The research used various data sets including the Constitution of Kenya 2010, the District and Provinces Act, 1992, the National Government Co-ordination Act, 2013, digital Electoral maps from IEBC, digital Administrative and 1: 50,000 Topographic maps from Survey of Kenya (SOK), digital Census maps from Kenya Bureau of Statistics. Table 1 shows the various data sets and their origin metadata.

The first task was to overlay the various spatial datasets involved in the alignment and put them into a common Spatial Reference System. Cleaning and removal of unnecessary geometries and matching the corresponding objects in the datasets was also done [3] .

Flowchart on the Alignment Methodology in Figure 2 below shows the first part of the two part methodology undertaken in the research.

The two boundary data sets were in different reference system, thus there was need to harmonize them in to a common one for them to be integrated for

accurate viewing and analysis. In Arc Toolbox data management tools, projections and transformations the data were projected to geographic coordinate system WGS84 as shown in Figure 3. This was adopted in order to enable web mapping as most online platforms use this coordinate system. The IEBC data was in Arc 1960, thus it had to be projected to WGS84.

Once the harmonized boundary was achieved, a web-based GIS portal for it was designed and populated in order to demonstrate the system’s functionality for sharing with the Geospatial community and any other users. It features a full screen mobile-friendly map template with responsive navbar and modal placeholders, jQuery loading of external GeoJSON files, logical multiple layer marker clustering via the leaflet maker cluster plugin and a client-side multi-layer feature search with auto-complete using typeahead.js. The portal also has a responsive sidebar feature list synced with map bounds, which includes sorting and filtering via list.js. Marker icons included in grouped layer control via the grouped layer control plugin [4] .

Softwares used for the study. The Software used for the research were Quantum

GIS, PostgreSQL with PostGIS, Mapbox, Bootstrap 3, Leaflet, and typeahead.js and Bitnami Wampstack Apache

Once the harmonized boundary was achieved, a web-based GIS portal for it was designed and the resultant shape-file imported. After the database creation, it was linked to Qgis. This enabled the administrator to add features directly to the database. This was done by using PostGis in Qgis, database, DBmanager, and then connected to a localhost in postgres by creating a new creation in the steps shown in the methodology flow chart 2 in Figure 4.

The research project used a single PostgreSQL server service to store the data. PostgreSQL 9.4 was downloaded and installed from the web site [5] , in the default c/program files/postgres and port 5432. PostGIS add-on was added by using the postgreSQL application stack builder. To check whether postGIS was installed clicking the 10th icon on the pdAdmin toolbar. Mavoko database was created on the PostgreSQL server by converting the shape files to their corresponding tables in a PostgreSQL database using the import shape file plugin in PostGIS extension. This was done by right clicking databases, new database in the PgAdmin III. extension.

To load a new extension into on the Mavoko database SQL plane, the following

code was typed and executed as shown on Figure 5. This was typically to create new SQL objects such as functions, data types, operators and index support methods. CREATE EXTENSION additionally records the identities of all the created objects, so that they can be dropped again if DROP EXTENSION is issued [6] .

CREATE EXTENSION IF NOT EXISTS postgis;

CREATE EXTENSION IF NOT EXISTS postgis_topology;

CREATE EXTENSION IF NOT EXISTS adminpack;

On the PostGIS shape-file and Dbf loader, a connection was done to the database then the shape files were added by importing them to PostgreSQL database tables using the shape file import manager plugin in PostGIS.

Tables which are the workhorses for the database for spatial functions meta-data were automatically created in the database’s public schema. The SPATIAL_REF_ SYS table and the GEOMETRY_COLUMNS table. The SPATIAL_REF_SYS table holds EPSG IDs and descriptions of the coordinate systems used in the spatial database [7] . By right clicking on the table, it was confirmed that the geometry column was present as shown below in Figure 6, thus a successful upload. These tables contain all the attributes of the imported shape files including the coordinates and geometry that define each feature.

Once the datasets were acquired they were put under a common special reference system as shown in Figure 7. The research identified several minor errors as shown in Figure 8 and corrected one by one. The PDA 2012 was used to harmonize the county boundaries. The existing Harmonized Boundary Maps Figure 9 were used to ascertain the correct boundaries between constituencies. This is because most constituency boundaries follow the already defined Municipal and County Boundaries.

Kenya Counties were established under the PDA 2012, this act was used to replot

the county boundary between the Nairobi and Machakos Counties in order to ascertain the correct boundary line [8] . Figure 10 shows the newly plotted boundary overlaid on 1:50,000 Topographical Maps and on Figure 11 overlaid on ArcGIS Online Satellite imagery.

The research realized that the two departments have different opinion on the boundary between adjacent administrative regions which make up the Muthwani and Mathatani CAW’s, Kinanie and Muthwani CAW’s, Syokimau and Ngelani CAW’s and Athi River Township and Athi River North CAW’s. To harmonize these boundaries, the research adopted the Harmonized Boundary (HB) Plan No. 22 that covers Machakos Municipality, HB 24(C) covering Mavoko Municipality and HB 24(D) covering Kangundo Town Council. These maps clearely showed the extent of each town, thus aking it possible to harmonize the boundaries. Figure 12 shows the Boundary overlaid on the HB Plans and Figure 13

show the boundary after rectification.

The boundary between Kinanie and Muthwani CAW’s had a gap, resulting into a disputed block as shown on Figure 14. In order to align the two boundary data sets, a field survey was carried out. This involved public consultation of the various stakeholders in the area, including but not limited to the area administrative officers, the school head teachers and their education counterparts, the IEBC Constituency Elections Coordinators, the County Surveyors and some residents. The boundary was picked as described in the field and plotted as shown on Figure 15.

The developed Web GIS portal is able to dispatch accurate information on time and consists of various useful GIS tools for spatial data visualization, analysis, querying and finally download data for use in mapping as base data. For the system to access the database, a Bitnami Wampstack Apache was downloaded and

installed, upon whose launch the log in user interface show in Figure 16. The results obtained through interacting with the developed web are diagrammatically illustrated in Figure 17, is the proposed harmonized boundary for Mavoko Constituency as a result of the research. Figure 18 depicts the interactive user interface with the boundaries, roads, markets and the polling stations with the various markets highlighted.

The study led to the creation of a single sub location layer for the Mavoko Constituency. The Geo-Portal created was able to facilitate basic functionalities of search and data retrieval in simple and fast data access, data analysis and re use of the sub location data in order to fulfill various functions and so as to suit these objectives. Therefore the research used a simple interface that would allow for easy information dissemination to all. Three categories of users were envisioned: 1) Those who would want to know boundary information in relation to places.

2) Those who would want to analyze the boundaries therefore download the data. 3) Those who would want to add more information into the platform.

The Kenya National Spatial Data Infrastructure (KNSDI) set up standards for carrying out Geo spatial work in Kenya. However very little was set in terms of alignment on boundaries by the various government departments in carrying out the various tasks. The research recommends that the IEBC, Kenya International Boundaries Office (KIBO), the Survey of Kenya (SoK), KNBS and the relevant department in state department of interior to work together and come up with a harmonized data set for the country. The methodology on boundary harmonization adopted in this research if adopted for this task can lead to a harmonized boundary in Kenya. Once the sub location data set is created, checked and authenticated then it can be used in future by the various public and private bodies or individual for any kind of mapping as base data. This will ensure harmony in the data used and avoid conflicts of spatial data hence boundary dispute experienced in many parts of the country. Some unique challenges could be experienced in areas with unique case of conflict like the international boundary in some instances and some historical issues that require negotiations and goodwill other than the scientific methods suggested. The web based portal if linked with the Kenya Open DataInitiative (KODI) network can be shared by for use by many people.