PRE2020 4 Group6
| Members | Student ID | Faculty | |
|---|---|---|---|
| Marijn Borghouts | 1449532 | BMT | m.m.borghouts@student.tue.nl |
| Bert de Groot | 1459597 | ME | g.d.groot@student.tue.nl |
| Nando di Antonio | 1465325 | ME | n.z.d.antonio@student.tue.nl |
| Dorien Duyndam | 1305107 | EE | d.a.duyndam@student.tue.nl |
Subject
Idea
The idea is to create a smart plant system that would notify the user if it needs either water or more or less sunlight. The target group is a social work space (zorgboerderij) for mentally disabled people. They can see or hear which plant needs attention and get that plant what it needs. The social workers will therefore do something useful which is very great for such people. The people monitoring this social work space will also get a great work relief because of this system because they don’t have to tell these people what to do with the plants anymore. The plant pot will probably get a nice face so that it looks like a friendly robot and it will get water sensors implemented in the soil and light sensors around the plant to monitor the amount of light the plant gets. The pot will also be able to notify when it is being moved or given water and will start saying nice things to the person moving it or giving it water.
USErs
User
The main target group for this product is people with a mental disability. The product is designed to help the users overcome some of the challenges that they face due to their disability. "Mental disability" is a very broad term and can out itself on a whole spectrum of problems, ranging from difficulty with speaking to recognising emotions. For the sake of making a more tailored product, we have decided to focus on people with Down syndrome. This decision allows us to gather more specific needs and requirements from the users (which can be found in its own section).
Our robot will notify the user by speech when a plant needs more or less water, or more or less sunlight. This way the product helps the user take care of a plant without having to do complex tasks like remembering when and how often a plant needs water or sunlight. Our robot gives simple, chopped up clear instructions so that the user knows what is being expected from him/her. After a task is completed, the robots will give confirmation in the form of positive feedback to the user. This helps assure the user that a task has been successfully completed. This way our product makes caring for plants more accessible for people with Down syndrome. which has all types of benefits (see Sources XXXX)
The secondary users are the caretakers. The product is meant to be used by people with Down syndrome but is meant to be bought and installed by the caretakers. This device helps relieve workload from the caretakers by automating a part of the managing and task distribution process in a social work environment. Therefore it is important to always be mindful of who the users of specific functions is and what their needs and capabilities are.
Society
Some say that a society is measured by how it treats its weakest members (famous misquote NOT by Ghandi {Does this need an extra source?}). We realise that our product will not solve any world crisis or drastically improve the farming capacity of social workspaces, but it helps people who need a little bit more care. Our robot allows people with Down syndrome to more easily perform work, giving them a way to spend their day and make themselves (somewhat) useful. This benefits society by allowing better participation across all layers of society and show empathy and care toward those who need it the most.
Secondly, this helps relieve some of the workload of social caregivers who are often overworked. Financing for this sector generally low {does this need a source?} and our product might save some valuable time by automating some simple repetitive tasks.
Enterprise
This product of course has to be developed and manufactured. This creates jobs and potential revenue which is all good for the economy. Products of these types do already exist (see sources XXXX) but there are mainly focused on increasing greenhouse yield. This product has a different goal and is therefore unique enough to not have to deal with fierce competition in the market, giving it a fair shot at succeeding in our opinion.
Plan
Week 1
- Come up with an idea (all)
- Make the planning (Bert, Nando)
- Find relative papers (all)
- Decide who the USErs will be (all)
- Research about why it is good for the users (all)
| Name | Total hours | Tasks |
|---|---|---|
| Marijn | 10 | Group formation(0.5), watched lectures(0.5), done research about the subject(3), searched for sources about the subject(4), edited the cstwiki(2) |
| Bert | 10 | Group formation(0.5), watched lectures(0.5), done research about the subject(3), searched for sources about the subject(4), edited the cstwiki(2) |
| Nando | 10 | Group formation(0.5), watched lectures(0.5), done research about the subject(3), searched for sources about the subject(4), edited the cstwiki(2) |
| Dorien | 10 | Group formation(0.5), watched lectures(0.5), done research about the subject(3), searched for sources about the subject(4), edited the cstwiki(2) |
Week 2
- List the needs this user requires (Marijn, Dorien)
- Research about possible components (Nando, Bert)
- RPC list (Dorien, Marijn)
| Name | Total hours | Tasks |
|---|---|---|
| Marijn | hours | tasks |
| Bert | hours | tasks |
| Nando | hours | tasks |
| Dorien | Hours | tasks |
Week 3
- Design an electrical circuit (Bert)
- Make a start on the design of the pot (Dorien, Nando)
- Start working on the code (Marijn, Nando)
| Name | Total hours | Tasks |
|---|---|---|
| Marijn | hours | tasks |
| Bert | hours | tasks |
| Nando | hours | tasks |
| Dorien | Hours | tasks |
Week 4
- Start with the CAD design of the pot (Nando)
- Continue working on the code (Marijn, Bert, Dorien)
- Start testing the electrical components (Dorien, Bert)
| Name | Total hours | Tasks |
|---|---|---|
| Marijn | hours | tasks |
| Bert | hours | tasks |
| Nando | hours | tasks |
| Dorien | Hours | tasks |
Week 5
- Adjust the code according to the test results (Bert, Nando)
- Test again (Marijn, Dorien)
- Build a prototype (all)
| Name | Total hours | Tasks |
|---|---|---|
| Marijn | hours | tasks |
| Bert | hours | tasks |
| Nando | hours | tasks |
| Dorien | Hours | tasks |
Week 6
- Upgrade the code again (Marijn, Bert)
- Adjust things to the prototype according to the test results (Nando, Dorien)
| Name | Total hours | Tasks |
|---|---|---|
| Marijn | hours | tasks |
| Bert | hours | tasks |
| Nando | hours | tasks |
| Dorien | Hours | tasks |
Week 7
- Work on the cstwiki (all)
- Work on the design and start on the product (all)
- Start working on the final presentation (all)
| Name | Total hours | Tasks |
|---|---|---|
| Marijn | hours | tasks |
| Bert | hours | tasks |
| Nando | hours | tasks |
| Dorien | Hours | tasks |
Week 8
- Finalize the cstwiki (all)
- Finalize the design and the product (all)
- Finalize the final presentation (all)
| Name | Total hours | Tasks |
|---|---|---|
| Marijn | hours | tasks |
| Bert | hours | tasks |
| Nando | hours | tasks |
| Dorien | Hours | tasks |
Approach
The approach will be as follows. Firstly, a literature study will be held in order to increase the knowledge about the subject and to find arguments in support of or against the project . Secondly a prototype will be made, this should resemble the final product quite closely. The prototype will consist of mechanical parts with the implementation of software. Lastly, the prototype will be adjusted to better resemble a final product in looks and performance.
Deliverables
- The first deliverable will be this wiki page. It logs our progression and helps the tutors and other people with an interest in our project to follow the progression of the project.
- The second deliverable will be our physical prototype of the greenhouse climate management system.
- The third deliverable is the final presentation, in which we present our project for our teachers and peers.
Milestones
- 1: Literature study
- 2: Make an RPC list
- 3: Make a BOM list
- 4: Ordering of the parts
- 5: Software development
- 6: Making the prototype
- 7: Make the final design
- 8: Finalise the wiki page
Objectives
Cost efficient/Affordable
The prototype should make optimal use of the available resources. Furthermore the components and assembly process should be as cheap as possible to reduce the total production cost, making the design cheaper for users (or obtaining a bigger profit margin for the vendor)
Easy to use
The prototype should be easy to install and operate. This is especially important considering the target audience of mentally handicap people. This product is designed to help these people with doing more complex tasks. If the operation of the product is not extreme straight forward it will only work counter effectively.
Friendly/Positive reinforcement
We want the product to interact nicely with the user. The product should communicate with the user in a friendly manner and compliment the users when they perform an action. This makes the product more pleasant to use and the explicit positive reinforcement confirm to the mentally disabled people that they are in fact doing a good job.
State of the art
Section one: sources on existing smart greenhouse control systems
[1] Abbassy, M. M., & Ead, W. M. (2020). Intelligent Greenhouse Management System. 2020 6th International Conference on Advanced Computing and Communication Systems, ICACCS 2020. https://doi.org/10.1109/ICACCS48705.2020.9074345
This paper mentions an robotic intelligent greenhouse management system. Which reads out the water level, humidity, and measures the moisture content of the soil based on real-time area data. With arduino components.
[2]Kaneda, Y., Ibayashi, H., Oishi, N., & Mineno, H. (2015). Greenhouse environmental control system based on SW-SVR. Procedia Computer Science, 60(1). https://doi.org/10.1016/j.procs.2015.08.249
This paper includes information about the general design of a greenhouse automatic environment control system.
[3]Kokieva, G. E., Trofimova, V. S., & Fedorov, I. R. (2020). Greenhouse microclimate control. IOP Conference Series: Materials Science and Engineering, 1001(1). https://doi.org/10.1088/1757-899X/1001/1/012136
This paper discusses (the lack of) a mathematical model to control greenhouse temperature and heat transfer.
[4]Kumar, A., Singh, V., Kumar, S., Jaiswal, S. P., & Bhadoria, V. S. (2020). IoT enabled system to monitor and control greenhouse. Materials Today: Proceedings. https://doi.org/10.1016/j.matpr.2020.11.040
This paper includes diagrams of arduino (components) and wiring to assemble a greenhouse management system.
[5]Sri Jahnavi, V., & Ahamed, S. F. (2015). Smart wireless sensor network for automated greenhouse. IETE Journal of Research, 61(2). https://doi.org/10.1080/03772063.2014.999834
This source includes information on all types of smart sensors aimed at a smart greenhouse.
[6]Von Borstel, F. D., Suárez, J., De La Rosa, E., & Gutiérrez, J. (2013). Feeding and water monitoring robot in aquaculture greenhouse. Industrial Robot, 40(1). https://doi.org/10.1108/01439911311294219
This paper contains the design of a robotic system to feed aquatic organisms and measure water physicochemical parameters in experimental aquaculture ponds. Our own system is focused on plants but the robotic monitoring of environmental parameters is of interest here.
[7]Zhang, C. (2018). Greenhouse intelligent control system based on microcontroller. AIP Conference Proceedings, 1955. https://doi.org/10.1063/1.5033697
This paper contains a chart with components of a greenhouse control system, including information on the circuitry per module, and a flow chart of how the software should work.
[8]Zhao, R., & Lu, L. (2020). Automatic Temperature and Humidity Detection and Alarm System for Greenhouse. IOP Conference Series: Earth and Environmental Science, 512(1). https://doi.org/10.1088/1755-1315/512/1/012099
This paper designs and implements the monitoring and alarm system of temperature and humidity of a greenhouse.
[9]Loram, A., Warren, P., Thompson, K., & Gaston, K. (2011). Urban Domestic Gardens: The Effects of Human Interventions on Garden Composition. Environmental Management, 48(4), 808–824. https://doi.org/10.1007/s00267-011-9723-3
This paper talks about how taking care of plants works stress-relieving.
[10]Pedrinolla, A., Tamburin, S., Brasioli, A., Sollima, A., Fonte, C., Muti, E., Smania, N., Schena, F., & Venturelli, M. (2019). An Indoor Therapeutic Garden for Behavioral Symptoms in Alzheimer’s Disease: A Randomized Controlled Trial. Journal of Alzheimer’s Disease, 71(3), 813–823. https://doi.org/10.3233/jad-190394
This paper is about fardening as a therapy for people with Alheimers disease.
[11]George, D. R. (2013). Harvesting the Biopsychosocial Benefits of Community Gardens. American Journal of Public Health, 103(8), e6. https://doi.org/10.2105/ajph.2013.301435
This paper is about how community gardens work for people with other mental illnesses, so it could also work on people with down syndrome.
[12]George, D. R., Kraschnewski, J. L., & Rovniak, L. S. (2011). Public Health Potential of Farmers’ Markets on Medical Center Campuses: A Case Study From Penn State Milton S. Hershey Medical Center. American Journal of Public Health, 101(12), 2226–2232. https://doi.org/10.2105/ajph.2011.300197
This paper is about how farmer-markets work positively on the health of people.
[13]Wieseler, N. A., Hanson, R. H., Chamberlain, T. P., & Thompson, T. (1988). Stereotypic behavior of mentally retarded adults adjunctive to a positive reinforcement schedule. Research in Developmental Disabilities, 9(4), 393–403. https://doi.org/10.1016/0891-4222(88)90033-9
A paper about a study which evaluated the indirect effects on stereotypic frequency when the value of a concurrent fixed-interval reinforcement schedule for adaptive behaviour was varied.
[14]Weatherley, P. E. (1976). Introduction: water movement through plants. Philosophical Transactions of the Royal Society of London. B, Biological Sciences, 273(927), 435–444. https://doi.org/10.1098/rstb.1976.0023
This paper explains how water movement in plants work.
[15]Carder, C. (2004). Irrigation systems. Rocky Mountain Construction, 85(20), 5. Retrieved from https://search-proquest-com.dianus.libr.tue.nl/trade-journals/irrigation-systems/docview/196317404/se-2?accountid=27128
A paper about the irrigation technology being used currently
[16]Vijendra Babu, D. (2020). Automatic Irrigation Systems for Efficient usage of Water using Embedded Control Systems. 993 012077
A paper about a similar project being done
[17]Mudiyanti, R. (2019). Design watering system on greenhouse using microcontroller with matrix based. iopscience.iop.org. 1280 022067
This paper is about desiging a watering system on a greenhouse using microcontroller with matrix based
[18]Gafni, V. (1999). Robots: A Real-Time Systems Architectural Style. ACM SIGSOFT Software Engineering Notes, 24(6), 1–18. https://doi.org/10.1145/318774.318786
This paper gives a broad description of what robots are
[19]Angela P. Presson, Ginger Partyka, … Edward R.B. McCabe, Current Estimate of Down Syndrome Population Prevalence in the United States, The Journal of Pediatrics, Volume 163, Issue 4, 2013, Pages 1163-1168, ISSN 0022-3476, https://doi.org/10.1016/j.jpeds.2013.06.013.
A paper about how often the syndrome of down occurs
[20]Robert A. Catalano, Down syndrome, Survey of Ophthalmology, Volume 34, Issue 5, 1990, Pages 385-398, ISSN 0039-6257, https://doi.org/10.1016/0039-6257(90)90116-D.
This paper goes really deep into what the syndrome of down actually is
[21]Mark Selikowitz. Down Syndrome. Vol 3rd ed. OUP Oxford; 2008. Accessed April 22, 2021. http://search.ebscohost.com/login.aspx?direct=true&db=nlebk&AN=467605&site=ehost-live
This paper is about raising children with down syndrome
[22]Chao, D., & Lin, H. (2010). The tricks plants use to reach appropriate light. Science China Life Sciences, 53(8), 916–926. https://doi.org/10.1007/s11427-010-4047-8
This paper explains how plants make sure they get the right amount of light, so not too much and not too little.
[23]Vanderbilt, V., & Grant, L. (1985). Plant Canopy Specular Reflectance Model. IEEE Transactions on Geoscience and Remote Sensing, GE-23(5), 722–730. https://doi.org/10.1109/tgrs.1985.289390
A model for the amount of light specularly reflected and polarised by a plant.
[24]Roberts, E., & Burleigh, M. (2010). Watering Systems for Success in Growing Plants, Using Low pH and Ammonium Nitrogen. Cactus and Succulent Journal, 82(6), 266–275. https://doi.org/10.2985/0007-9367-82.6.266
The paper describes what changes should be made to the water that is used in the system in order to get the best results.
[25]Drury, & Sally. (2011). Watering, bedding plants and tubs. Horticulture week, 34. https://search-proquest-com.dianus.libr.tue.nl/trade-journals/watering-bedding-plants-tubs/docview/872335545/se-2?accountid=27128
This paper explains when it is the best time of day to water certain plants.
[26]Rogers, P. (1993). Watering is crucial to plants: [ALL Edition]. Telegram & Gazette, G1. https://search-proquest-com.dianus.libr.tue.nl/newspapers/watering-is-crucial-plants/docview/268517145/se-2?accountid=27128
This paper explain why it is important that plants get the right amount of water.
User Needs and Preferences
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