Energy for Sustainable Development 64 (2021) 118–127

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Energy for Sustainable Development
Ray of hope for sub-Saharan Africa's paratransit: Solar charging of urban
electric minibus taxis in South Africa
C.J. Abraham a, A.J. Rix a, I. Ndibatya a,b, M.J. Booysen a,⁎
a Department of E&E Engineering, Stellenbosch University, South Africa
b College of Computing and Information Sciences, Makerere University, Uganda
⁎ Corresponding author.
E-mail address: mjbooysen@sun.ac.za (M.J. Booysen).

https://doi.org/10.1016/j.esd.2021.08.003
0973-0826/© 2021 The Author(s). Published by Elsevie
creativecommons.org/licenses/by-nc-nd/4.0/).
a b s t r a c t
a r t i c l e i n f o
Article history:
Received 12 June 2021
Revised 20 August 2021
Accepted 27 August 2021
Available online 07 September 2021
Minibus taxi public transport is a seemingly chaotic phenomenon in the developing cities of the Global South
with uniquemobility and operational characteristics. Eventually this ubiquitous fleet of minibus taxis is expected
to transition to electric vehicles, which will result in an additional energy burden on Africa's already fragile elec-
trical grids. This paper examines the electrical energy demands of this possible evolution, and presents a generic
simulation environment to assess the grid impact and charging opportunities. We used GPS tracking and spatio-
temporal data to assess the energy requirements of nine electric minibus taxis as well as the informal and formal
stops at which the taxis can recharge. Given the region's abundant sunshine, wemodelled a grid-connected solar
photovoltaic charging system to determine how effectively PVmay be used to offset the additional burden on the
electrical grid. The mean energy demand of the taxis was 213kWh/d, resulting in an average efficiency of
0.93kWh/km. The stopping time across taxis, a proxy for charging opportunity, ranged from 7.7 h/d to 10.6 h/
d. The energy supplied per surface area of PV to offset the charging load of a taxi while stopping, ranged from
0.38 to 0.90kWh/m2 per day. Our simulator, which is publicly available, and the results will allow traffic planners
and grid operators to assess and plan for looming electric vehicle roll-outs.
© 2021 The Author(s). Published by Elsevier Inc. on behalf of International Energy Initiative. This is an open access

article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).
Keywords:
Electric vehicle
Paratransit
Minibus taxi
Demand management
Renewable energy
Introduction

Paratransit in Africa's developing countries differs substantially from
that of developed countries, from its inception to its vehicle types to its
operations. In developed countries, paratransit usually means a point-
to-point flexible demand-responsive transport service customised
with special requirements for the elderly and the disabled (Askari
et al., 2021; Behrens et al., 2017). For Africa's developing countries,
paratransit means an organically evolved, informal, market-oriented,
self-organising urban transport service that operates somewhere be-
tween private passenger transport and conventional public transport
in terms of cost, scheduling, routes and quality of service (Ndibatya &
Booysen, 2021; Neumann & Joubert, 2016). Here the paratransit system
consists of shared-ride, demand-responsive privately owned vehicles,
such as the minibus taxis in Lagos, Johannesburg, Nairobi and
Kampala, or the single-passenger motorcycle taxis (“boda bodas”) in
Kampala, or the tricycle taxis (“tuk-tuks”) in Nairobi (Booysen et al.,
2013; Diaz Olvera et al., 2019; Mutiso & Behrens, 2011).

Paratransit plays a vital role as the primary form of transport in sub-
Saharan Africa's public transit system. It transports more than 70% of the
daily commuters and is a source of livelihood for many families (Behrens
r Inc. on behalf of International En
et al., 2015). Paratransit in the region takes various forms, such asminibus
taxis,motorcycle taxis andbicycle taxis (Ehebrecht et al., 2018),withmini-
bus taxis carrying the largest daily share of passengers (Behrens et al.,
2017). Powered by internal combustion engines, the taxis contribute to
the emission of greenhouse gases and a general decline of air quality in
African cities (Collett & Hirmer, 2021; Odhiambo et al., 2021).

Travel by paratransit accounts for approximately 70%, 90%, 91%, and
98% of the road-based public trips in Johannesburg, Lagos, Kampala and
Dar es Salaam, respectively (Behrens et al., 2015; Evans et al., 2018). Of
these paratransit passenger trips, 83% are by minibus taxi (Dorothy
et al., 2016; Evans et al., 2018; KCCA, 2016).

The revolution in sub-Saharan Africa's paratransit

In sub-SaharanAfrica, the public transport industry experienced two
fundamental organic changes in the last quarter of the nineteenth cen-
tury. The first was the shift of transport services proprietorship, from
public to private, most often sole proprietorship, as a result of the
World Bank's structural adjustment policies of the 1990s that restricted
financing to state-owned entities, leading to their eventual collapse
(Kumar, 2011; Ajay Mahaputra Kumar et al., 2008; Cervero & Golub,
2007). The second was the gradual introduction of low-capacity (five-
to twenty-seater) passenger-carrying vehicles to fill the public trans-
port vacuum (Behrens et al., 2015; Diaz Olvera et al., 2019; Jennings &
ergy Initiative. This is an open access article under the CC BY-NC-ND license (http://

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mailto:mjbooysen@sun.ac.za
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C.J. Abraham, A.J. Rix, I. Ndibatya et al. Energy for Sustainable Development 64 (2021) 118–127
Behrens, 2017; Mutiso & Behrens, 2011). From the five seater Anglia
(Ford cars of the 1970s), to the 10-seater Peugeot 204 (1980s), to the
current 16-seater Toyota HiAce, paratransit service vehicles have been
of many types in many countries. Since the 1990s, the fourth and fifth
generations (H100 1989-model and H200 2004-model) of the
Japanese Toyota HiAce have dominated the paratransit market in
Africa. The Toyota HiAce trades under several names depending on
the country of assembly, such as Toyota Quantum in South Africa and
Toyota Ventury in Thailand. Originating simply as a complementary
transport service, the minibus taxis have become a way of life for the
urban poor in several African cities.

Two competing views have broadly shaped discourse on the mini-
bus taxis as part of the paratransit system in Africa. The predominant
view is that minibus taxis and paratransit in general are the most ex-
treme example of public transport failure in the developing world
(Lucas et al., 2019). To support this view, terms such as “chaotic”, “un-
sustainable”, “unsafe” and “pollutants” are common in the literature in
reference to the minibus taxis (Agbiboa, 2016; Pojani & Stead, 2017,
2018; Venter et al., 2019). In fact, the contribution of minibus taxis to
urban air pollution is significant, partly because they are old (often
older than 20 years) and they stand idling their engines for long
hours, thus hugely contributing to greenhouse gas emissions and the
deteriorating air quality in African cities. TheWorld HealthOrganisation
classifies exposure to ambient air pollution (AAP) as a major threat to
human health in sub-Saharan Africa, linking it to the increase in cardio-
vascular and cardiopulmonary diseases and lung cancer and respiratory
infections (Amegah & Agyei-Mensah, 2017; Dalal et al., 2011). Conse-
quently, proponents of this view advocate for a total overhaul of the
minibus taxi industry and its replacement with the western idea of or-
derly transport, the bus rapid transit (BRT) system.

Proponents of the second view advocate for a hybrid future, with
paratransit complementary to the scheduled BRT. However, the adop-
tion of this view is very slow and facingmuch resistance from the para-
transit operators. Although several benefits would accrue to them (such
as job security for the drivers, proper regulation, and government subsi-
dies) they would lose their autonomy and the elements of self-
organisation that formed the core of the original paratransit in Africa.

An alternative third view is emerging, which imagines Africa's
paratransit system as a complex adaptive system, composed of
many interdependent components that interact non-linearly, often
operating between “chaotic” and semi-orderly states (Behrens
et al., 2015; Goodfellow, 2017). This view acknowledges the coping
mechanisms and innovative forms of self-organisation exhibited by
paratransit and how the system adapts to serve the population's mo-
bility needs with little or no centralised control. Actually paratransit
“chaos” reveals to some degree the hidden order described by Hecht
as the “invisible governance … that maintains competing agendas
and aspirations in some kind of functional and parallel existence”
(Hecht, 2007).

The minibus taxi paratransit came into being to suit the mobile life-
style of the urban poor in sub-Saharan Africa. It is unlikely that themini-
bus taxis will be phased out of Africa's cities any time soon. They are
ubiquitous and will continue for many reasons: their schedule flexibil-
ity, the urban sprawl, the irregular commuter movement patterns in
urban spaces due to informal employment and the socio-cultural life-
styles of the urban poor in developing cities. However, the environmen-
tal cost of running these old internal combustion engine vehicles is
worrying. It has triggered discussions about the possibility of
transitioning to electric minibus taxis as part of the global electrification
and sustainability agenda (Collett & Hirmer, 2021).

The transition to electric vehicles and the electric minibus taxi

The development of low-carbon transport in cities is crucial to the
global agenda to combat climate change's various effects sustainably.
In fact, three of the seventeen United Nations Sustainable Development
119
Goals, one, eleven and thirteen, are clean energy, sustainable cities and
climate action (Zinkernagel et al., 2018).

The Intergovernmental Panel on Climate Change (IPCC) estimates
that the transport sector generates 23% of the global energy-related
greenhouse emissions (Sims et al., 2014). In sub-Saharan Africa the de-
teriorating air quality resulting from ambient air pollution and a high
concentration of particulate matter (PM2.5) is partly attributed to
vehicle emissions (Lozano Gracia et al., 2021; Rajé et al., 2018; Singh
et al., 2020). The WHO estimated that 1,100,000 deaths in Africa in
2016were due to air pollution, though thefiguremay be higher than re-
ported because air pollution epidemiological data is limited (United
Nations, Department of Economic and Social Affairs, Population
Division, 2019; World Health Organization et al., 2018). Akumu esti-
mates the cost of air pollution in African cities to be as high as 2.7% of
GDP (Akumu, 2014).

Consequently, electrification is promoted as a low-carbon transport
strategy to reduce combustion emissions and slow down the possibly
damaging effects of climate change. In the same spirit, the transition
to electric vehicles is gradually picking up in developing countries to
the extent that some vehicle manufacturers are planning to phase out
internal combustion engines. Sub-SaharanAfrica is seeing a few isolated
pilot electric vehicle projects, mainly focusing on micro-mobility (as
motorcycles and tricycles), as well as buses and private cars (Black
et al., 2018). At present, there is no known electric vehicle transition ini-
tiative targeting the paratransit industry, let alone theminibus taxis that
are responsible for more than 80% of the public transport trips in the re-
gion.

This paper builds a foundation for evaluating the eventual impact of
the transition to electricminibus taxis on cities' electrical grids, localised
pollution, carbon footprint and taxi owners' profitability. Specific atten-
tion is given to the energy requirements of these vehicles, the potential
distribution of charging stations and the potential electricity generation
capacity from renewable sources.

Overview of earlier studies and approaches

Initiatives to achieve sustainable urban mobility often follow a
three-pronged transport decarbonisation approach, the “Avoid-Shift-
Improve” paradigm (Galuszka et al., 2021; Lah, 2017). This approach
aims to reduce trips, shift towards public transport and non-motorised
modes and improve vehicle efficiency coupled with electrification (Le
& Trinh, 2016; Osei et al., 2021). In sub-Saharan Africa, the avoid and
shift approaches have not been intensively studied (Krüger et al.,
2021). The focus has been primarily on improvements: urban traffic
management strategies such aswidening roads, optimising road signal-
ling and encouraging multi-modal transport (developing mass transit
systems such as BRT and promoting walking and cycling) (Krüger
et al., 2021; Shams & Zlatkovic, 2020; Sietchiping et al., 2012; Venter
et al., 2018). Ironically, evidence from other world cities suggests that
building freeways and roads around cities only increases car depen-
dence and thus intensifies congestion and pollution (Sietchiping et al.,
2012). ll:introduction_shifting_to_evs Shifting to electric vehicles in
public transport and paratransit is an approach that has been neglected.
The literature on paratransit in sub-Saharan Africa focuses on aspects of
sector governance (Goodfellow, 2017) and regulation and reforms
(Jennings & Behrens, 2017; Lucas et al., 2019), but seldom on operations
(Ndibatya & Booysen, 2020), mobility characteristics (Ndibatya &
Booysen, 2021) and the prospects of electric mobility integration
(Galuszka et al., 2021).

Research from outside the region shows that electric vehicles are
three times more efficient than internal combustion engine vehicles
and twice as efficient as hybrid vehicles (Du et al., 2017; Weiss et al.,
2020). This efficiency is achieved partly by the efficient braking systems
and elimination of idling losses and the consequent saving of energy for
the vehicle's actual movement (Weiss et al., 2020). Although debate
continues on the economic and environmental trade-offs associated



C.J. Abraham, A.J. Rix, I. Ndibatya et al. Energy for Sustainable Development 64 (2021) 118–127
with electric vehicles (Li et al., 2016), there is evidence of sustainable elec-
tric vehicle deployment. Some researchers argue that deploying electric
vehicles shifts gasoline usage to coal-fired power generation, which exac-
erbates CO2 emissions by the power systems (Li et al., 2016). However,
electric vehicle proponents counter-argue that, on a macro-scale, these
vehicles' impact in terms of CO2 emissions depends mainly on the
charging strategy and that the emissions can be reduced by optimising
the use of renewable energy sources such as solar power (Buresh et al.,
2020; Schücking et al., 2017). In one of the scarce and isolated
publications on electric vehicles in sub-Saharan Africa, Buresh et al.
(2020) note that South Africa (like many countries in the region) has
high levels of insolation (the measure of solar energy at a place over a
specified time), from between 4.5 and 6.5 kWh/m2 per day, with annual
sunshine averaging more than 2500 h. This implies that the region has
an excellent chance of harnessing this renewable energy source to
power electric vehicles. Indeed, projects researching alternative renew-
able energy have taken shape in the region (Jadhav et al., 2017), though
not targeting electric vehicles for public transport services.

Two main research gaps remain in the literature on sub-Saharan
Africa's transition to electric minibus taxis. One is the mobility charac-
teristics of minibus taxis. As Quirós-Tortós et al. (2018) observe, to esti-
mate the charging requirements and vehicle performance of an electric
vehicle we need to know its mobility patterns, such as distance, travel-
ling time and idle time (or stopping time and duration). In other words,
the vehicle's mobility has spatio-temporal dimensions. Apart from the
findings of isolated studies on minibus taxi mobility, such as those by
Ndibatya and Booysen (2021), the general mobility dynamics of para-
transit in sub-Saharan Africa are unknown. The other is the region's po-
tential for renewable energy from different sources such as solar PV,
wind and bio-fuel as part of this transition (Jadhav et al., 2017;
Sawadogo et al., 2020; Soares et al., 2019).

From the sparseness of the work, it is clear that we lack information
on the mobility of minibus taxis in sub-Saharan Africa and specifically
the requirements of these minibus taxi fleets if they are converted to
electric vehicles (Collett & Hirmer, 2021; Odhiambo et al., 2021;
Booysen et al., 2021). Our reproducible method for determining their
mobility and analysing the generated data will fill the gap and help
city planners as well as fleet owners to improve their future operations.

Contribution

First the paper explores for the first time the energy requirements of
electric minibus taxis in an urban paratransit system, on journeys within
and between towns and cities. This was done by using an electric vehicle
model and a year's worth of GPS tracking data ll:introduction_fcd_def
(time-stamped geographical-coordinates recorded at minutely intervals)
in a micro traffic simulator. Second the paper explores the potential
charging opportunities at the multitude of formal and organically-
formed informal stops locations. Todo this,we analyse theGPSdata to de-
termine the locations of these stops, as well as the wildly variable arrival
times and stop durations. Thirdwe use thesemobility results (movement
patterns, stop locations and stop durations) in a solar PV simulator to also
establish the potential for chargingwith grid-connected solar PV, without
battery storage, at these stops. Ourmethod is limited to a case study in an
urban scenario near Cape Town in South Africa, but our fourth contribu-
tion is our integration and stop extraction software under the GPLv3 li-
cense, which can be modified and used to perform similar evaluations.
Finally, we assess the impact on the struggling South African grid of
converting all the minibus taxis in South Africa to electric vehicles, with
and without solar augmentation.

Method

This section describes the dataset and the three models used for the
research: theminibus taxi (MBT)mobilitymodel, the photovoltaic (PV)
model and the electric minibus taxi (eMBT) electric vehicle (EV)model.
120
It describes the pre-experimental collection and analysis of the floating
car data from a fleet of nine internal combustion engine minibus taxis.
Inter-town MBTmobility modelling involved spatial clustering of float-
ing car data to identify stopping events and generate routes between
stops in preparation for PV and eMBT modelling. We present two
model simulation setups for the EV and PVmodels and discuss their ap-
plication to our urban paratransit context. The PV model was based on
the SystemAdvisorModel (SAM) developed by theNational Renewable
Energy Laboratory (Blair et al., 2014). We ran the PV and the EVmodels
independently in a micro-transport simulator (SUMO) (Kurczveil et al.,
2014; Lopez et al., 2018), then recorded and analysed the eMBT energy
and PV requirements for each simulated context.

A custom simulation software was written in Python to automate
the steps in this methodology. The software is publicly available at:
https://gitlab.com/eputs/embt-sim/

Mobility

The dataset consisted of floating car data obtained by tracking urban
minibus taxis operating on bidirectional routes connecting Stellen-
bosch, Brackenfell and Somerset West in the Western Cape Province
of South Africa. The area under study is defined by coordinates are
(34.229224, 18.656884) and (−33.786222, 18.969438) as shown in
Fig. 1a. The data obtained from Mix Telematics (a local fleet manage-
ment service provider), consisted of timestamped geo-locations (lati-
tude and longitude), speed and direction, logged at a frequency of one
minute from onboard tracking devices for over two years. After
cleaning, filtering and performing pre-data loading preparations, we
had an average of 201 days' worth of floating car data per minibus
taxi for use in EV and PV modelling.

Spatial clustering and analysis
An overlay heatmap showing the intensity variation of minibus taxi

activity (based on the count of GPS data points)was plotted as shown in
Fig. 1a. Three high-intensity areas were visible in the heatmap: Stellen-
bosch, Brackenfell (west of Stellenbosch) and Somerset West (south of
Stellenbosch). We interpreted these three areas as the epicentres of
minibus taxi activity, a view that closely matches that of Ebot Eno
Akpa et al. (2016).

We used the density-based spatial clustering of applications with
noise (DBSCAN) algorithm to group high-density closely related data
points (or geo-locations), forming spatial clusters of data points that
represented significant events (such as stopping and movement) dur-
ing normal minibus taxi operations. We chose the DBSCAN algorithm
because of its robustness to outlier detection, its ability to discover clus-
ters with uneven densities and arbitrary shapes, and the fact that it does
not need prior knowledge of the number of clusters (Liu et al., 2012;
Renjith et al., 2020). For cluster analysis we used a Python implementa-
tion of the DBSCAN algorithm from the Scikit-Learn package (Pedregosa
et al., 2011). The minimum cluster size (min_samples) was 70, and the
maximum distance between neighbouring points in a cluster
(max_eps) was 0.0002° (Ndibatya et al., 2014). Fig. 1b shows the spatial
distribution of cluster centroids overlaid on OpenStreetMap.

Identifying minibus taxi stops
To generate the mobility patterns and establish the potential for

charging at stops, it was necessary to identify the spatial clusters with
stopping events. Additional temporal analysis was required to deter-
mine the stop times and stop durations. We therefore further analysed
each spatial cluster to identify sets of data points representing either a
stop event or a movement event within the cluster's spatial extent. A
stop event in our work is closely related to a “stay point” as defined by
Zheng et al. (2009) and Damiani et al. (2014) and refers to a series of
consecutive GPS locations within a cluster's spatial extent, with a taxi
velocity below a threshold of 1 km/h. The arrival time of the stop
event is the time of the first GPS location in the series, and the duration

https://gitlab.com/eputs/embt-sim/


Fig. 1. (a) Heat map showing the variation (by density) of floating car data; (b) Distribution of spatial-clusters in Stellenbosch as determined by the clustering process; (c) Illustration of
way points, stop events and route generation process.

C.J. Abraham, A.J. Rix, I. Ndibatya et al. Energy for Sustainable Development 64 (2021) 118–127
of the stop-event is the difference between the timestamps of the first
and last GPS locations in the series as illustrated in Fig. 1c. Themovement
events (or waypoints) represented by all the cluster data points that do
not belong to the ‘stop event’ category were preserved for use during
minibus taxi route generation in the EV model.

For each spatio-temporal clusterwe generated a statistical summary
describing the total number of stop events, average stop arrival time,
average stop duration, and the standard deviations from these. The
statistical summary helped to identify the spatial clusters with the
most stop events and their typical time and duration. We were thus
able to identify spatial clusters with many stop events as formal taxi
stops (terminuses). Spatial clusters with lower counts could be identi-
fied as intersections where the taxis pause for traffic, or informal stops
made en route to pick up passengers. Clustering the stop events tempo-
rally also helped to identify the times when these stops typically
occurred.

Generating routes
To simulate the mobility of MBTs between the three towns and sub-

sequently study their energy requirements, we generated the routes
linking the identified stops. A route in this context is a series of edges
connecting two or more stop events, often starting and ending in differ-
ent clusters (or cluster centroids). A simulatedMBT follows pre-selected
routes as part of its daily route plan within the simulation boundary.

We used the stop events' cluster centroids, the waypoints (GPS data
representing moving events), the roads network, and SUMO's shortest
path Djikstra algorithm to generate the routes. The underlying road
network was based on OpenStreetMaps (OSM) (OpenStreetMap
contributors, 2017), which included the roads, intersections, speed
limits, and traffic lights information. All the GPS data points (including
cluster centroids andwaypoints) were snapped to the OpenStreetMap's
road network, and the shortest path between the origin and destination
points of interest was computed using SUMO's implementation of the
Djikstra algorithm (Lopez et al., 2018). This algorithm searches for the
route with the least cost (Lewis, 2020), where the cost can be the dis-
tance, time, or electricity consumption of the simulated EV. In this
study, we defined the cost as the distance (we omitted the other options
due to simulation performance considerations). For each simulated day
we generated a route, and from these routes we computed extra
121
information that affects an EV's (or eMBT's) energy usage, such as the
total distance, the road inclination and the road curvature.

The eMBT EV model

We set up a simulation model using a custom SUMO electric vehicle
simulation model, SUMO EV, to measure the temporal variation of
power and energy usage and the relationships between power con-
sumption and eMBT speed. The model's parameters were specified to
match the prevailing MBT used in South Africa, the Toyota Quantum.
The weight and front surface area used for a synthetic eMBTwere mea-
sured from one of the Toyota Quantumminibus taxis operating in Stel-
lenbosch.We approximated the rest of the parameters according to the
recommendations by Fridlund andWilen (2020). These parameters in-
clude: height 2.3 m, width 1.9 m, front-facing surface area 4m2, weight
2900 kg, constant power intake 100 W, propulsion efficiency 0.8, recu-
peration efficiency 0.5, roll drag coefficient 0.01 and radial drag coeffi-
cient 0.5. The simulation program initialised the eMBT model for each
date that was simulated. The eMBTmodel was applied to the generated
routes. For every second of simulation time, the simulator logged the
energy consumption and speed of the eMBT as it progressed along its
route.

With an average of 201 routes per taxi, the volume of output data
from the model was huge. Our goal was to obtain useful metrics that
would summarise this data. The first metric we considered was the av-
erage power usage profile of the fleet of nine eMBTs. Such a profile
would indicate how much power the eMBTs used at various points in
time. This profile would be indispensable, for example, for testing the
hypothesis that there would be a good charging opportunity at midday.
It would also show what order of magnitude the motor size should be.
We calculated the profile by obtaining the power-vs-time profile for
each day, averaging this across all days for each eMBT, and then averag-
ing that across all eMBTs in the fleet. The profile was plotted with re-
spect to time.

PV model simulation setup

We set up the SAM-based PVmodel to calculate the energy available
from photovoltaic sources and to study the daily charging potential for



C.J. Abraham, A.J. Rix, I. Ndibatya et al. Energy for Sustainable Development 64 (2021) 118–127
each eMBT in a synthetic fleet of nine eMBTs. The model generates the
plane-of-array solar irradiance profile based on radiometric data, solar
azimuth angle, and photovoltaic panel tilt angle. We used radiometric
data for a year sampled every 15 min from the National Solar Radiation
Database (Sengupta et al., 2018). The azimuth and tilt angleswere set at
0° (North) and 20°, respectively, a common configuration which maxi-
mises energy yield in South Africa (Le Roux, 2016).

To get the output power profile of the PV array, a 16% system effi-
ciency was applied to the irradiance profile, i.e., 20% and 80% were
used for the solar panel and balance of the system (including the in-
verter), respectively. We used the stop event analysis done earlier to
further analyse the battery charging potential from solar PV by evaluat-
ing the times atwhich the stop events occurred and their durations.We
Fig. 2. Spatio-temporal clustering of arrival time and duration of stops at significant spatial-clust
the spatial-clusters situated near termini found in Kayamandi in Stellenbosch, Somerset West, and

122
first applied thresholds tofilter out stop eventswith durations above 8 h
or below 20 min. This was to ensure that stop events irrelevant to our
study did not skew the statistics. Stops above 8 h would only occur on
special events such as a public holiday or a vehicle breakdown. Stops
under 20 min would be too short for charging. These stop events were
grouped according to the spatial cluster in which they occurred, and
temporal clustering was done within each spatial cluster to obtain
spatio-temporal clusters.

Based on the stop events detected during the spatio-temporal clus-
tering, we computed the potential energy sourced from PV per day.
For each eMBT stop event, the PV output-power-profile was integrated
from the beginning to the end of the stop event in order to calculate the
total energy that could be charged from PV during that stop event. The
ers for threeMBTs: (a) T1001; (b) T3001; (c) T5000.North, South and Central termini refer to
Stellenbosch Central, respectively.



Table 1
Summary of the MBT stop events identified during the cluster analysis. The clusters are
grouped by vehicle ID and sorted by duration in descending order. The vehicleswith bold-
faced IDs were plotted in Fig. 2. (Note: μ = Mean, σ = Standard deviation).

Minibus Spatio-temporal Stop events Arrival
(h)

Duration
(h)

Terminus

Taxi ID Cluster ID count μ σ μ σ Name

T1000 C101 302 12.0 4.8 1.5 1.2 North
C102 309 14.1 3.1 1.4 1.2 Central
C104 15 17.4 1.3 0.7 0.3 South
C103 18 7.1 0.4 0.5 0.2 South

T1001 C111 1074 12.9 5.3 1.5 1.1 North
C112 782 14.6 3.2 1.2 1.1 Central
C114 41 16.6 1.4 0.7 0.4 South
C113 17 7.1 0.4 0.5 0.2 South

T3001 C311 686 12.5 4.7 1.5 1.2 North
C312 689 14.2 3.4 1.2 1.0 Central
C314 87 16.1 1.3 0.7 0.3 South
C313 37 7.2 0.4 0.5 0.1 South

T4000 C402 495 14.2 3.4 1.5 1.4 Central
C401 406 11.8 4.5 1.3 1.0 North
C404 42 16.4 1.0 0.6 0.2 South
C403 29 7.0 0.4 0.5 0.1 South

T5000 C501 787 10.5 4.3 1.3 1.1 North
C502 709 14.7 3.4 1.2 1.0 Central
C503 139 16.3 1.0 0.6 0.2 South
C504 30 7.4 0.4 0.5 0.2 South

T6000 C601 34 8.5 0.4 5.9 1.0 North
C602 82 16.6 1.1 1.1 0.8 North
C603 52 7.1 1.0 1.0 0.6 North

T6001 C611 403 12.4 4.7 1.4 1.1 North
C612 359 14.1 3.3 1.3 1.2 Central
C613 11 7.2 0.5 0.5 0.2 South
C614 8 17.6 1.0 0.5 0.2 South

T7000 C702 904 14.3 3.2 1.3 1.1 Central
C701 765 10.7 4.1 1.3 1.1 North
C704 30 16.5 1.5 0.6 0.3 South
C703 33 7.0 0.4 0.5 0.2 South

T7001 C712 430 15.0 3.7 1.4 1.1 Central
C711 272 12.0 4.9 1.1 0.9 North

C.J. Abraham, A.J. Rix, I. Ndibatya et al. Energy for Sustainable Development 64 (2021) 118–127
PV energy of each stop event was summed to get the total energy that
could be charged from PV for that day as a function of the area of the
PV array. These “daily PV charging potentials” were aggregated for
each taxi and plotted as box plots. This metric allowed us to approxi-
mate the size of the PV array required to provide a certain percentage
of an eMBT's energy demands.

Results and discussion

This section describes the results obtained from applying our three
models to the floating car data from Stellenbosch and its surrounds.
The results obtained refer specifically to the MBT mobility, the eMBT's
power requirements and the potential charging opportunities. The
charging opportunities are separated into stop times for the purpose
of source-ambivalent charging, and potential charging from PV.

The inter-town MBT mobility modelling provides spatial clustering
of the identified stop events that serve as input to the PV modelling
while generating routes used to determine the power requirements of
the individual eMBT and the fleet of eMBTs.

Mobility analysis

Fig. 2 shows the results of the spatio-temporal clustering of data
from three minibus taxis to determine the stops. Despite the seemingly
chaotic patterns, the clustering analysis identified spatio-temporal clus-
ters of stops. The figure shows how each minibus taxi has a vertically
distributed (i.e. varying duration) morning cluster at around 8:00 am,
and a horizontally distributed (i.e. varying arrival time) cluster in the
evening. For example, the spatio-temporal clusters in the South Termi-
nus indicate that those spatial clusters were visited in the morning and
in the evening.

The spatio-temporal clusters were primarily used in SUMO to gener-
ate the traffic simulator's mobility patterns and then analyse the charg-
ing potential during stationary periods. A statistical summary of all the
identified stop clusters, showing the stationary periods during daylight
hours grouped by taxi, is provided in Table 1. Although the standard de-
viation is substantial, themean stop durations of the clusters weremore
than one hour for at least two stops per taxi. The arrival times of the lon-
ger stopswere all between 10:30 am and 3:00 pm except for one outlier
taxi T6000, which exhibited wildly different clustering results. Accord-
ingly, the clusters indicate that there should be substantial potential
for charging from solar power.

Energy analysis

The output of the EV simulation is shown in Fig. 3. Themean instan-
taneous power demand versus time of a working weekday is shown in
Fig. 3a. A clear typical temporal profile is apparent for theminibus taxis,
closely matching the peak traffic hours. There is a sharp peak demand
period from 6:00 am to 9:00 am, with a peak value of 32 kW. A dimin-
ished demand with a mean of 6 kW is observed from 9:00 am to 1:00
pm, constituting a period of substantially reduced activity, due to the
taxis being stationary during this time. This demonstrates the potential
for charging, particularly with solar energy, due to the high insolation at
midday. This is followed by a gradual increase to a less pronounced peak
value of 30 kW between 5:00 pm and 6:00 pm. This flatter evening de-
mandprofile slowly declines to return to the trough of 7 kWby 9:00pm.
Complete inactivity is observed from 11:30 pm to 4:30 am. Not only is
this profile clearly defined, but the variation between taxis, shown by
the minimum and maximum profiles in the shaded area, is minimal.
The only substantial deviation is the increase in the maximum profile
just after 9:00 pm, which results from the long-distance journeys over
weekends (departing at 9:00 pm on Friday evenings) and holidays, as
reported by Ebot Eno Akpa et al. (2016).

This profile indicates the energy demand profile requirements of the
eMBTs, and already hints at substantial charging potential during the
123
evening – probably from grid power – and during the middle of the
day – preferably from solar power.

Fig. 3b shows the MBT's speed versus time of the day, the similarity
of which highlights the substantial impact of speed on power draw. The
energy required and the distance travelledwas found by integrating the
the power and speed profiles with respect to time. It was found that the
energy required was close to linearly proportional to the distance trav-
elled, which demonstrates that a simpler distance-based model would
have provided good estimations and required substantially less process-
ing power. The mean energy required per day is 213kWh.

The distribution of energy usage per taxi per day, is shown in Fig. 4a
for the nine taxis. The taxis' energy usage is similar, with themedian en-
ergy per taxi per day across all taxis ranging from 189kWh to 252kWh,
with the mean of the medians equal to 215kWh. For any given taxi, on
75% of the days, less than 303kWh is used. Eight of the nine taxis, on
all days, use less than 420kWh, while the other taxi uses up to 490kWh.

The results show that the maximum daily impact that a taxi would
have on the grid is approximately 500kWh. For 75% of the time, the im-
pact would be less than 300kWh. This impact can be reduced by using
solar energy to meet part of the energy requirements. Finally, it can be
noted that the actual battery size of the taxi could be considerably
lower than the daily energy usage, since the taxi can be charged during
the day at its longer stops.

Charging potential

A sizable eMBT fleet could place a substantial burden on the local
electrical distribution network and power generation capacity of coun-
tries in sub-Saharan Africa. The strain on the local network could cause
infrastructure and electrical supply problems, so we investigated the



Fig. 3. Plots of (a) the mean power-usage profile and (b) the mean speed profile of the fleet of simulated eMBTs.

C.J. Abraham, A.J. Rix, I. Ndibatya et al. Energy for Sustainable Development 64 (2021) 118–127
opportunities for charging these vehicles from solar PV systems. To dis-
cover the eMBTs' opportunities and requirements if they are to charge
during stationary periods, we did a 24-h analysis of the start times
and the durations of stop events. The analysis shows what the average
charger capacity should be if a vehicle is charged using only power
from the local electrical network.We applied a minimum stop duration
of 20min and amaximum stop duration of 8 h to ensure that only valid
operational stops would be identified and that drop or pick up and go
events were not included as charging opportunities.We chose themax-
imum of 8 h because a taxi in normal service would not stop for longer
than that on a week day.
Fig. 4. Summary of mobility, energy req

124
Charging from the grid
Fig. 4b shows the distribution of stop events across days, with the

minimum and maximum stop duration thresholds applied. The figure
shows that the MBTs' stop duration times vary considerably, with the
median duration per day ranging from a minimum of 7.7 h for taxi
T3001 to a maximum of 10.7 h for taxi T6000.

To calculate the charger capacity we used a relatively high energy
demand and a relatively short charging time for a relatively demanding
situation to obtain a conservative estimate of the charger capacity. We
used the averages of the 75th percentile of the energy usage (Fig. 4a)
and the 25th percentile of the 24-h stop duration times (Fig. 4b) as
uirements, and charging potentials.



C.J. Abraham, A.J. Rix, I. Ndibatya et al. Energy for Sustainable Development 64 (2021) 118–127
247 kWh and 7.65 h respectively to calculate a charger capacity of 32.3
kW. This assumes a constant charging profile and charging only from
the local electrical grid.

Charging from solar PV
We evaluated the potential for charging the eMBTs from solar PV,

both to reduce the load on the electrical grid and to reduce the size of
the battery installed in the eMBT. The energy generated per surface
area is shown in Fig. 4c for each month of the year, representing an
upper bound of charging potential during stationary periods.

The aggregate charging potential per square metre of solar panel,
for the fleet, is shown in Fig. 4d, indicating that a large amount of the
generated energy could be used during stops. The disaggregated dis-
tribution of charging potential for each taxi, per squaremetre of solar
panel, is shown in Fig. 5. The variation of charging potential between
taxis is low, indicating that the taxis follow similar patterns during
the daylight hours, and that they would require similar charging in-
frastructure. Assuming that the PV installations were sized to exploit
the median stop potential per taxi, the mean potential would be
0.68kWh/m2 and would vary from a minimum of 0.38kWh/m2 to a
maximum of 0.90kWh/m2 during the year. The results show that a
solar installation of approximately 320m2 (equivalent to the total
area of half a tennis court) would be required per taxi to ensure
that the taxi's daily energy requirements are met by solar supply at
least 50% of the time.
Fig. 5. Disaggregated charging potential (in kWh

125
Given the estimated 285,000 taxis in South Africa, our analysis indi-
cates that to charge all the minibus taxis from the national grid will re-
quire 9.72% (61.27GWh) of the current daily national energy
generation. The average taxi would be able to directly utilise between
57% and 80% of installed PV generation capacity during normal stops.

Conclusion

This paper focuses on paratransit, a common feature in sub-Saharan
Africa, which transports more than 70% of the region's commuters. One
urgent outcome of the United Nations' Sustainable Development Goals
is to decarbonise paratransit in the region. However, due to the sector's
unstructured, unregulated and demand-driven nature, the lack of data
on the mobility of minibus taxis poses a substantial challenge against
these efforts.

We therefore formulated a structured approach for evaluating vari-
ousmetrics which can help to evaluate the feasibility and the design re-
quirements of electric paratransit systems. The approach used easily-
obtainable GPS tracking data and a traffic simulator to evaluate the elec-
trical demand requirements of these vehicles, as well as the proportion
of the demand that can be met by renewable energy. For the first time,
using this method, an estimate could be given of the energy require-
ments of a hypothetical electrical paratransit system in SSA.

Paratransit mobility was characterised using GPS tracking data.
These characteristics revealed that the mean distance travelled per
m2) per eMBT for each month of the year.



C.J. Abraham, A.J. Rix, I. Ndibatya et al. Energy for Sustainable Development 64 (2021) 118–127
taxi was 228 km/day. For each of the nine taxis, the median daily stop
duration was calculated and was found to range from 7.7 h to 10.6 h.
This indicated that the energy demand would be quite high, and the
time for charging would be quite low.

From the mobility characteristics, we found that a minibus-taxi
would use approximately 215 kWh to satisfy its daily mobility require-
ments.We found that taxis whichwere stopped for shorter periods, and
hence had less time for charging, were also the ones that needed more
energy because they were more mobile. Nonetheless, a charger of
around 32 kW would be required. This meant that the total fleet of
South Africa's minibus taxis would use around 10% of the daily national
energy generation. This may not seem like a lot, but it would cover ap-
proximately 70% of the country's commuter trips, while incentivising
investment into renewable energy infrastructure.

The sustainability of future paratransit needs to be coupled with a
transition to renewable energy. Stellenbosch, like most other cities in
SSA is privileged to have abundant sunshine. Therefore, photovoltaics
was conceived as a potentially feasible renewable energy generator
that can support electric paratransit. We found that a PV installation of
320m2 (half the size of a tennis court) could satisfy the energy require-
ments of the average taxi 50% of the time. This took into account the
daily solar irradiation profile and the times and durations that the taxi
made its stops. Developing countries outside of Africa may not have
such abundant sunshine, but the methodology uses software which in-
cludes models of other renewable energy generators.

Although these results are specific to a scenario in South Africa, the
major contribution of this paper is the novel procedure for evaluating
the impacts and opportunities of electric-vehicle roll-outs. The software
is contributed, and can be easilymodified to suit the context of other de-
veloping countries. For example, to evaluate the impact of electrification
of India's auto rickshaws, the EVmodel parameters can bemodified ac-
cordingly, and the PV simulation can be modified to include local
weather conditions. The authors call for future work to be done to eval-
uate the energy requirements in other developing countries. The results
of the program can be used not only by researchers, but also by grid-
operators, traffic planners, and private-entities to obtain the financial,
environmental, electrical, and mobility impacts of electric-vehicle roll-
outs of varying scales.
Declaration of competing interest

The authors declare that they have no known competing financial
interests or personal relationships that could have appeared to influ-
ence the work reported in this paper.

Acknowledgements

The authords acknowledge MiX Telematics for the data, and MTN
South Africa (through the MTN Mobile Intelligence Lab), and Eskom
(through the Tertiary Education Support Programme) for sponsoring
this research.We also thank the taxi owners and drivers for their partic-
ipation.

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	Ray of hope for sub-�Saharan Africa's paratransit: Solar charging of urban electric minibus taxis in South Africa
	Introduction
	The revolution in sub-Saharan Africa's paratransit
	The transition to electric vehicles and the electric minibus taxi
	Overview of earlier studies and approaches
	Contribution

	Method
	Mobility
	Spatial clustering and analysis
	Identifying minibus taxi stops
	Generating routes

	The eMBT EV model
	PV model simulation setup

	Results and discussion
	Mobility analysis
	Energy analysis
	Charging potential
	Charging from the grid
	Charging from solar PV


	Conclusion
	Declaration of competing interest
	Acknowledgements
	References