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AI SALAD

Team members

Li Xingyun (ESD), Dionetta Young (ESD), Yeo Ying Xuan (ESD), Nicole Lee Xuening (ISTD), Rahul Bhattacharjee (ISTD), Ng Jia Yi (ISTD)

Instructors:

Francisco Benita, Liu Jun, Sergey Kushnarev

Writing Instructors:

Rashmi Kumar

Teaching Assistant:

Anirudh Maruvada

Company Partner:

norgren logo
problem statement

 

 

 

 

PROJECT OBJECTIVES

Partnered with Norgren, a firm specialising in motion control and fluid technology, we aim to develop an Internet-of-Things (IoT) enabled smart indoor vertical farming monitoring technology. The main objectives are to reduce cost of production and improve crop yield for Norgren’s client, Indoor Farm Factory Innovation (I.F.F.I), a local agri-food enterprise. Hence, we focused on the features on the right.

 

 

 

proposed solution

 

 

 

OVERALL SYSTEM ARCHITECTURE

 

System Architecture

 

 

HARDWARE ARCHITECTURE

hardware architecture facility

 

 

WEB BASED DASHBOARD

 

website functions

 

 

 

GROWTH DEGREE DAYS ANALYSIS

Growth of the plant is modelled as a function of the average daily temperature. After analyzing a real dataset with large variability in the data, we found that Linear Regression model delivered the best performance for this task.

Our testing and observation of the data in indoor conditions reveals to us that there is much less variance in indoor data, and consequently less noise. This means that our model will most probably be able to capture the trend with less noise in the indoor environment.

Our comprehensive database design combined with our django backend framework ensures that it is easy to expand the capabilities of the analytics system for other use cases, such as Irrigation Automation and Varying Evaporation Rate Modelling.

PROBLEM STATEMENT

Our land and resource-scarce Singapore produces only a small amount of food for its population, leaving the country vulnerable to disruptions in the global food supply chain.

We have always been heavily reliant on food imports, and the current COVID-19 situation has further emphasised the importance of local food production, as part of Singapore's long-term strategy to ensure food security.

For this Capstone Project, we explored into how we can leverage on innovating farming technologies to boost the nation's self-sufficiency for food.

 

project objectives

 

PROPOSED SOLUTION

Based on the client’s needs, our group proposed a solution that includes the use of hardware sensors to measure the plant growth conditions, and the development of a web-based dynamic dashboard.

The purpose of the sensors is to obtain the relevant parameters required to predict optimal conditions for plant growth. The data collected would then be transmitted to a cloud database, which can then be extracted to be analysed and visualised on the dashboard. The purpose of the web-based dashboard is to provide our client with real-time monitoring and analytics on the plant growth conditions based on the sensors installed at the indoor farm facility. It will also display a Growth Degree Days (GDD) Analysis feature to predict plants’ growth based on daily temperatures.

 

TECHNOLOGY STACK

 

proposed solution

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hardware architecture microenvironment

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microenvironment overview
gdd
regtests

TEAM MEMBERS

student Li Xingyun Engineering Systems and Design
student Dionetta Young Engineering Systems and Design
student Yeo Ying Xuan Engineering Systems and Design
student Nicole Lee Xuening Information Systems Technology and Design
student Rahul Bhattacharjee Information Systems Technology and Design
student Ng Jia Yi Information Systems Technology and Design
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