Forecasting Optimal Solar Energy Supply in Jiangsu Province (China): A Systematic Approach Using Hybrid of Weather and Energy Forecast Models


Research Article
Forecasting Optimal Solar Energy Supply in Jiangsu
Province (China): A Systematic Approach Using Hybrid of
Weather and Energy Forecast Models

Xiuli Zhao, Henry Asante Antwi, and Ethel Yiranbon

School of Management, Jiangsu University, 301 Xuefu Road, Zhenjiang, Jiangsu 212013, China

Correspondence should be addressed to Xiuli Zhao; asanteantwi2@gmail.com

Received 17 October 2013; Accepted 21 November 2013; Published 5 January 2014

Academic Editors: R. Pedicini and P. Pei

Copyright © 2014 Xiuli Zhao et al. This is an open access article distributed under the Creative Commons Attribution License,
which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

The idea of aggregating information is clearly recognizable in the daily lives of all entities whether as individuals or as a group, since
time immemorial corporate organizations, governments, and individuals as economic agents aggregate information to formulate
decisions. Energy planning represents an investment-decision problem where information needs to be aggregated from credible
sources to predict both demand and supply of energy. To do this there are varying methods ranging from the use of portfolio
theory to managing risk and maximizing portfolio performance under a variety of unpredictable economic outcomes. The future
demand for energy and need to use solar energy in order to avoid future energy crisis in Jiangsu province in China require energy
planners in the province to abandon their reliance on traditional, “least-cost,” and stand-alone technology cost estimates and instead
evaluate conventional and renewable energy supply on the basis of a hybrid of optimization models in order to ensure effective and
reliable supply. Our task in this research is to propose measures towards addressing optimal solar energy forecasting by employing
a systematic optimization approach based on a hybrid of weather and energy forecast models. After giving an overview of the
sustainable energy issues in China, we have reviewed and classified the various models that existing studies have used to predict
the influences of the weather influences and the output of solar energy production units. Further, we evaluate the performance of
an exemplary ensemble model which combines the forecast output of two popular statistical prediction methods using a dynamic
weighting factor.

1. Introduction

China as a growing economy has high demand for electricity
and nonrenewable sources of energy have been documented
to have low capacity for supporting future social and eco-
nomic development of China [1]. There is high future demand
for energy and a need to explore sustainable alternatives such
as the use solar energy in order to avoid future Chinese
energy crisis. According to Yang [2] the conceptualization of
renewable energy and its sustainability form the foundation
of emerging agendas on the future sources and use of energy
and energy planning in China as a whole. Solar power,
wind power, thermal power, hydropower, and nuclear power
are categorized as renewable energy. From sustainability
perspective, different sources of power have different life
cycle costs, which further contribute to the differences in

prioritization of the different renewable power sources [3],
although life cycle costs of nuclear power may be lower
compared to life cycle costs of solar power and wind power,
for example, nuclear plants are exposed to risks of nuclear and
radiation emissions that have negative long term impacts on
the plants and animals. Solar power has advantage of lower
maintenance costs over a long period of time [4].

In China, the alignment of sustainability goals and contri-
bution to socioeconomic development recognize solar power
to have the lowest forms of environmental pollution and the
lowest level of carbon footprint. For this reason solar power is
perceived to be more competitive in China and more research
and development have been targeted at improving innovation
of solar power in China (at least with the last half of the
century) [5]. Apart from its superiority in environmental
sustainability goals, solar energy has a higher capacity to

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Volume 2014, Article ID 580606, 9 pages
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2 The Scientific World Journal

satisfy different industrial and domestic needs based on per-
formance measures for achieving energy efficiency, energy
saving capabilities, and capacity for reduction of emission
technologies. In addition, solar power has higher advantages
as a clean energy technology. As Huang et al. [6] have noted
planning for energy use within a region or province is a
huge investment-decision problem. Currently most of the
research works in solar energy issues in China are devoted
to issues of demand and investments. Usually demand issues
are analyzed by investors using portfolio theory in order to
manage risk and maximize portfolio performance under a
variety of unpredictable economic outcomes. There is also
a modicum of studies in China which encourages those
responsible for energy policy formulation and planning to do
away with the continuous reliance on traditional, “least-cost”
stand-alone technology cost estimates. Instead they should
evaluate conventional and renewable energy sources based on
the portfolio cost, the cost/risk versus contribution [6].

While the demand for solar energy appears to be relatively
high, its supply is not for several reasons in China. Apart from
variations, there is also a challenge in the sense that solar
energy supply is given attention only in a few provinces in
China compared to other forms of energy. For this reason
there is the need to develop efficient and dedicated methods
of forecasting solar energy as a basis for supporting energy
planners and grid operators to efficiently and effectively
manage the balance of power between demand and supply of
solar energy to overcome any possible instability in and even
possible collapses of the sector in the not too distant future
[7]. In respect of effective forecasting of solar energy supply,
a number of studies exist in the extant literature both at indi-
vidual and community levels to help cope with the situation.

Even though there is a large deposit of studies which
interrogates both practical and scientific optimization ideas,
it is still to be determined a straightforward and easy-to-use
approach to standardized energy forecasting especially when
it comes to solar energy. If the results of different experi-
mental projects are compared, this makes it more difficult
to arrive at a simplified and standardized energy forecasting
approach because most of these studies analyzed cases that
are region specific. Further, there is no constant form of
result evaluation across all publications, as different error
metrics are applied to measure output quality [8]. Our task
in this research is to propose measures towards addressing
optimal solar energy forecasting by employing a systematic
optimization approach based on a hybrid of weather and
energy forecast models. After giving an overview of the
sustainable energy issues in China, we have reviewed and
classified the various models that existing studies have used
to predict the influences of the weather influences and the
output of solar energy production units. Further, we describe
the process of solar energy forecasting and establish the
relevant parameters, settings, and other exogenous influences
for selecting the appropriate model against that background.
Next, we evaluate the performance of an exemplary ensemble
model which combines the forecast output of two popular
statistical prediction methods using a dynamic weighting
factor [9].

Figure 1: Provincial map of China showing the location of Jiangsu
province, adopted from [10].

Following proposal for further studies in existing litera-
ture, this study describes essential forecasting ideas in respect
of energy planning and discusses their application in the
Jiangsu province which is one of the areas in China where
solar energy is gaining significant attention (Figure 1 shows
the map of China indicating the location of Jiangsu Province).
Finally we outline the additional research directions for our
future work. Thus, a study on criteria for forecasting methods
of solar power could help to determine its sustainability in
the long term and capacity to support grid power supply
[8]. Further this study is important as it seeks to act as
benchmarks for rationale power policy development in global
and local contexts and determination of rationale power
information systems could be managed [8].

2. Renewable Energy Investment in Jiangsu

Currently the Chinese energy demand is largely dependent
on coal and crude oil and hydro based energy sources.
Recent studies have documented the possibility of increase
in demand of power from current 5000–6000 Tonne Watt
per hour to 8000–10000 Tonne Watt per hour. The increase
in energy demand against decreasing coal-reserves presents
possible future challenges and risks of energy crisis or
possible economic crisis in China that may arise from energy
crisis, aspects that may have more negative economic and
financial impacts than was experienced during 1970s Global
Financial Crisis that was linked to oil crises; [11] explains that
the prospect of exploiting full capacity of solar power cannot
be done in haste due to high level of planning and quan-
tification measures that ought to be done and long period
that is needed to implement solar power (China National
Committee for the Implementation of the UN Convention to
Combat Desertification) [11]. This means that the economic
and social developments in China may continue to rely on



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coal and crude oil driven machines due to inability to produce
enough alternative sources such as solar energy, wind energy.

Prabhu [12] proposed possibilities of continuity in the use
of coal or nonrenewable sources of energy to power national
grid system due to high losses that are associated with solar
power supply at the point of generation. However this system
thinking approach, where high power losses occur at point
of generation, could result in nonuse of solar power in large
scale or in commercial purposes. But this has been negated
by Peidong et al. [13] who proposed that future development
of solar power and other renewable sources of energy is
important due to lack of sustainability of non-renewable
sources of energy from social, economic, and environmental
perspectives. This implies that, in China, as emerging higher
consumer of electric power, there is, a need for development
and innovation of solar power.

Again, according to Qu et al. [14], high energy losses
occur at the point of production of solar power which implies
that the net energy output (NEO) that is eventually supplied
to the National Grid system is lower. Further, as later studies
by Fan et al. [15] found, the sellable electricity output from
solar farms is very low. The costing of sellable solar power
is calculated as a difference between loss of energy output
(LEO) and gross energy output (GEO) to give net energy
output (NEO) which is documented din literature to be a
range between 58% and 47%, from sellable energy percentage
of 42% and 53%. For all practical purposes, [15] indicates
that solar firms or solar power generators cannot achieve
gross energy output (GEO) that is dependent on onsite
measurement data and variability of local solar resources.
Reference [14] indicate that that differences in GEO arise
because different factors are not taken into account when
calculating GEO. Some of these factors include

(i) wake effect of solar turbine generator system,
(ii) electric equipment which also consumes part of

generated power,
(iii) line losses due to type of wires used and distance

that the power is transmitted from production site to
consumption point,

(iv) presence of the wake effect of solar-turbine generator
systems,

(v) stability or instability of solar speed for turning
turbiness,

(vi) changes in the directions of solar leading to variation
in the quantity of solar power that is generated,

(vii) changes and variation in weather and climate for
instance low or high temperatures and their impacts
on air density,

(viii) on-site air density and variation of air density,
(ix) solar farm electricity needs and consumption in the

solar farms,
(x) guarantee of power curve of wake effect of solar

turbine generator system.

There are fears that solar power may fail to support
economic developments the way coal or crude oil power has

Figure 2: Map of Chinese power grid, adopted from [16].

supported economic developments. However, the high rate
of economic development from coal has resulted in increased
environmental and resources pressures. For instance, in 1980,
in China, acidic rain is documented to have affected over 10%
of Chinese land mass. This implies that crude oil and coal as
power sources are more pollutant compared to solar power.
In addition, solar power does not preclude development of
global energy and global power solution. Reference [17] has
indicated that the current amount of money that will cost
Jiangsu to produce renewable energy is among the highest
compared to other options but this cost is actually the initial
set-up cost but largely lower when it is spread over its useful
life and the consideration is given to other associated social
costs. In other words, if renewable energy is compared with
other forms of energy such as coals and hydro, on the basis
of environmental impact, then using renewable energy is
far cheaper in the long term as it helps to bring significant
improvement in environment and reduces the susceptibility
to other forms of diseases that could have been incurred
compared to the high social cost of the rest which are
still struggling to get improved technology to make their
processing better.

It is the estimation of Zhong [18] that by the end of the
year 2013 the prices of domestic renewable energy technology
will decline by averagely less than 5,000 RMB/kW. Since the
renewable energy industry all over the world and in China
in particular is gradually developing, the trend in prices
will continue to decline by about 10% in 2015 and even till
about a decade afterwards and will reduce by 10% per decade
[18]. It is the confident estimation of [17] that by the year
2030, the prices of renewable energy technology may hit as
low as 3,850 RMB/kW or even lower at 3,000 RMB/kW due
to the expectation of the emergence of the new efficiency
technologies that will make it cheaper to produce and operate
the renewable energy technology. On the other hand it is also
the case that the unit cost of operating the solar power turbine
was going to 0.125 RMB/kWh [19]. Figure 2 shows the map of
Chinese power grid.

It has also been estimated by Zhipeng [20] that by the
end of the year 2030, the total investment in the solar power
if it is looked at from a high scenario perspective will reach



4 The Scientific World Journal

Energy forecast models

Physical Statistical Hybrid

Naïve prediction Similar days Stochastic time series Machine learning 

MultivariateUnivariate

Figure 3: Classification of energy forecasting models, adopted from [8].

about 2.84 trillion RMB, but with an intermediate scenarios
the expectation will be that the total investment cost will be
2.13 trillion RMB. On the other hand the low scenario will
lead to a total investment cost of approximately 1.57 trillion
RMB. From the above analysis and in comparison with other
approaches to power generation, Xiaoliang [21] presented
evidence to support the claim that not only is renewable
energy generation environmentally friendly, thereby having
the possibility of reducing the cost of operations in one
country as it is in the case of China, but also it has lower
operating cost based on all sensitive analyses to the point
that even the worst case scenario of costing appears to be
more favourable than other methods such as the coal fired
energy sources [7]. That notwithstanding it is important for
China to target the best case scenario of achieving the lowest
cost production and investment since it is within the reach
of achievement. Again a recent study [7] categorizes the
superiority of solar power energy into three main areas and
these are explained below.

3. Energy Supply Forecasting Approaches

Within the existing literature there are several approaches to
energy supply prediction; however, the time series remains
a common and classical tool for applied energy prediction
analysis. According to Alfares and Nazeeruddin [22], the
extant literature is inundated with a long and rich history
of forecasting electricity load or demand using a range of
very sophisticated but high-quality models. However, the
necessity for having specialized energy supply forecasting
approaches remains a fairly new topic and hence has limited
number of studies. The recent interest in energy supply fore-
casting is largely because of the challenges of grid-connected
RES penetrating the distribution systems. Notwithstanding,
both energy demand and supply forecasting approaches make
use of similar or related techniques. Generally, there are
generally two main approaches to energy supply forecasting
and these are the weather forecast models and the energy
forecast models. Figure 3 shows the classification of weather
forecasting models.

According to Chen et al. [23] the weather forecasting
models are computed based on the assumption that energy
supply predictions must be done rationally if one wants

to get a good forecast. They further explain that a good
prediction of the solar energy output is will depend on a
good forecast of the solar irradiation. Consequently, using
a precise weather forecast model is a functional prerequisite
for obtaining or generating a reliable energy output model.
This view is shared by Dorvlo et al. [24] who also argue that
even though determining the quality of the solar irradiation
is orthogonal to the core activities of a grid operator (this is
the core work of the meteorological services), having a basic
understanding of the underlying principles helps in choosing
a specific energy output model. Wu and Chan [25] present
series of approaches under the weather forecasting models
some of which include the numerical weather prediction, the
cloud imagery and statistical models.

Each of these models has different submodels used
in enhancing effective prediction. For example, under
the numerical weather prediction researchers have used
approaches such as the European Center for Medium-Range
Weather-Forecasts Model (ECMWF), the Global Forecast
System (GFS) from National Centers for Environmental
Prediction 4, or the North American Mesoscale Model
(NAM). While the numerical weather prediction models
above are modern and common method to predict a number
of variables by describing the physics and dynamic of the
atmosphere, which are then used to derive the relevant
weather influences at a specific point of interest, the cloud
imagery approaches are relatively different [8].

Using either the satellite data approach or the total sky
imagers approach, cloud imagery hinges on the influences of
local cloudiness where it is considered to be the most critical
factor for the estimation of solar irradiation, especially on
days with partial cloudiness where abrupt changes may occur.
With the statistical models the treatment of solar radiation
forecasting is based on data on historical observation through
the use of simple and common time series regression models
like ARIMA, artificial neural networks (ANN) or fuzzy-logic
models (FL) [8].

According to Reikard [26] after comparing various
regression models, ARIMA in logs with time-varying coef-
ficients performs best, due to its ability to capture the diurnal
cycle more effectively than other methods [25]. It is further
the contention of Wu and Chan [25] that combining ARMA
and a time delay neural network (TDNN) is the best while
[24] also posit that a hybrid of multilayer perceptron (MLP)



The Scientific World Journal 5

Weather Forecast Models

Numerical Weather Prediction
ECMWF

GFS (NCEF)
NAME (NCDC)

Cloud Imagery
Satellite Based

Total Sky Imager

Statistical Models
ARMA/TDNN

ARIMA
ANFIS
RBFNN

MLP

Figure 4: Classification of weather forecasting models, adopted from [8].

and radial basis functions (RBF) which are both ANN-
models simpler and precise. On the other hand Mu et al.
[27] compares the performance of Adaptative network based
fuzzy inference system (ANFIS) against autoregressive mod-
els (AR) and ANN. For this reason [8] think that using a
statistical model as those above is considered being domain-
neutral.

On the other hand it is the contention of Cai et al. [28]
that when the outputs have been generated from any of
the weather models described above, they must equally be
converted into energy forecast models. Currently the main
energy forecast models or methods include categories of
physical, statistical, and hybrid methods as shown in Figure 4.

According to Cai et al. [28] the physical models embraces
all the energy supply forecasting approaches that rely on
a renewable power plant’s technical ability to convert the
meteorological resources collected into electrical power. It
considers the external influences derived from NWP, local
topography, and atmospheric conditions. They are fitted to
become an accurate set which has no need of historical output
curves. With the local topography, this becomes suitable
for the estimation of future output of planned or recently
installed RES units. While some levels of solar energy supply
predictions have been made by applying physical models, the
most frequent and suitable area for their use is in predicting
wind energy supply [28].

When it comes to the statistical models for predicting
energy, the work of [29] has explained series of them which
are used under different conditions. The first of these is the
naive prediction model. In this approach considered as the
most straightforward of the statistical models naive guess
is made by assuming that next periods’ expected energy
output will be equal to the observations of the current period
𝑃𝑝. The next statistical approach to energy prediction is the
similar-days model which is based on the concept of diurnal
persistence, improved forecasts. This is computed by selecting
related historical days with appropriate similarity of time
series measures [30].

These models are the most popular for forecasts loads
under situations where the weather awareness plays an
insignificant role in relation to how consumption cycle
derived from historical data influences forecast load. In case
of solar energy forecasts, similar-days models are used in

instances where there is no NWP available at all or the
prediction error included naturally in the NWP is estimated
as too high to provide reliable energy output forecasts
(Bolinger et al. [31]).

With the stochastic time series models for energy supply
forecasting, it is the contention of [8] that this depends on
the total number of parameters that influences the models.
There are two groups of main approaches to energy supply
forecasting in the model and these are univariate and mul-
tivariate models. While the univariate employs exponential
smoothing for effective one-period ahead, the multivariate
model allows for the integration of exogenous parameters.
Finally there is the machine learning model to energy supply
forecasting. This approach is the most common approach
to forecasting a time series’ future values. This is because
it appears to be the best alternative to conventional linear
forecasting methods.

In the existing literature, the ANN has been applied
more successfully in forecasting the rate of energy supply
fluctuation. ANN learns to recognize patterns in data using
training data sets. For example, the use of neural networks
is proposed by Frank et al. [32] due to their examination of
the feed-forward (FFNN), the radial basis function (RBFNN)
and the recurrent neural network (RNN) for solar power fore-
casting based on NWP input and historical observation data.
A similar approach is described by [31] where a RBFNN is
combined with a weather type classification model obtained
by a self-organizing map (SOM). In contrast, Tao et al.
compute hourly energy forecasts using an adaptive NARX
network combined with a clear-sky radiation model, which
allows for forecasts without including NWP data and still
outperforms nonadapting regression based methods.

4. Argument for Hybrid Method

According to Kleindorfer et al. [33] the challenge with adopt-
ing a single approach top prediction is often the uncertainty
that comes with it. The process of planning and predicting is
generally an attempt to make a good guess of an uncertain
future based on what is happening today. For this reason the
ability to get different predictive tools to validate results is
essential in effective planning that reduces the risk exposure.
In essence the hybrid models refer to the combination of any



6 The Scientific World Journal

two or more of the above methods that have been described.
According to Jensen [34] using hybrid approaches to predict
energy supply pattern has become a very popular approach
because of the fact that it gives the opportunity to take
advantage of the strongest points of different stand-alone
forecasting techniques [35]. The basic idea of combining
models is to use each method’s unique features in capturing
different patterns in the data. Theoretical and empirical
findings from other domains suggest that combining linear
and nonlinear models can be an efficient way to improve
the forecast accuracy [36] so hybrid models seem to be a
promising approach that can potentially outperform nonhy-
brid models individually.

Awerbuch [37] provides a successful example of how
hybrid approaches can be applied thus setting a context
as to the extent to which this can be applied within the
context of Chinese Jiangsu province where solar energy is
gaining some level of appreciation over the last couple of
years. Specifically in this study we provide an analysis of the
impact of the parameters for the selection of energy models
for forecasting solar energy supply including the model
combination task. From them we compare the total supply
quantity forecasted using two stochastic models belonging
to the multivariate class: (A) a simple linear model based
on principal component analysis and multivariate regression
from the MIRABEL project and (B) a commercial library
using the more complex non-linear MARS algorithm.

The forecasts are compared both individually and in com-
bination against a naive, weather-unaware reference model
(REF) based on the similar-days method. Similar models have
been used within the context of Germany by [8]. It is however
uncertain as to whether differences in geographical location
identified as an important factor in solar energy prediction
will affect the level of success of the application of this model
in Jiangsu province in China.

5. Materials and Methods

5.1. Data and Setting for Experiment. Recent studies into
prediction market have led to the introduction of model
selection criteria of spatial aggregation. In order to cope with
this challenge the study included three different observations
of solar energy output curves into our adopted scenario.
Firstly a single, disaggregated PV-installation located in
central Jiangsu town of Nanjing which is incidentally the
provincial capital was chosen and is denoted in our model
or scenario as DA. Secondly the scenario also considers the
aggregate of all PV-installations available that is measured in
the same local distribution system and this has been denoted
as DS. Thirdly our model equally has an aggregation of all PV-
installations attached to the superior transmission system.
This however is denoted as TS. The ability to obtain this
information requires some level of cooperation; hence, DA
and DS data were provided by a cooperating distribution
system operator, while data category TS was obtained from a
public website. All-time series have a resolution of 15 minutes
and cover June 2012 to June 2013.

The study picked data on weather which included mea-
surements of solar irradiation, air temperature, and wind
speed with a resolution of 1 hour from a nearby weather sta-
tion operated by the meteorological services in the province.
This was an appropriate source because it is located within
the range of the distribution networks. The reason why only
the observed weather data was used is because of the ability
to eliminate the NWP prediction error. This further allows
the energy model performance itself to be evaluated with a
high degree of accuracy. From our source time series, we
made use of the historical data for the first eleven months
for the purposes of training and the last month for forecast
evaluation. In order for our scenario to account for day-ahead
and intraday terms, forecast horizons of two, twelve, and
twenty-four hours ahead were defined in consistency with
earlier works of [8, 37–39]. The time thus started each day
at 00:15. The model building horizon was adopted following
the computation of the forecast. To do this we added the
forecast horizon length to the model horizon. This was to
extend the length of the available history in accordance with
each of the iterations completed. The effect of this was to
simulate the integration of newly arriving observations in
the forecasting process, which can then be compared with
the forecasted values and used to qualify the forecast model.
Therefore, the number of forecasting models required to
cover the whole month was three hundred seventy-two for
a horizon of two hours, sixty-two (twelve hours) and thirty
one (twenty-four hours), respectively. In order to derive the
optimal combination ratio between two analyzed algorithms
𝐴 and 𝐵, the variable perceptual weighting factor 𝜆 was
introduced. The final energy forecast𝑃𝐼

𝑡
is then computed by

𝑃
󸀠

𝑡
=𝜆𝑃
󸀠

𝐴𝑡
+(1−𝜆)𝑃

󸀠

𝐵𝑡
. (1)

In this equation, 𝑃𝑡
𝐴𝑡

represents the forecasted value of
algorithm𝐴 and𝑃𝐼

𝐵𝑡
is the forecasted value from algorithm

𝐵 for a timestamp of 𝑡.

6. Output Evaluation

A number of different statistical metrics available were used
to evaluate the extent to which the values that have been
forecasted are of good and realistic quality. According to [37]
it is often the case that the root mean square error (RMSE) is
desirable when one is measuring or evaluating the criterion
for intraday forecasts. The reason is that it is able to address
the likelihood of extreme values better than others. With
the RMSE returning absolute values, we used a normalized
form to enable the comparison of the performance of the
models on output curves of different aggregation scales. The
normalized root mean square error (nRMSE) is achieved by

nRMSE=
RMSE
𝑃max
∗100. (2)

In this model the 𝑃max represents the maximum observed
power output. It was noted that using the percentage dif-
ference between observed and predicted power outputs to
forecast with day-ahead horizons or above is more inter-
esting. This is expressed by the mean absolute percentage



The Scientific World Journal 7

Table 1: Quality of forecast results using nRMSE evaluation metric.

REF 𝜆A 𝜆B DA 2 DA 12 DA 24 DS 2 DS 12 DS 24 TS 2 TS 12 TS 24
100% — — 17,64 18,79 12,99 17,27 20,24 24,96 9,65 10,67 13,33
0 100% 0% 13,66 13,66 13,66 14,68 14,68 14,68 11,80 11,80 11,80
0 70% 10% 13,98 14,28 13,97 13,79 14,39 14,08 9,48 10,14 11,10
0 40% 40% 13,04 12,47 12,89 13,11 14,70 14,39 8,16 9,58 11,30
0 10% 70% 11,84 12,05 13,12 12,29 14,82 15,55 8,73 9,29 11,45
0 0% 100% 11,16 12,54 13,47 12,35 13,88 14,25 8,73 10,51 11,47

error (MAPE). Following [8], nondaylight hours (values with
timestamps before 8 am and after 4 pm) and all resting sero
observation values were excluded from error calculation. This
also means that the effects of snow coverage or measurement
failures were removed completely from the results.

7. Results of Experiment

In Table 1, the results of both the linear (A) and non-linear (B)
models have been presented. The table shows that both the
linear and nonlinear models clearly outperform the similar-
days reference model (REF) individually in most of the
analyzed cases in terms of nRMSE. Again the information
also shows that generally the nonlinear model gives better
results than the linear model and this is an indication of
the fact that including the historical values improves the
quality of output. Notwithstanding, some constellations can
be found where model combinations perform slightly better
than individual models. With regard to the impact of the
chosen forecast horizon, it is observed that the quality of
algorithm B decreases with longer horizons and is almost
identical to model A for day-ahead periods while model A
provides constant values. This can also be explained by the
exponential influence of historical values, which has no effect
on model A. It is our suspicion that model A can outperform
model B on short-term, and midterm forecasts, which have
not been covered by the presented scenario.

It appears rather surprising that all models show the
lowest preciseness on the DS aggregate where a better per-
formance was expected than that on the disaggregation
DA. The possibly included share of self-consumption units
(prosumers) may explain the reduction of correlation values,
as those measurements are hidden within the observed
output curve, thus requiring an individual treatment (e.g.,
using combined energy demand and supply models) which
needs to be further investigated. It is also noted that all
models perform best on the highest aggregate. Even though
the observed correlation of weather information at only one
location is not a representative influence on that supra-
regional level, the effect of weather-awareness seems to be
completely neutralized by the impact of high aggregation.

8. Conclusion

Our task in this research was to propose measures towards
addressing optimal solar energy forecasting by employing

a systematic optimization approach based on a hybrid of
weather and energy forecast models. After giving an overview
of the sustainable energy issues in China, we have reviewed
and classified the various models that existing studies have
used to predict the influences of the weather influences and
the output of solar energy production units. Further, we
have established the relevant parameters, settings, and other
exogenous influences for selecting the appropriate model
against that background.

Finally we have evaluated the performance of an exem-
plary hybrid model that combines the forecast output of
two popular statistical prediction methods using a dynamic
weighting factor. The study has shown that effective fore-
casting of solar energy output requires a two-step approach.
Firstly it requires weather, and energy forecast models. It has
been observed that with respect to energy forecast, there are
possible choices that can be selected amongst statistical, phys-
ical, and hybrid models. The research has further established
that selecting an appropriate model is dependent on various
conditions, hence, the forecasting step can be considered
as an iterative process. From the effectiveness of the hybrid
approach as has been found in the analysis of data, it is evident
that a hybrid model that combines both weather and energy
forecasting models appears to offer additional optimization
option.

This is especially in the case where there is no model
found to individually outperform in all given situations. This
has been demonstrated in the analysis against the parameters
of forecast horizon and spatial aggregation. Notwithstanding
we propose that future studies must focus on examining the
extent to which complex hybrid forms of energy and weather
forecasting models can lead to more efficient predictions.
In effect combining many weather forecasting approaches
against single energy forecasting approach and vice versa
is good enough to start future enquiry into finding the
most efficient way of predicting energy supply. The dynamics
of solar energy supply in Jiangsu province in China still
makes it an interesting field to explore any future complex
application of hybrid solar energy prediction models. This
may provide some opportunities to develop global standards
for forecasting solar energy with more efficient and reliable
outcomes.

Conflict of Interests

The authors declare that there is no conflict of interests
regarding the publication of this paper.



8 The Scientific World Journal

Acknowledgment

The authors wish to express their profound appreciation
to China Natural Science Fund (Grant nos. 71273119 and
71073071) for supporting this project.

References

[1] J. Asafu-Adjaye, “The relationship between energy consump-
tion, energy prices and economic growth: time series evidence
from Asian developing countries,” Energy Economics, vol. 22,
no. 6, pp. 615–625, 2000.

[2] H.-Y. Yang, “A note on the causal relationship between energy
and GDP in Taiwan,” Energy Economics, vol. 22, no. 3, pp. 309–
317, 2000.

[3] B.-N. Huang, M. J. Hwang, and C. W. Yang, “Causal relationship
between energy consumption and GDP growth revisited: a
dynamic panel data approach,” Ecological Economics, vol. 67, no.
1, pp. 41–54, 2008.

[4] C.-C. Lee, “The causality relationship between energy con-
sumption and GDP in G-11 countries revisited,” Energy Policy,
vol. 34, no. 9, pp. 1086–1093, 2006.

[5] C. John and Y. Li, “Relationship between national energy
consumption and GDP,” Unpublished work. Term Research
Paper for EAS501 Energy and Its Impact by Professor Lior, 2008.

[6] B.-N. Huang, M. J. Hwang, and C. W. Yang, “Causal relationship
between energy consumption and GDP growth revisited: a
dynamic panel data approach,” Ecological Economics, vol. 67, no.
1, pp. 41–54, 2008.

[7] J. Child and Y. Yan, “Investment and control in international
joint ventures: the case of China,” Journal of World Business, vol.
34, no. 1, pp. 3–15, 2012.

[8] R. Ulbricht, U. Fischer, W. Lehner, and H. Donker, “Optimized
renewable energy forecasting in local distribution networks,”
Proceedings of the Joint EDBT/ICDT Electronic Conference,
2013.

[9] W. Zhang, “Can the strategy of western development narrow
down China’s regional disparity?” Asian Economic Papers, vol.
3, no. 3, pp. 1–23, 2004.

[10] China Statistical Bureau, Political Maps of Chinese Provinces,
Beijing, China, 2012.

[11] China National Committee for the Implementation of the UN
Convention to Combat Desertification (CCICCD), “China
National Action Program to Combat Desertification,” CCICCD,
2009, http://www.docstoc.com/docs/33202781/CHINA-
NATIONAL-ACTION-PROGRAM-TO-COMBAT-DESERTI-
FICATION.

[12] E. Prabhu, “Reflective energies and national renewable energy
laboratory (U.S.),” Solar Trough Organic Rankine Electric-
ity System (STORES). November 2000–May 2005 Golden,
Colo: National Renewable Energy Laboratory, 2006, http://purl
.access.gpo.gov/GPO/LPS91600.

[13] Z. Peidong, Y. Yanli, S. jin, Z. Yonghong, W. Lisheng, and L. Xin-
rong, “Opportunities and challenges for renewable energy
policy in China,” Renewable and Sustainable Energy Reviews,
vol. 13, no. 2, pp. 439–449, 2009.

[14] H. Qu, J. Zhao, and X. Yu, “Simulation of parabolic trough solar
power generating system for typical chinese sites,” Proceedings
of the Chinese Society of Electrical Engineering, vol. 28, no. 11, pp.
87–93, 2008.

[15] J. Fan, W. Sun, and D.-M. Ren, “Renewables portfolio standard
and regional energy structure optimisation in China,” Energy
Policy, vol. 33, no. 3, pp. 279–287, 2005.

[16] China State Power, Map of China’s Power Grid, Beijing, China,
2012.

[17] J. Li, “Renewable Energy Polices & Market in China,” 2012.
[18] Y. Zhong, China Wind Power Utilization and Development,

University Press, Zhenjiang, China, 2009.
[19] E. M. Jens, A. Delucchi, and M. Z. Jacobson, “A plan to power

100 percent of the planet with renewables,” Scientific American,
2003.

[20] L. Zhipeng, “Targets and suggested policy framework for
Renewable Energy Development in China,” China’s National
Energy Strategy and Reform Background Reports, 2003, 2012.

[21] L. Xiaoliang, “the story of Goldwind development,” Dafeng qixi
fengliu yong, Economic Daily, 2012.

[22] H. K. Alfares and M. Nazeeruddin, “Electric load forecasting:
literature survey and classification of methods,” International
Journal of Systems Science, vol. 33, no. 1, pp. 23–34, 2002.

[23] C. Chen, S. Duan, T. Cai, and B. Liu, “Online 24-h solar power
forecasting based on weather type classification using artificial
neural network,” Solar Energy, vol. 85, no. 11, pp. 2856–2870,
2011.

[24] A. S. S. Dorvlo, J. A. Jervase, and A. Al-Lawati, “Solar radiation
estimation using aritificial neural networks,” Applied Energy,
vol. 71, no. 4, pp. 307–319, 2002.

[25] J. Wu and C. K. Chan, “Prediction of hourly solar radiation
using a novel hybrid model of ARMA and TDNN,” Solar Energy,
vol. 8, no. 5, pp. 808–817, 2011.

[26] G. Reikard, “Predicting solar radiation at high resolutions: a
comparison of time series forecasts,” Solar Energy, vol. 83, no.
3, pp. 342–349, 2009.

[27] Q. Mu, Y. Wu, X. Pan, L. Huang, and X. Li, “Short-term load
forecasting using improved similar days method,” in Proceed-
ings of the Asia-Pacific Power and Energy Engineering Conference
(APPEEC ’10), pp. 1–4, March 2010.

[28] T. Cai, S. Duan, and C. Chen, “Forecasting power output for
grid-connected photovoltaic power system without using solar
radiation measurement,” in Proceedings of the 2nd International
Symposium on Power Electronics for Distributed Generation
Systems (PEDG ’10), pp. 773–777, June 2010.

[29] P. G. Zhang, “Time series forecasting using a hybrid ARIMA
and neural network model,” Neurocomputing, vol. 50, pp. 159–
175, 2003.

[30] S. Awerbuch and M. Berger, “Energy security and diversity
in the EU: a mean-variance portfolio approach,” IEA Report
EET/2003/03, Paris, France, 2003.

[31] M. Bolinger, R. Wiser, and W. Golove, “Accounting for fuel price
risk when comparing renewable to gas-fired generation: the role
of forward natural gas prices,” Energy Policy, vol. 34, no. 6, pp.
706–720, 2006.

[32] F. Frank, F. Gupta, and H. Markowitz, “The legacy of modern
portfolio theory,” The Journal of Investing Fall, pp. 7–22, 2002.

[33] Kleindorfer, R. Paul, and L. Li, “Multi-period VaR-constrained
portfolio optimization with derivative instruments and appli-
cations to the electric power sector,” Risk Management and
Decision Processes Center, The Wharton School, University of
Pennsylvania, Philadelphia, Pa, USA, 19104, 2002.

[34] S. G. Jensen, “Quantitative analysis of technological develop-
ment within renewable energy technologies,” in International

http://www.docstoc.com/docs/33202781/CHINA-NATIONAL-ACTION-PROGRAM-TO-COMBAT-DESERTIFICATION
http://www.docstoc.com/docs/33202781/CHINA-NATIONAL-ACTION-PROGRAM-TO-COMBAT-DESERTIFICATION
http://www.docstoc.com/docs/33202781/CHINA-NATIONAL-ACTION-PROGRAM-TO-COMBAT-DESERTIFICATION
http://purl.access.gpo.gov/GPO/LPS91600
http://purl.access.gpo.gov/GPO/LPS91600


The Scientific World Journal 9

Journal of Energy Technology and Policy, vol. 2, pp. 335–353,
2004.

[35] A. C. Stirling, “On the economics and analysis of diversity,”
Tech. Rep. 28, Science Policy Research Unit (SPRU) University
of Sussex, 1996.

[36] A. Stirling, “Diversity and ignorance in electricity supply
investment: addressing the solution rather than the problem,”
Energy Policy, vol. 22, no. 3, pp. 195–216, 1994.

[37] S. Awerbuch, “Portfolio-based electricity generation planning:
policy implications for renewables and energy security,” Mitiga-
tion and Adaptation Strategies for Global Change, vol. 11, no. 3,
pp. 693–710, 2006.

[38] S. Awerbuch, “Getting it right: the real cost impacts of a renew-
ables portfolio standard,” Public Utilities Fortnightly, 2000.

[39] S. Awerbuch, “Investing in photovoltaics: risk, accounting and
the value of new technology,” Energy Policy, vol. 28, no. 14, pp.
1023–1035, 2000.