground)
- Steve Dring (Growing Underground)
- Tom Webster (GrowUp Urban Farms)
- Nicola Cowell (Food Nation)
- Paul Brown (GrowModule 365)
- Clive Goodwin (Victoria Tunnels)
Newcastle University Farms
- Dr. Ankush Prashar
- James Standen
- Rachel Chapman
Our Sponsors
SPONSORS