Difference between revisions of "G1-Group10"

Revision as of 00:37, 22 November 2019

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PROPOSAL

DATA TRANSFORMATION

POSTER

APPLICATION

RESEARCH PAPER

Introduction

International Food Chain (IFC) is a leading brand in its sector, with over 18000 outlets worldwide and an ever-growing presence in the global market. In Taiwan alone, IFC has over 240 branches and are constantly expanding.

However, as the franchise grows bigger, so does its challenges. One of the challenges involves the lack of a geographical analysis to efficiently compare the performance of each chain to one another.

Leveraging on this fact, our group aims to digitalise the data and conduct in-depth analysis on each branch. We hope to track the performance of each chain in relation to Point-Of-Interests surrounding each chain, uncovering and comprehending phenomena, with the aid of spatial data.

Problem and Motivation

To provide an analysis that allows for:

Digitizing of each chain’s trade and delivery area
Business profiling of the company’s outlet to determine Points-Of-Interests (POIs) that can generate insights such as: Highest earning outlets, relative performance of outlets, outlet’s profile patterns and item sales information.
Allow for informed business decisions, such as determining locations for new outlet openings with matching POIs of high sales outlets
Scalable program to incorporate future data to generate current information (Using data from other cities besides Taiwan)
Easy and intuitive tool to quickly view information with regards to all branches

Objectives

This project aims to provide insights into the following:

Missing Areas in trade zone
Number of POIs surrounding each store
Store performance with regards to sales
Delivery Information
Population Density
Buffer and proximity
Nearest Competitors to store
Variable importance based on regression analysis

Background Survey of Related Works (WIP)

Visualizations	Explaination
	Data source: https://www.researchgate.net/publication/324949619_Visualization_of_Fast_Food_Restaurant_Location_using_Geographical_Information_System The visualization provides the buffer polygons, as well as representing population density of the area through colour. By comparing the two, we can conclude whether the center of activity is proportional to the population density in a region. It allows us to perform further exploration to see what spatial information significantly affects the level of activity in a city, such as the availability of points-of-interest. This visualization is great as it allows the viewer to clearly see multiple dimensions dealing with spatial data in an elegant way.
	Data source: https://www.researchgate.net/publication/324949619_Visualization_of_Fast_Food_Restaurant_Location_using_Geographical_Information_System The graph on the left shows the distribution of outlets on the geographical map. The right graph describes the outlets grid distribution, result from grid creation and spatial joint operation. From both figures, they can show the potential tendency of whether the outlets are clustered, and with the number of outlets in each grid. We could use them together to justify and adjust the outlet locations.
	Data source: https://www.researchgate.net/publication/324949619_Visualization_of_Fast_Food_Restaurant_Location_using_Geographical_Information_System This visualization provides a novel way of linking a variable to its geographical location when hovering over the respective area. It would be great in our case, if we were to allow the user to view the corresponding branch through the tooltip, for example profit.
	Data source: https://www.researchgate.net/publication/324949619_Visualization_of_Fast_Food_Restaurant_Location_using_Geographical_Information_System This shows kernel density surface, based on the number of fast food restaurants around Jakarta and distribute them smoothly, so it provides average surface estimation. Kernel density estimation allows us to observe both the centrality and agglomeration of existing outlets. This visualization allows us to view multiple dimensions at a time in an effective manner, through the choice of colour and size.
	Data source: https://public.tableau.com/profile/mirandali#!/vizhome/Salesforce-SalesPerformance/SalesPerformance This databoard shows the cumulative sales. We could learn from this and display by outlets to compare the performance by having multiple forms of visualization. We really like the fact that certain key summarizations and variables are displayed on the top, and will consider using this in our project.

Tools and Libraries

The following tools and libraries are used in the digitisation and analysis:

QGIS
Python
R
Tableau

Datasets

Datasets Provided:

Dataset

Rationale

Traced Map

The client provided us with powerpoint files of manually drawn trade areas. These maps contain the various zones within the trade area, competitors, nearby stores as well as the drive time between each spots in the main road.
The five competitors defined by the client are:

Dominos
Napoleon
Mcdonalds
Kentucky Fried Chicken
Mos Burger

Geospatial Data

The client provided us SHP files that contains information about Counties found in Taiwan

Column	Description	Example
COUNTYID	Unique ID of each County	“U”
COUNTYCODE	Unique numerical ID of each County	10015
COUNTYNAME	Name of the County in Mandarin	“台北市”
COUNTYENG	Name of the County in English	“Taipei City”

Town Area

The client provided us SHP files that contains information about Towns found in Taiwan

Column	Description	Example
VILLCODE	Unique numerical ID of each Village	65000050041
VILLNAME	Name of the Village in Mandarin	“甲仙區”
VILLENG	Name of the Village in English	“Jiasian”
TOWNID	Unique ID of each Town	“K12”
TOWNCODE	Unique numerical ID of each town	10005060
TOWNNAME	Name of the Town in Mandarin	“半線城”
COUNTYID	Unique ID of each County	“U”
COUNTYCODE	Unique numerical ID of each Countyy	10015
COUNTYNAME	Name of the County in Mandarin	“台北市”
NOTE	Miscellaneous notes	NIL

Village Area

The client provided us SHP files that contains information about Villages found in Taiwan

Column	Description	Example
TOWNID	Unique ID of each Town	“K12”
TOWNCODE	Unique numerical ID of each town	10005060
TOWNNAME	Name of the Town in Mandarin	“半線城”
TOWNENG	Name of the Town in English	“Bamboo Town”
COUNTYID	Unique ID of each County	“U”
COUNTYCODE	Unique numerical ID of each County	10015
COUNTYNAME	Name of the County in Mandarin	“台北市”

Taiwan Stores

The client provided us a GeoPackage that contains information about each Pizza Hut Store

Column	Description	Example
fid	Unique ID of each Town	“K12”
Country	Unique numerical ID of each town	10005060
Market	Name of the Town in Mandarin	“半線城”
PH/PHD	Name of the Town in English	“Bamboo Town”
Status	Unique ID of each County	“U”
Milestone	Unique numerical ID of each County	10015
Local Code	Name of the County in Mandarin	“台北市”
CHAMPS Code	Name of the Town in English	“Bamboo Town”
JDE Code	Unique ID of each County	“U”
Store Name	Unique numerical ID of each County	10015
Latest Asset Type	Name of the County in Mandarin	“台北市”
Facility Type	Name of the Town in English	“Bamboo Town”
City Location	Unique ID of each County	“U”
Location Type	Unique numerical ID of each County	10015
Open Date	Name of the County in Mandarin	“台北市”
Close Date	Unique numerical ID of each County	10015
Corresponding Relo-Open / Relo-Closure Store Name	Name of the County in Mandarin	“台北市”
Corresponding Relo-Open / Relo-Closure Date	Unique numerical ID of each County	10015
Corresponding Relo-Open / Relo-Closure Asset Type	Name of the County in Mandarin	“台北市”
Store Address	Address of the store	B1 & 1F., No. 52-1, Hsin Sheng S. Rd., Sec. 1, Taipei, Taiwan (R.O.C)
Latitude	Latitude of the store	25.041601
Longitude	Longitude of the store	121.532475
Month	Month of the opening date of the store	10
Quarter	Quarter of the opening date of the store	Q4
Year	Year of the opening date of the store	FY1995
Grouping	Used to denote which group these stores were assigned to	G1 Group 10
Cluster ID	Used to denote which group these stores were assigned to, in numerical value	6

Foreseen Technical Challenges

We encountered the following technical challenges throughout the course of the project. We have indicated our proposed solutions, and the outcomes of the solutions.

Key Technical Challenges	Proposed Solution	Outcome
Data is already pre-aggregated to display monthly sales	The dataset is given directly to us from IFC, and we are unable to change it. Thus, We shall utilize and do our best with the available data.	NA
Unfamiliarity in R and Python in creation of data processing scripts	Watching video tutorials about R and Python Independent learning on the design and syntax Peer learning and sharing Using Datacamp as our mentor	We managed to start using the languages quickly and suit our own project needs. Each of us work on different parts such as setting up, designing, logic and deployment. This speeds up our project progress.
Data Cleaning & Transformation Proposed Solution	Having a systematic process while working together in order to maximise efficiency e.g. taking turns to clean, transform and perform checks on the data to ensure accuracy	The adopted process was having clear instructions issued to each member in the team, along with maintaining constant communication with each other. In the event that the dataset is deemed too dirty to be usable, it was dropped along with sourcing for new data that would be a suitable replacement.
Lack of geospatial knowledge to understand the dataset initially	Attend SMT201 class to learn more, as well as reading up on resources given by Prof Kam to gain further contextual knowledge	NA
Digitising of trade areas from powerpoint slide to QGIS	The process is manual and we had to put in a lot of effort to convert the drawn polygon to data points in QGIS.	The data points can better allow us to generate insights on the profile of each outlet via its trade area.
Integrating Relevant Data from Multiple Sources Proposed Solution	Working together to decide on what data to extract or eliminate	NA

Roles & Milestones (WIP)

Roles

Kelvin Chia Sen Wei	Linus Cheng Xin Wei	Eugene Choy Wen Jie
Data Cleaner Wiki Writer	Report Writer Design Architect	Data Cleaner 2 Poster man

Project Timeline

References

Project Page: https://wiki.smu.edu.sg/1920t1smt201/GIS_Project
Python Pandas: https://pandas.pydata.org/
Tableau: https://www.tableau.com/learn/training
QGIS: http://www.qgistutorials.com/en/

Comments

Feel free to leave comments / suggestions!

@@ Line 29: / Line 29: @@
 <br/>
-==<div style="background: #8b1209; padding: 15px; line-height: 0.3em; text-indent: 15px; font-size:18px; font-family:Helvetica"><font color= #FFFFFF>Introduction & Motivation</font></div>==
+==<div style="background: #8b1209; padding: 15px; line-height: 0.3em; text-indent: 15px; font-size:18px; font-family:Helvetica"><font color= #FFFFFF>Introduction</font></div>==
 <div style="font-family:Helvetica;font-size:16px">
 International Food Chain (IFC) is a leading brand in its sector, with over 18000 outlets worldwide and an ever-growing presence in the global market. In Taiwan alone, IFC has over 240 branches and are constantly expanding.
@@ Line 36: / Line 36: @@
 Leveraging on this fact, our group aims to digitalise the data and conduct in-depth analysis on each branch. We hope to track the performance of each chain in relation to Point-Of-Interests surrounding each chain, uncovering and comprehending phenomena, with the aid of spatial data.
+==<div style="background: #8b1209; padding: 15px; line-height: 0.3em; text-indent: 15px; font-size:18px; font-family:Helvetica"><font color= #FFFFFF>Problem and Motivation</font></div>==
+<div style="font-family:Helvetica;font-size:16px">
+To provide an analysis that allows for:
+* Digitizing of each chain’s trade and delivery area
+* Business profiling of the company’s outlet to determine Points-Of-Interests (POIs) that can generate insights such as: Highest earning outlets, relative performance of outlets, outlet’s profile patterns and item sales information.
+* Allow for informed business decisions, such as determining locations for new outlet openings with matching POIs of high sales outlets
+* Scalable program to incorporate future data to generate current information (Using data from other cities besides Taiwan)
+* Easy and intuitive tool to quickly view information with regards to all branches
 ==<div style="background: #8b1209; padding: 15px; line-height: 0.3em; text-indent: 15px; font-size:18px; font-family:Helvetica"><font color= #FFFFFF>Objectives</font></div>==
@@ Line 58: / Line 68: @@
 ! style="font-weight: bold;background: #000000;color:#fbfcfd;width: 10%;" | Explaination
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 <br>
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@@ Line 66: / Line 76: @@
 |-
-| [[Image:12.png|500px]]
+| [[Image:12.png|500px|center]]
 <br>
 ||
@@ Line 72: / Line 82: @@
 The graph on the left shows the distribution of outlets on the geographical map. The right graph describes the outlets grid distribution, result from grid creation and spatial joint operation. From both figures, they can show the potential tendency of whether the outlets are clustered, and with the number of outlets in each grid. We could use them together to justify and adjust the outlet locations.
 |-
-| [[Image:13.png|500px|]]
+| [[Image:13.png|500px|center|]]
 <br>
 ||
@@ Line 78: / Line 88: @@
 This visualization provides a novel way of linking a variable to its geographical location when hovering over the respective area. It would be great in our case, if we were to allow the user to view the corresponding branch through the tooltip, for example profit.
 |-
-| [[Image:14.png|500px]]
+| [[Image:14.png|500px|center]]
 <br>
 ||
@@ Line 84: / Line 94: @@
 This shows kernel density surface, based on the number of fast food restaurants around Jakarta and distribute them smoothly, so it provides average surface estimation. Kernel density estimation allows us to observe both the centrality and agglomeration of existing outlets. This visualization allows us to view multiple dimensions at a time in an effective manner, through the choice of colour and size.
 |-
-| [[Image:15.png|500px|]]
+| [[Image:15.png|500px|center|]]
 <br>
 ||

Difference between revisions of "G1-Group10"

Revision as of 00:37, 22 November 2019

Contents

Introduction

Problem and Motivation

Objectives

Background Survey of Related Works (WIP)

Tools and Libraries

Datasets

Foreseen Technical Challenges

Roles & Milestones (WIP)

References

Comments

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