Copyright © 2019 The Author(s). Published by VGTU Press

This is an Open Access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.
org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author 
and source are credited.

*Corresponding author. E-mails: k1271217@kingston.ac.uk; vincent_ajayi@yahoo.com

COMPARING MULTIVARIATE MODELS’ FORECASTS OF 
INFLATION FOR BRICS AND OPEC COUNTRIES

Olaoluwa Vincent AJAYI  *

Department of Economics, Kingston University, London, Penrhyn Road, KT1 2EE, United Kingdom

Received 25 June 2019; received in revised form 19 August 2019; accepted 26 September 2019

Abstract. Purpose  – This study identifies the most appropriately selected multivariate model for 
forecasting inflation in different economic environments. In specifying the multivariate models, the 
study test for the orders of integration of variables and for those that are nonstationary. For non-
stationary variables, this study examines whether they are cointegrated. Engle and Granger (1987) 
establish that a cointegrating equation can be represented as an error correction model that incor-
porates both changes and levels of variables such that all of the elements are stationary. However, 
VARs estimated with cointegrated data will be misspecified if all of the data are differenced because 
long-run information will be omitted, and will have omitted stationarity inducing constraints if all 
the data are used in levels. Further, including variables in both levels and differences should sat-
isfy stationarity requirements. However, they will omit cointegrating restrictions that may improve 
the model. Of course, these constraints will be satisfied asymptotically; but efficiency gains and 
improved multi-step forecasts may be achieved by imposing the constraints (Engle and Granger 
1987, p. 259). Therefore, this study test for order of integration and compare inflation forecasting 
performance of different multivariate models for BRICS and OPEC countries.
Research methodology  – The following approaches were considered; the first approach is to con-
struct a VAR model in differences (stationary form) to forecast inflation. The second approach is to 
construct a VECM without imposing cointegrating restrictions. The third approach is to construct 
a VEC that imposes cointegrating restrictions on the VECM. This will help to understand whether 
imposing cointegrating restrictions via a VEC improves long-run forecasts.
Research limitation – The proposed multivariate models focused on differencing and cointegrating 
restrictions to ensure the stationarity of the data, the available variables were combined and speci-
fied based on their level of integration to forecast inflation. For instance, a VAR model is estimated 
based on differenced variables I(0); the same holds true for VECM and VEC models, where dif-
ferenced variables and linear combinations of I(I) covariates are stationary. In future, multivariate 
models guided by economic theory rather than the order of integration of variables are suggested.
Findings – The result shows that the forecast performance of inflation depends on the nature of the 
economy and whether the country experiencing higher inflation or low inflation. For instance, the 
model that includes long-run information in the form of a specified cointegrated equation generally 
improves the inflation forecasting performance for BRICS countries and one OPEC country (Saudi 
Arabia) that has a history of low inflation.
Practical implications – This research will improve the policy makers decision on how to select ap-
propriate model to forecast inflation over different economic environment.

Business, Management and Education
ISSN 2029-7491 / eISSN 2029-6169

2019 Volume 17 Issue 2: 152–172

https://doi.org/10.3846/bme.2019.10556

mailto:k1271217@kingston.ac.uk
mailto:vincent_ajayi@yahoo.com
https://orcid.org/0000-0001-8122-0061
https://doi.org/10.3846/bme.2019.10556


Business, Management and Education, 2019, 17(2): 152–172 153

Introduction

Previous studies clearly indicates that performance of inflation forecasting depends on the 
type of model in use, monetary policy regime, the sample period, the variables included in 
the model, transformations applied to the data for stationarity and structural breaks as well 
as the length of the forecasting horizon (Lee, 2012, Ozkan & Yazgan, 2015). Buelens (2012) 
and Stock and Watson (2008) stated that the accuracy of a forecasting model depends on 
the sample period in which they are estimated and evaluated. For example, the appropriate 
forecasting model to be used prior to the economic crisis may be different from that during 
the economic crisis. Fanchon and Wendel (1992) observed that the predictive performance 
of VAR and VEC models depends on the length of the forecasting horizon. For instance, the 
multivariate VEC model outperformed the VAR model 11 and 13 months ahead forecasting 
horizons. Also, Stock and Watson (1999) argued that the Phillips curve produced a better 
forecast when estimated with real economic variables (GDP) than when estimating the Phil-
lips curve with the unemployment variable.

Multivariate specifications based on VARs and cointegration have been extensively used 
for modelling and forecasting macroeconomic variables in developed countries (especially, 
Europe and the United States) that have a history of low inflation (Hoffman, Anderson, & 
Rasche, 2002; Shoesmith, 1992, 1995a, 1995b; Timothy & Thoma, 1998). However, these 
methods have not been used to forecast inflation in many emerging economies such as OPEC 
and BRICS countries despite the importance of many of these countries to the global econ-
omy. This study fills this gap by evaluating the forecasting performance of inflation using 
multivariate VAR and cointegrating models for OPEC and BRICS countries.

BRICS countries comprise Brazil, Russia, India, China and South Africa. In recent times, 
they have emerged to form an international organisation body that will influence global 
financial trade and form a serious competitor to western economies. Accordingly, there are 
many common features between BRICS nations. For instance, they are fast developing na-
tions with one of the largest economies in their regions. China has the largest economy in 
Asia and is second only to America in the world. Russia is a member of the G8 advanced 
leading countries in the world, and India has the third-largest economy in Asia. South Africa 
has the second-largest economy in Africa after Nigeria, while Brazil has the largest economy 
in South America (World Economic Outlook, 2019). Global Sherpa (2014) found BRICS 
countries ranked among countries in the world with largest and most influential economies 
in the 21st century. They account for 25% of world GDP, over a quarter of the world’s land 
area and more than 40% of the global population. They control almost 43% of global foreign 

Originality/Value  – These methods have not been used to forecast inflation for many emerging 
economies such as OPEC and BRICS countries despite the importance of many of these countries 
to the global economy. This study fills this gap by evaluating the forecasting performance of inflation 
using multivariate VAR and cointegrating models for OPEC and BRICS economies.

Keywords: inflation forecasting, cointegrating and stability tests.

JEL Classification: B22, C12, C22, C52, C53, E31.



154 O. V. Ajayi. Comparing multivariate models’ forecasts of inflation for BRICS and OPEC countries

exchange reserves, and their share keeps rising (The Goldman Sachs Group, 2007; Agtmael, 
2012).

The organisation of petroleum exporting countries (OPEC) comprise Iran, Iraq, Kuwait, 
Saudi Arabia, Venezuela, Qatar, Angola, Indonesia, Libya, United Arab Emirates, Algeria 
and Nigeria. OPEC has a rich diversity of cultures, languages, religions and united by their 
shared status as oil-producing developing countries. Many of these countries heavily depend 
on exportation of petroleum, which has contributed to the higher percentage of their export 
earnings. For example, Nigeria earned 70% of its total export revenue from crude oil, Kuwait 
derived almost 60% of its gross domestic product and  93% of export revenue from crude 
oil, Libya acquired almost 95% of its government revenues. In Qatar, oil and natural gas ac-
counted for 60% of the country’s gross domestic product and around 85% of export earnings. 
In Saudi Arabia, the oil and gas  sector contributed to  50% of the gross domestic product 
and 90% of export earnings and in Venezuela, oil revenues accounted for about 95% of ex-
port earnings and 25% of gross domestic product (Organization of the Petroleum Exporting 
Countries, 2019). In total, the OPEC members produce almost 40% of the world’s crude oil, 
which represents almost 60% of the total petroleum traded internationally, produces about 
a third of the world’s daily consumption of 90 million barrels of crude oil, and controls 78% 
of the world’s crude oil reserves (Energy Information Administration, 2013).

This paper forecast inflation using different multivariate specifications. In particular, it 
is aims to identify the most appropriately selected multivariate model for forecasting infla-
tion in different economic environments. In specifying the multivariate models, this study 
faced different decisions, namely the variables to be included and how to deal with the non-
stationarity variables. For non-stationary variables, this study test for the orders of integra-
tion and examine whether they are cointegrated. Modelling and forecasting any series that 
is not stationary may lead to spurious results. Engle and Granger (1987) establish that a 
cointegrating equation can be represented as an error correction model that incorporates 
both changes and levels of variables such that all of the elements are stationary. However, “
VARs estimated with cointegrated data will be misspecified if all of the data are differenced 
because long-run information will be omitted, and will have omitted stationarity inducing 
constraints if all the data are used in levels. Further, including variables in both levels and 
differences should satisfy stationarity requirements. However, they will omit cointegrating 
restrictions that may improve the model. Of course, these constraints will be satisfied asymp-
totically; but efficiency gains and improved multi-step forecasts may be achieved by imposing 
the constraints ” (Engle & Granger, 1987, p. 259).

This study considers different multivariate specifications using differencing and cointe-
grating restrictions to ensure stationarity and to produce forecasts. The following approaches 
were considered, two of which are discussed by Timothy and Thomas (1998). The first ap-
proach is to construct a VAR model in differences (stationary form) to forecast inflation. 
The second approach is to construct a VECM without imposing cointegrating restrictions. 
The third approach is to construct a VEC that imposes cointegrating restrictions on the 
VECM. This will help understand whether imposing cointegrating restrictions via a VEC 
improves long-run forecasts. The empirical analysis addresses the following issues: which of 
these models produces the best forecasting performance for each country? Is there a gener-



Business, Management and Education, 2019, 17(2): 152–172 155

ally best performing specification across countries or for different forecasting horizons? Is it 
better to treat the oil price as endogenous or exogenous in multivariate models? Are models 
that use unemployment to capture the Phillips curve effect preferred to those that employ the 
output gap (when both variables are available)? Lastly, this study investigates whether each 
of the multivariate model (VAR, VECM and VEC) is structurally stable. If not, what is the 
implication of the instability for forecasting future inflation and what forecasting methods 
work well in the face of instability?

1. Literature review

There is a growing consensus that theoretical models are more accurate in forecasting when 
the economy is weak, especially during periods of economic crises, compared with ARIMA, 
Naïve and VAR models (Buelens, 2012; Dotsey, Fujita, & Stark, 2011; Onder, 2004). For ex-
ample, Onder (2004) used quarterly data between 1987: q1 and 1999: q4 to forecast Turkish 
inflation with the Phillips curve, ARIMA, Vector Autoregression (VAR), VECM and naive 
models. The evidence revealed that the Phillips curve model outperformed other models 
for one-quarter ahead forecasts and the prediction of the 2001 financial crisis. This result is 
similar to the study of Pretorious and Rensburg (1996) who forecasted South African infla-
tion and compared the forecasting abilities of different theoretical models (Phillips curve 
model, Traditional monetarist and money demand specifications) with the time series model 
(ARIMA) for the period 1991:q1‒ 1995:q3. The estimation period was divided into two dif-
ferent samples to reflect periods of stable and higher inflation. The study found that during 
the periods of higher inflation, the forecast produced by the money demand, Phillips curve 
and Traditional monetarist forecast models generated the lowest RMSE and MAE compared 
to the ARIMA model. However, the ARIMA models outperformed other multivariate models 
and theoretical model during periods of stable and low inflation.

A few studies also found Multivariate VAR model produce a better forecast than alterna-
tive models over the long horizon (Canova, 2007; Onder, 2004; Fritzer, Moser, & Scharler, 
2002; Fanchon & Wendel, 1992). For example, Gupta, Eyden, and Waal (2015) examine 
whether the global vector autoregressive (GVAR) approach forecasts better than a vector 
error correction model (VECM) and a BVAR model for two key South African variables, 
GDP output and inflation between the period 1979q2‒2009q4. Evidence revealed that the 
global multivariate VAR (GVAR) model outperforms VECM in forecasting inflation, espe-
cially at longer forecast horizons (more than four quarters ahead). However, the BVAR model 
was found to performs better than the best VECM when forecasting the output. Similarly, 
Fanchon and Wendel (1992) specified different multivariate VAR models (Vector error cor-
rection (VEC), VAR and Bayesian VAR models) to forecast cattle prices between the period 
of 1970‒1989. The VEC model differenced the data to achieve stationarity and used an error-
correction term to model the long-run information. The performance of all the estimated 
models was compared. The result shows that the VAR model generated the lowest mean 
square error for the 58‒ month horizon forecast. The VEC model outperformed the VAR 
model for 11 and 13-month horizons. The VAR and VEC models outperformed the Bayesian 
VAR models. They concluded that the performance of VAR and VEC models depend on the 
length of the forecast horizon.



156 O. V. Ajayi. Comparing multivariate models’ forecasts of inflation for BRICS and OPEC countries

Recent literature indicates the forecasting by a multivariate model (either by VAR or VECM) 
generally better than that of an alternative model (ARIMA and naive model). For example, 
Shan and Ghonasgi (2016) forecasted Indian inflation over a 24-period horizon and compared 
the predictive performance of the VAR with ARIMA models between 1994–2008. The VAR 
model has better forecasting performance than the ARIMA model. Also, Kelikume and Salami 
(2014) applied the ARIMA and VAR models to forecast inflation for Nigeria between January 
2003 and December 2012 and found the VAR model outperformed the ARIMA specification.

The conclusion from this section is that the theoretical model, especially the Phillips 
curve, more accurately forecasts inflation when the economy is weak, especially during the 
economic crises, compared with the univariate ARIMA model. In contrast, the ARIMA 
models outperform other multivariate models and theoretical model (Phillips curve) during 
periods of stable and low inflation (Dotsey & Fujita, 2011; Lee, 2012; Mitra & Rashid, 1996; 
Nadal-De Simone, 2000; Pretorious & Rensburg, 1996). When comparing VAR models with 
VECM models, the former outperformed the latter over the longer horizon (more than four 
quarters ahead) (Fanchon & Wendel, 1992; Gupta et al., 2015).

This study compares the forecasting performance of multivariate VAR-based specifica-
tions and the naïve model for selected OPEC and BRICS countries. There have been very few 
such studies for these countries, especially for samples covering the recent period.

2. Empirical methods

This section describes the process of modelling with Vector autoregression (VAR) based 
specifications and the naïve model.

VAR is a stochastic process model that captures linear interdependencies among multiple 
time series and is estimated using differenced stationary data. The VECM model can be dis-
tinguished from the VAR model by including an error‒correction term and is estimated with 
the nonstationary series that is known to be cointegrated. The VEC model imposes a coin-
tegrating restriction on VECM. The unrestricted VAR approach models every endogenous 
variable in the system as a function of the lagged values of all of the endogenous variables in 
the system and can be specified as:

 ty  = 1 1tA y −  +….+ p t pA y −  + tBx  + te , (1)
where ty  is a k  vector of the endogenous variables, tx  is a d  vector of exogenous variables, 

1A ,…..,  pA  and B  are matrices of coefficients that need to be estimated, and te  is a vector of 
innovations that may be contemporaneously correlated however they are uncorrelated with 
their own lagged values. The VECM representation of (1) is:

 ty∆  = δ  + tBx + 1ty −Π + 1 1ty −Γ ∆ +….+ 1 1p t py− − +Γ ∆  + te , (2)
where, iΓ , i  =1 ,…, 1p − , (which are functions of iA ) reflect the short-run dynamic rela-
tionship. ty  are independent ( )1I  variables, ∆  = ( )1 L−  while L  is the lag operator, δ  is 
the intercept, Π  is the matrix containing long-run information and te  is the residual. The 
Granger representation theorem indicates that if the matrix  Π has reduced rank r < k it can 
be decomposed as Π  = ′αβ . The dimension of α  and β  is r  x k . The number of cointe-
grating equations is r, where β  is the cointegrating vector and α  is the speed of adjustment 
to the long-run equilibrium defined by the cointegrating relationships, which is determined 



Business, Management and Education, 2019, 17(2): 152–172 157

primarily by the likelihood ratio (LR) trace test. Imposing r  cointegrating equations on (2) 
gives the VEC representation. In this study, 1r =  for all our VEC specifications.

In VAR modelling, the first step is to estimate a VAR model with an appropriate lag length 
sufficient to capture the full dynamics of the system. The choice of appropriate lag order (p) 
is important because too short a lag length may not be able to remove the autocorrelation in 
the residuals and too long a lag length may reduce the precision (efficiency) of the estimates 
due to a reduction of degrees of freedom (Lack, 2006). This research chooses the maximum 
possible lag length (P*) as 10 for all countries except where only lower orders can be esti-
mated. Different maximum lag lengths will be considered when the experimentation reveals 
a lag length below 10 cannot reject the hypothesis of no autocorrelation. Also, the Akaike 
information criterion (AIC) and Schwarz criterion (SC) will be employed to determine the 
initial lag length P**. If there is no evidence of autocorrelation (of orders 1, 2, … 10), this 
initial lag length is selected. However, if there is evidence of autocorrelation, the VAR model 
is re-estimated using a lag length of P**+1. The process is repeated until the VAR model 
cannot reject the hypothesis of no- autocorrelation at the 5% level.

Further, Atkeson and Ohanian (2001) argued that an inflation forecasting model based on 
some hypothesised economic relationship cannot be considered a useful guide for policy if 
its forecasting performance is not better than a simple naïve model. This study estimates the 
naïve model as a benchmark model and compares its forecasting performance with the best 
selected multivariate models. The naïve model can be estimated by equating the observed 
value in the last quarter of the estimation period to forecast the present quarter, that is:

 T hy +  = Ty , (3)
where T hy +  is the h  period ahead forecast and Ty  is the observed data in the last period 
of the estimation sample.

3. Data and variable selection

Quarterly and annual data are collected from the World Bank, United Nation (UN DATA), 
Organisation for Economic Co-operation and Development (OECD) and International Fi-
nancial Statistics (IFS) published by the International Monetary Fund (IMF). In selecting 
variables for the multivariate model, this study focuses on those commonly and mostly used 
to explain and forecast inflation in the literature as well as where the data is available (because 
there are some data constraints). An eclectic theoretical approach is considered in the sense 
of combining variables from different economic theories in the VAR specification.

The approach follows in this study includes the following steps: The VAR model is first 
specified based on variables available at quarterly frequency across the whole sample for any 
particular country. The variable may include money supply, interest rates and consumer prices 
(from which inflation can be generated). The ability of VAR model based on these variables are 
examined to forecast inflation. To avoid model misspecification (in particular omitted variable 
issues), additional information is incorporated, that is, added variables that are available only 
annually over the available sample and use frequency conversion tools to generate quarterly 
series. In this case, the VAR models, including all the available inflation determinants for each 
country are considered. In particular, the VARs are based on (a subset of ) consumer prices, 
money supply, interest rates, real effective exchange rates, the output gap (or, alternatively the 



158 O. V. Ajayi. Comparing multivariate models’ forecasts of inflation for BRICS and OPEC countries

unemployment rate) as well as the world oil price. In addition, the index of industrial produc-
tion or real output measured by real GDP is used to construct the output gap. When estimating 
output gap, this study follows Stock and Watson (1999) and use the Hodrick-Prescott (HP) 
filter. The general features of selected macroeconomic variables, shown in Table 1, were identi-
fied in each country by mainly focusing on seasonality and stationary characteristics to avoid 
the issue of seasonal integration. For each series, the autocorrelation functions of each series 
were plotted and if this indicated seasonality, the data was adjust seasonally using the Census 
X13 method. The seasonal indices obtained from the adjustment process were saved and used 
to reintroduce seasonality into the forecasts produced by this study. This study also employs the 
DF-GLS, augmented Dickey-Fuller (ADF), Phillips and Perron (PP) and Kwiatkowski–Phillips–
Schmidt–Shin (KPSS) unit root tests to identify the variables’ orders of integration (Vogelsang 
& Perron, 1998; Perron, 1989). A summary of the data employed for each country and whether 
the data is seasonally adjusted or not as well as the orders of integration of these variables is 
given in Table 1, 2 and 3, respectively. All variables are transformed using natural logarithms 
except for the interest rate, unemployment and output gap.

Table 1. Summary of data availability for all the countries

Countries Sample Variables

Brazil 1999q4 2012q4 P, M, R, REE, UN, GAP and Oilp

Russia 2003Q2 2012q4 P, M, R, REE, UN, GAP and Oilp

India 1963q1 2012q4 P, M, R, GAP and Oilp
China 1992q1 2012q4 P, M, R, REE, GAP and Oilp

South Africa 1995q2-2012q4 P, M, R, REE, GAP and Oilp

Algeria 1999q2 2012q4 P, M, R, REE, GAP and Oilp

Angola 2002q4 2012q4 P, M, R, GAP and Oilp
Nigeria 1998q4 2012q4 P, M, R, REE, GAP and Oilp

Saudi Arabia 1983q1 2012q4 P, M, R, GAP and Oilp
P = consumer price, M = money supply, REE = real exchange rate, GAP = output gap, R = interest rate, 
UN = unemployment and Oilp = oil price.

Table 2. Summary of whether the data is seasonally adjusted or not

Countries / Variables BRA RUS IND CHI SOU NIG ALG ANG SAU

P UN SA SA UN UN SA SA UN UN
M SA UN UN UN UN UN UN SA UN
R UN UN UN UN UN UN UN UN
REE UN UN UN UN UN UN UN
U UN SA
OilP UN UN UN UN UN UN UN UN UN
GAP UN SA UN UN UN UN UN UN UN

SA indicates seasonally adjusted series and UN indicates unadjusted series. Blank indicates where the 
data is unavailable for the variable in that particular country. The country is represented by its first 
three letters.



Business, Management and Education, 2019, 17(2): 152–172 159

Table 3. Orders of integration of the data

Variables/Countries BRA RUS IND CHI SOU NIG ALG ANG SAU

P I(1) I(1) I(1) I(1) I(1) I(1) I(1) I(1)** I(1)
M I(1) I(1) I(2) I(1) I(1) I(1) I(1) I(1) I(1)
R I(1) I(0) I(0) I(1) I(1)* I(1) I(1) I(1)*

REE I(1) I(1) I(1) I(1) I(1) I(1) I(1)
U I(1) I(1)
OilP I(1) I(1) I(1) I(1) I(1) I(1) I(1) I(1)
GAP I(0) I(1) I(0) I(0) I(0) I(0) I(0) I(0) I(0)

* Indicates a variable that may be stationary around a structural break while ** denotes a variable that 
may be I(1) around a structural break.

4. Model specifications

Based on the orders of integration of the data reported in Table 3, the following three mul-
tivariate models are estimated: first, an unrestricted VAR model that includes variables only 
in stationary form (typically through differencing); second, a VECM that includes all I(1) 
variables as endogenous. A test is conducted to determine whether a linear combination of 
the nonstationary variables is cointegrated, and if cointegrated the model is used to produce 
forecasts for inflation. Third, a VEC model is constructed that imposes a single cointegrating 
equation on the VECM to forecast inflation. Based on this analysis, the forecasting perfor-
mance of all three multivariate specifications (VAR, VECM and VEC) are compared to the 
naïve model and to identify the best inflation forecasting model.

For the unrestricted VAR, four different variants for Brazil and Russia are estimated.1 The 
first VAR model includes the output gap and excludes unemployment with all other available 
variables included. The second VAR includes unemployment and excludes the output gap 
with all other available variables included. The aim of these two VARs is to consider whether 
the VAR that includes the output gap provides superior forecasts to the VAR model that in-
cludes unemployment. The remaining two VARs are the same as the first two VARs, except 
the oil price is treated as exogenous because international oil prices are best regarded when 
determined outside the system for some countries  – although, for oil producing countries 
or large oil-consuming countries, such as China, the assumption of endogeneity may be 
more appropriate. That is, these VARs considers oil price exogenous and all other available 
variables endogenous. The motivation behind the latter two VARs is to examine the impact 
of treating oil prices as exogenous on the inflation forecasts.

For the remaining countries (China, South Africa, Algeria, Angola, Nigeria and Saudi 
Arabia), two VARs were estimated. The first VAR model considers all variables as endog-
enous. The second VAR model treats the oil price as exogenous and all other available vari-
ables as endogenous. All VAR models consider the intercept to be exogenous. The model 

1  These two countries have two substitute variables for the economic activity measure (output gap and unemploy-
ment).



160 O. V. Ajayi. Comparing multivariate models’ forecasts of inflation for BRICS and OPEC countries

where oil prices are specified as exogenous, the oil price forecast produced between 2013q1a-
nd 2014q4 based on an ARIMAX forecasting method is considered. A summary of the valid 
VAR, VECM and VEC models that are free from evident autocorrelation are available in 
Table 4 and 5 for stability test.

5. Stability tests for multivariate models

The stability of each multivariate model in Table  4 and 5 were determined to understand 
whether they have stable coefficients across the entire estimation sample. If not, the implica-
tions of the instability on forecasting inflation and type models that work well in the face of 
instability were examined. This study performs a CUSUM test for stability tests. The CUSUM 
test is based on the cumulative sum of the recursive residuals. If the line of the CUSUM 
test statistics fluctuates within the two 5% critical lines, the estimated models are said to be 
stable. In contrast, the models are unstable if the line of the CUSUM test goes outside the 
area between the 5% critical lines. The summarised results of the stability tests are available 
in Tables 4 and 5 for BRICS and OPEC countries, respectively.

Table 4. Summary of the stability tests for BRICS countries

Model CUSUM test results

Brazil
VAR(GAP) Unstable
VAR(UN) Unstable
VAR(GAP)_Exo Stable
VAR (UN)_Exo Stable
VECM(UN) Stable
VECM(UN)_Exo Stable
VEC(UN) Unstable
VEC(UN)_Exo Stable
Russia
VAR(UN) Stable
VAR(UN)_Exo Unstable
VECM (UN) Stable
VECM(GAP) Stable
VECM(GAP)_Exo Stable
VECM(UN)_Exo Stable
VEC(UN) Unstable
VEC(GAP) Unstable
VEC(GAP)_Exo Unstable
VEC(UN)_Exo stable



Business, Management and Education, 2019, 17(2): 152–172 161

Model CUSUM test results

India
VAR Stable
VAR_Exo Stable
VECM Stable
VECM_Exo Stable
VEC Unstable
VEC_Exo Unstable
China
VAR Unstable
VAR_Exo Unstable
VECM Stable
VECM_Exo Stable
VEC Unstable
VEC_Exo Unstable
South Africa
VAR Unstable
VAR_Exo Stable
VECM Stable
VECM_Exo Stable
VEC Unstable
VEC_Exo Unstable

Stable  = result of the CUSUM test where the lines of CUSUM tests lie within the two critical lines. 
Unstable = result of the CUSUM test where the lines of CUSUM tests lie outside the two critical lines; 
VAR = VAR model that considers all variables endogenous; VECM = multivariate model estimated with 
all nonstationary variables that consider all variables endogenous; VEC = Multivariate model imposes 
cointegrating restrictions on the VECM and considers all variables endogenous.2

2 VAR_Exo = VAR model that considers oil price exogenous and other variables endogenous; VECM_exo = VECM 
specification that considers oil price as exogenous and other variables as endogenous; VEC_Exo = VEC model that 
considers oil price as exogenous and other variables as endogenous. For Brazil and Russia, where the unemploy-
ment and output gap variables are available; VAR(UN) = VAR, where all variables are considered endogenous 
except output gap, which is excluded; VAR(GAP) = VAR where all variables are considered endogenous except 
the unemployment variable, which is excluded; VAR(UN)_Exo  = VAR where oil price is specified as exogenous 
and all other variables as an endogenous variable, except for output gap; VAR (GAP)_Exo = VAR where oil price 
is specified as exogenous and all other variables as endogenous variables, except for the unemployment variable; 
VECM(UN) = VECM that considers all variables endogenous except for the output gap; VECM(UN)_Exo  = 
VECM where oil price is specified as exogenous and all other variables as endogenous variables, except for the 
output gap, which is excluded; VECM(GAP) = VECM that considers all variables endogenous except for the un-
employment variable; VECM(GAP)_EXO = VECM where oil price is specified as exogenous and all other variables 
as endogenous variables, except for the unemployment variable, which is excluded; VEC(UN) = VEC, where all 
variables are considered endogenous except for the output gap, which is excluded; VEC(GAP) = VEC, where all 
variables are considered endogenous except for the unemployment variable, which is excluded; VEC(UN)_Exo = 
VEC, where oil price is specified as exogenous and all other variables as endogenous except for output gap; 
VEC(GAP)_Exo = VEC, where oil price is specified as exogenous and all other variables are endogenous variables 
except the unemployment variable.



162 O. V. Ajayi. Comparing multivariate models’ forecasts of inflation for BRICS and OPEC countries

Table 5. Summary of the stability tests for OPEC countries

Model CUSUM test results

Algeria
VAR Stable
VAR_Exo Stable
VECM Stable
VECM_Exo Stable
VEC Unstable
VEC_Exo Unstable
Angola
VAR Unstable
VAR_Exo Unstable
VECM Unstable
VECM_Exo Stable
VEC Unstable
VEC_Exo Unstable
Nigeria
VAR Unstable
VAR_Exo Stable
VEC Unstable
VEC_Exo Unstable
Saudi Arabia
VAR Stable
VAR_Exo Stable
VECM Stable
VECM_Exo Stable
VEC Unstable
VEC_Exo Unstable

Note: see Table 4.

For the BRICS countries (Table  4), the CUSUM test suggests evidence of instability for 
all models except the following: all VECM models for all selected countries, all VARs speci-
fication for India, South Africa and Brazil (except for the VAR where all variables included 
as endogenous except the unemployment variable, which is excluded, the VAR where all 
variables are considered endogenous except output gap, which is excluded for Brazil and the 
VAR model that considers all variables endogenous for South Africa). The following models 
are also structurally stable: the VEC model where the oil price is specified as exogenous and 
all other variables included as endogenous variable except output gap for Brazil and Russia.



Business, Management and Education, 2019, 17(2): 152–172 163

For OPEC countries (Table  5), all models show evidence of structural instability except 
the VAR and VECM specifications, which consider all variables endogenous for Saudi Arabia, 
the VECM model that specifies oil price as exogenous for Angola, as well as the VAR and 
VECM specifications for Algeria.

In general, the CUSUM test indicates evidence of instability in the coefficients for the 
VAR, VECM and VEC for both BRICS and OPEC countries (except VECM for BRICS). 
This study produces forecasts for all models presented in Table 4 and 5 despite the evidence 
of structural instability for many of these specifications because the literature suggests that 
models being subject to structural instability may or may not affect their forecasting per-
formance (Clark & Mccacken, 2006; Stock & Watson, 1999). Hence, it will be interesting to 
see whether models with evident instabilities have poor forecasting performance in either 
absolute or relative terms.

6. Forecast performance and evaluation

The m-step ahead forecasts are made for the valid VAR, VEC and VECM models reported 
in Table 4 and 5. Following Sarantis and Stewart (1995), Alles and Horton (2002); Ogunc et 
al. (2013) and Garcia, Medeiros, and Vasconcelos (2017); the forecasting performance were 
compared using rolling regressions. First, a series of rolling regressions were conducted and 
out-of-sample forecasts calculated for all the multivariate models free from autocorrelation. 
Each model is estimated over the sample period available for each country with the period 
ending in 2012q4 (the start of the estimation period varies across models and countries). 
These models are used to produce forecasts over the ex-post forecasting period 2013q1–
2014q4. These produce 1-step ahead forecasts for 2013q1, 2-step ahead forecasts for 2013q2 
and so on up to 8-step ahead forecasts for 2014q4. The identified models were then re-esti-
mated by adding one observation to the end of the sample, hence the models are estimated 
over a period ending in 2013q1. These estimated models are used to produce 1-step ahead 
forecasts for 2013q2, 2-step ahead forecasts for 2013q3 and so on up to 7-step ahead forecasts 
for 2014q4. This process is then repeated with one observation being added to the estimation 
period (with the last rolling regression’s sample period ending in 2014q3), and m-step ahead 
forecasts produced up to the end of the forecast period. These rolling regressions produce 
eight 1-step ahead forecasts, seven 2-step ahead forecasts, six 3-step ahead forecasts, five 
4-step ahead forecasts and so on up to one 8-step ahead forecast for each estimated model. 
Second, the forecasting performance of each model over the different step ahead forecast-
ing horizons using the Root Mean Squared Error (RMSE), Mean Absolute Percentage Error 
(MAPE) and Theil’s inequality coefficient (U) are calculated. The best forecasting model over 
any horizon will have the lowest value of these forecasting performance measures. To avoid 
space, only the forecast produced by the naïve model with the best forecasting multivariate 
models for each country were recorded, shown in the Tables 6 and 7 (the details of the fore-
cast produced by the VAR, VECM and VEC are available on request).



164 O. V. Ajayi. Comparing multivariate models’ forecasts of inflation for BRICS and OPEC countries

Table 6. Summary of the best forecasting multivariate models for OPEC countries

1-step 2-step 3-step 4-step 5-step 6-step 7-step 8-step

Algeria Naïve 
model

RMSE 0.012 0.017 0.019 0.029 0.020 0.016 0.016 0.017

MAPE 76.740 111.200 108.200 136.000 147.200 55.960 30.380 38.770
U 0.173 0.267 0.265 0.243 0.266 0.195 0.1670 0.168

VAR_
Exo

RMSE 0.007* 0.012* 0.017* 0.027 0.027 0.025 0.016* 0.0003*

MAPE 44.074* 101.566* 102.855* 257.60 207.500 94.940 29.649* 30.555*
U 0.098* 0.180* 0.255* 0.338 0.313 0.263 0.157* 0.003*

VEC 
(GAP)_
Exo

RMSE 0.012 0.016 0.019 0.021* 0.016* 0.014* 0.016 0.029

MAPE 66.931 114.508 111..534 132.570* 112.274* 38.803* 30.550 48.950
U 0.157 0.240 0.274 0.207* 0.232* 0.185* 0.204 0.324

Angola Naïve 
model

RMSE 0.007 0.013 0.017 0.022 0.022 0.015 0.013 0.013

MAPE 18.100 20.050 20.730 21.680 29.990 30.640 27.600 16.970
U 0.094 0.116 0.117 0.194 0.147 0.148 0.130 0.088

VAR RMSE 0.007* 0.008* 0.007* 0.006* 0.009* 0.009* 0.008* 0.005*
MAPE 7.203* 12.626* 19.545* 20.047* 27.366* 18.621* 17.984* 16.308*
U 0.047* 0.085* 0.111* 0.136* 0.138* 0.097* 0.091* 0.079*

Saudi 
Arabia

Naïve 
model

RMSE 0.004 0.007 0.011 0.014 0.017 0.020 0.025 0.026

MAPE 10.980 21.810 36.910 50.880 62.060 72.960 87.830 92.610
U 0.070 0.128 0.238 0.342 0.450 0.574 0.771 0.862

VECM RMSE 0.002* 0.003* 0.003* 0.003* 0.003* 0.002* 0.001* 0.001*
MAPE 7.828* 10.060* 10.930* 10.270* 12.710* 9.188* 2.891* 2.427*
U 0.046* 0.061* 0.064* 0.058* 0.063* 0.046* 0.015* 0.012*

Nigeria Naïve 
model

RMSE 0.025 0.044 0.066 0.078 0.086 0.090 0.099 0.123

MAPE 21.830 48.040 72.650 92.760 101.500 107.800 116.500 153.000
U 0.139 0.218 0.296 0.330 0.350 0.359 0.377 0.433

VAR RMSE 0.021 0.036 0.048* 0.050* 0.037* 0.027* 0.024* 0.013*
MAPE 19.121 38.90 54.872* 59.583* 37.772* 29.997* 28.762* 17.152*
U 0.111 0.182 0.220* 0.242* 0.193* 0.147* 0.112* 0.079*

VAR_
Exo

RMSE 0.019* 0.033* 0.051 0.053 0.041 0.031 0.025 0.044

MAPE 18.075* 37.632* 56.531 63.63 47.18 36.42 29.73 49.690
U 0.105* 0.169* 0.238 0.248 0.204 0.159 0.133 0.199

See Table 6 for definition of each model. The best multivariate forecasting model is identified by meas-
ure (RMSE, MAPE and U) and asterisk* for each forecasting horizon (1, 2, …, 8 steps ahead). 



Business, Management and Education, 2019, 17(2): 152–172 165

Table 7. Summary of the best forecasting multivariate models for BRICS countries

1-step 2-step 3-step 4-step 5-step 6-step 7-step 8-step

Brazil Naïve model RMSE 0.005 0.006 0.006 0.004 0.004 0.027 0.028 0.002

MAPE 6.699 9.612 8.738 4.885 5.417 9.859 12.310 13.014
U 0.040 0.052 0.049 0.029 0.025 0.053 0.066 0.015

VAR(UN) RMSE 0.006 0.012 0.013 0.011 0.015 0.020 0.014* 0.001*
MAPE 8.533 17.66 18.470 17.650 23.510 28.970 12.090* 12.440*
U 0.046 0.090 0.097 0.085 0.110 0.143 0.002* 0.011*

VEC(UN) RMSE 0.004 0.007 0.006 0.004 0.009 0.019 0.017 0.011
MAPE 5.181 10.100 6.880* 4.906 9.919 24.460 24.110 18.080
U 0.029 0.056 0.045* 0.029 0.066 0.137 0.133 0.083

VEC 
(UN)_Exo

RMSE 0.004* 0.006* 0.005* 0.003* 0.003* 0.013* 0.019 0.017
MAPE 5.084* 7.054* 7.304 4.479* 3.542* 9.830* 29.040 28.860
U 0.021* 0.044* 0.052 0.025* 0.022* 0.012* 0.134 0.126

Russia Naïve model RMSE 27.111 49.350 48.790 54.980 73.400 51.870 47.930 85.540
MAPE 23.760 45.730 44.610 49.940 65.090 52.180 55.600 112.600
U 0.116 0.196 0.194 0.218 0.285 0.218 0.212 0.360

VAR(GAP) RMSE 0.008 0.015* 0.0185 0.013 0.017 0.031 0.042 0.053
MAPE 8.867 14.690* 19.313 16.138 19.918 37.316 49.234 56.152

U 0.058 0.100* 0.124 0.085 0.122 0.227 0.320 0.394
VAR(UN) RMSE 0.009 0.019 0.015* 0.012* 0.051 0.022 0.027* 0.031*

MAPE 8.208 15.218 15.205* 14.408* 23.698 24.699 28.006* 33.366*
U 0.063 0.130 0.106* 0.086* 0.104 0.155 0.187* 0.200*

VAR(UN)_
Exo

RMSE 0.009 0.022 0.022 0.019 0.013* 0.019* 0.034 0.059
MAPE 9.095 20.789 21.252 20.689 0.150* 22.815* 40.623 62.371
U 0.064 0.153 0.148 0.124 0.088* 0.131* 0.251 0.453

VEC(GAP) RMSE 0.007* 0.015 0.022 0.021 0.025 0.037 0.045 0.056
MAPE 7.940* 18.103 23.916 25.771 27.892 43.893 51.781 58.632
U 0.049* 0.105 0.150 0.147 0.186 0.285 0.349 0.414

VEC 
(GAP)_Exo

RMSE 0.009 0.021 0.0273 0.027 0.0279 0.039 0.056 0.077
MAPE 11.667 26.099 33.324 32.166 28.511 47.853 65.972 80.493
U 0.057 0.100 0.192 0.197 0.209 0.312 0.479 0.674

India Naive model RMSE 10.701 17.570 22.240 17.730 19.090 19.770 29.290 37.020
MAPE 15.215 24.670 18.810 29.760 28.570 29.400 33.610 48.740
U 0.152 0.133 0.132 0.182 0.188 0.193 0.141 0.196

VEC RMSE 0.012* 0.018* 0.018* 0.021* 0.017* 0.017* 0.016* 0.014*
MAPE 14.620* 20.910* 17.490* 28.760* 26.560* 26.660* 23.870* 28.890*
U 0.066* 0.104* 0.110* 0.132* 0.117* 0.124* 0.122* 0.126*



166 O. V. Ajayi. Comparing multivariate models’ forecasts of inflation for BRICS and OPEC countries

1-step 2-step 3-step 4-step 5-step 6-step 7-step 8-step

China Naïve model RMSE 1.541 2.360 2.806 3.720 5.423 7.522 10.660 11.250
MAPE 7.191 13.788 15.915 19.417 23.848 27.91 39.005 61.91
U 0.086 0.770 0.132 0.129 0.122 0.173 0.344 0.363

VAR RMSE 0.006 0.011 0.010 0.013 0.016 0.017* 0.023* 0.030*
MAPE 10.281 16.464 14.271 18.873 22.643 25.104* 38.205* 51.647*
U 0.057 0.091 0.093 0.121 0.154 0.168* 0.240* 0.348*

VEC RMSE 0.004* 0.007* 0.010* 0.012* 0.016* 0.022 0.026 0.033
MAPE 5.001* 11.636* 12.310* 18.109* 22.292* 30.721 42.81 55.378
U 0.034* 0.067* 0.089* 0.113* 0.114* 0.214 0.282 0.382

South 
Africa

Naïve model RMSE 4.512 10.640 12.950 11.040 4.355 4.579 2.757 10.560
MAPE 10.041 13.900 14.43 9.856 8.077 12.816 18.175 12.350
U 0.118 0.112 0.091 0.043 0.047 0.059 0.061 0.078

VEC RMSE 0.006 0.009 0.011* 0.006* 0.005* 0.007* 0.007* 0.003*
MAPE 9.001 12.676 13.350* 8.706* 6.174* 10.260* 10.085* 5.751*
U 0.057 0.060 0.061* 0.040* 0.045* 0.040* 0.058* 0.029*

VEC_Exo RMSE 0.006* 0.009* 0.011 0.007 0.007 0.011 0.011 0.006
MAPE 8.716* 12.199* 15.098 12.280 12.280 16.500 15.631 10.681
U 0.057* 0.078* 0.093 0.066 0.076 0.093 0.088 0.056

See Table 6 for definition of each model. The best multivariate forecasting model is identified by meas-
ure (RMSE, MAPE and U) and asterisk* for each forecasting horizon (1, 2, …, 8 steps ahead).

7. Empirical results

Table  6 summarises the best forecasting multivariate models for OPEC countries in each 
forecasting horizon while Table  7 summarises the best forecasting models for the BRICS 
nations in each forecasting horizon. A general impression from the tables is that there is 
no single model that dominates across all countries. It was generally found that while both 
unemployment and the output gap are available as indicators of the Phillips curve (for Brazil 
and Russia), models including unemployment outperform those that use output gap. This 
view is contrary to the studies of Bjornland, Jore, Smith, and Thorsrud (2008) and Stock 
and Watson (1999), who argue that models including output gap contain the most valu-
able information in inflation forecasting rather than models based on alternative indicators 
(unemployment).

The VAR model often produces the best forecasting performance for OPEC countries 
except in Saudi Arabia, which has a history of relatively low inflation. VAR models have 
superior forecasting performance over all forecasting horizons for Algeria (except over the 4 
to 6 step-ahead horizons), Angola and Nigeria. In contrast, the VAR model rarely produced 
the best forecasts for BRICS countries. VAR models were only favoured over the 7 to 8 step 
ahead horizons for Brazil, 6 to 8 step-ahead horizons for China and the 2 to 8 step ahead 
horizons for Russia. VECM was only favoured for 1 out of the 4 selected OPEC countries 



Business, Management and Education, 2019, 17(2): 152–172 167

(Saudi Arabia over all forecasting horizons) and was never favoured for BRICS countries. 
The VEC models have better forecasts over all forecasting horizons for all BRICS countries 
with the following exceptions: China over the 6 to 8 step ahead horizons, Brazil over the 7 
to 8 step ahead horizons and Russia over the 2 to 8 step ahead horizons. However, the VEC 
model is rarely favoured for the selected OPEC countries (VEC is only favoured over the 4 
to 6 step ahead horizon for Algeria). The naïve model was never favoured.

In general, the results of this study indicate that VAR models have the best forecast-
ing performance for OPEC countries while the VEC model produces better forecasts for 
BRICS countries. The forecasting performance of the VEC model for BRICS countries 
and possibly the VECM for Saudi Arabia may be because inflation in many of these coun-
tries is relatively moderate and kept in check by good monetary policy, especially when 
compared with OPEC countries. As noted earlier, forecasts are most likely to improve by 
applying error-correction techniques if the data strongly supports the cointegration hy-
pothesis (Engle & Yoo, 1987). The VEC specification can also minimise the effect of model 
misspecification and thus avoid the long-run information lost due to non-differentiating 
a stationary variable (see Christoffersen & Diebold, 1998; Sa-ngasoongsong, Bukkapat-
nam, Kim, Iyer, & Suresh, 2012). Also, the evidence of good forecast performance of the 
unrestricted VAR models for OPEC countries may not be surprising because these VAR 
models have been estimated using the stationary series. The model estimated using first 
differencing (stationary data) has the ability to capture different characteristics of instabil-
ity in high inflation economy such as OEPC countries. Indeed, the results of this study 
generally support the view that the inclusion of cointegrating equations improve the infla-
tion forecasting performance for BRICS countries and Saudi Arabia (both have a history 
of low inflation). Notably, the naïve benchmark models were never favoured over the best 
forecasting multivariate models for each country. This result contrasts with that of Atkeson 
and Ohanian (2001) who found that the naïve model produces superior forecasts than the 
multivariate VAR-based models.

Whether the inclusion of oil prices as exogenous or endogenous improves forecast-
ing performance differs substantially according to the form of model employed and the 
country under consideration. For both BRICS and OPEC countries, the model that con-
siders the oil price endogenous generally secures better forecasting performance than the 
model that considers the oil price exogenous. Exception include Algeria over all forecast-
ing horizons, Brazil over the 1 to 6 step ahead horizons, Russia over the 5 to 6 step ahead 
horizons and over the 1 to 2 step ahead horizons for both South Africa and Nigeria. This 
is interesting because both BRICS and OPEC countries dependent heavily on oil import 
for domestic consumption and/or oil export for revenue (Organization of the Petroleum 
Exporting Countries, 2019). Therefore, increases or decreases in the global oil price will 
directly affect the government revenue and expenditure in many of these countries. How-
ever, the impact of oil shock on inflation in few economies especially Algeria, Brazil, South 
Africa, Russia and Nigeria, over a few steps may not be a surprise because many of these 
countries have recently implemented good monetary policies to manage their inflationary 
pressures. Therefore, it is possible good monetary policy can help to minimise the impact 



168 O. V. Ajayi. Comparing multivariate models’ forecasts of inflation for BRICS and OPEC countries

of changes in the global oil price for this country.3 This view is supported by the findings 
of Hooker (2002), Taylor (2000), Cologni and Manera (2008), Chen (2009), LeBlance and 
Chinn (2004), Mandal, Bhattcharya, and Bhoi (2012) and Dedeoglu and Kaya (2014) who 
indicate that the effect of the oil price on inflation is weaker when adequate monetary 
policies are implemented.

The range of the MAPE values for all favoured models for BRICS and OPEC countries 
is above 20 percentage points except for South Africa (5% to 14%), Brazil (5% to 13%) and 
Saudi Arabia (2%–13%) that have a history of the lower inflation. This suggests that countries 
with higher inflation will likely have higher MAPE values.

The stability test indicates that the stability of a model can enhance inflation forecasting 
performance for a few countries. For example, structurally stable models produce the best 
forecasts for 3 out of 4 selected OPEC countries. In particular, the favoured VAR specification 
is stable and produces the best forecasting performance for Algeria and Nigeria (at least 2 
steps ahead). The favoured VECM specification that is structurally stable produces the best 
forecast over all horizons for Saudi Arabia. In contrast, all the best forecasting multivariate 
models for BRICS countries are structurally unstable. The good forecasting performance of 
the structurally unstable models for BRICS countries is consistent with the observations of 
Stock and Watson (2003), Rossi (2012) and Gabrielyan (2016) in the sense that structural 
instability does not necessarily imply poor forecasting performance, especially in out-of-
sample. Rossi (2012) documents that out-of-sample forecast comparisons are robust to model 
instabilities because their procedures can minimise the effect of structural breaks on the 
forecasting model.

Conclusions and summary

This research utilised explanatory variables commonly employed to model and forecast infla-
tion subject to data availability. The order of integration and seasonally adjusting the data 
were carried out to avoid issues involving seasonal unit roots. The motivation for considering 
a range of VAR-based dynamic models is as follows: models involving non-stationary series 
may lead to problems of spurious regression that can adversely affect forecasting accuracy. 
Therefore, this study conducted differencing and cointegration restrictions to transform non-
stationary series into stationary variables. VARs estimated with cointegrated data will be mis-
specified if all of the data were found to be different because the long-run information will 
be omitted and will have omitted stationarity inducing constraints if all of the data are used 
in levels. Therefore, the order of integration of all the considered variables were tested for 
cointegration. Based upon this analysis, the forecasting performance of the following three 

3  For example, Brazil launched a growth acceleration program in 2007 to provide tax incentive and reduce energy 
costs, strengthen its investment through foreign participation and restructure its oil royalty payment to increase 
revenue and provide more capital to the private sector. Similarly, Algeria government has recently imposed a 
policy that reduces licensing of importation of luxury furniture’s. Also, Government has approved the quantita-
tive easing of printing almost 570 billion dinars (about 5 billion dollars) to help the Central Bank lend money to 
Public Treasury. In addition, government has also approved the plan to diversify its economy by boosting domestic 
engineering, petrochemical and pharmaceutical and food industries to make them more globally competitive (The 
reuter, 2016).



Business, Management and Education, 2019, 17(2): 152–172 169

multivariate specifications with the benchmark model (Naive Model) was compared ‒ first, 
the VAR model with only (difference) stationary variables; second, VECM without imposing 
cointegrating restrictions; and third, the VEC that imposes a single cointegrating equation 
on the VECM.

The main results in this paper confirm no single model can dominate across all the 
countries. The forecast performance of inflation depends on the nature of the economy and 
whether the country experiencing higher inflation or low inflation. For instance, the model 
that includes long-run information in the form of a specified cointegrated equation gen-
erally improves the inflation forecasting performance for BRICS countries and one OPEC 
country (Saudi Arabia) that has a history of low inflation. An explanation for this result is 
that country with moderate inflation tend to have low instability and may not require fur-
ther differencing of macroeconomic variables. This is consistent with previous findings that 
stated that forecasts are most likely to be improved by applying error-correction techniques 
if the data strongly supports the cointegration hypothesis (see, Timothy & Thomas, 1998; 
Christoffersen & Diebold, 1998).

This study also showed that the unrestricted VAR model has a superior inflation forecast 
than cointegrating models and naïve model for OPEC countries that have a history of higher 
inflation. As noted earlier, that first differencing (stationary data) can capture different char-
acteristics of instability in high inflation economy such as OPEC countries.

Further, areas where both unemployment and the output gap are available as indicators of 
the Phillips curve, models including unemployment outperform those that use the output gap 
because unemployment indicator contains the most valuable information in inflation fore-
casting rather than models based on alternative indicators (output) for the selected countries.

The evidence also revealed that the model that considers oil price endogenous appears 
to secure better forecasting performance than the model that considers the oil price as ex-
ogenous for both BRICS and OPEC countries. This is not surprising because OPEC coun-
tries export oil while the BRICS countries (except Russia) import oil. Therefore, increases or 
decreases in the global oil price will directly affect government revenue and expenditure in 
many of these countries. Lastly, the application of structural stability tests provides evidence 
that using stable models enhances inflation forecasting performance for some OPEC coun-
tries. In contrast, all the favoured forecasting models for BRICS countries are structurally 
unstable. The performance of the favoured unstable forecasting models is consistent with the 
study of (Stock & Watson, 2003; Rossi, 2012) who argued that an unstable theoretical model 
could mislead the favoured out-of-sample forecasting.

Finally, some limitations of this study are worth mentioning. First, the proposed multi-
variate models focused on differencing and cointegrating restrictions to ensure the stationar-
ity of the data, where available variables were combined and specified based on their level of 
integration to forecast inflation. For instance, a VAR model is estimated based on differenced 
variables I(0); the same holds true for VECM and VEC models, where differenced variables 
and linear combinations of I(I) covariates are stationary. In future, multivariate models guid-
ed by economic theory rather than the order of integration of variables are suggested. Also, 
this study only compares the forecasting performance of different multivariate models (VAR, 
VECM and VEC) with a naive model. Therefore, more non-linear models and dynamic 



170 O. V. Ajayi. Comparing multivariate models’ forecasts of inflation for BRICS and OPEC countries

models (such as switching Markov, Dynamic stochastic general equilibrium modelling and 
neural network) need to be considered for forecasting in both OPEC and BRICS countries 
in the future to develop the work further.

Acknowledgements

I am grateful to the comments of two anonymous referees and my PhD supervisor (Dr Chris 
Stewart)

References

Agtmael, A. (2012). Think again: the BRICS. Retrieved from http://www.foreignpolicy.com/arti-
cles/2012/10/08/think_again_the_brics

Alles, L., & Horton, D. (2002). An evaluation of alternative methods of forecasting Australian inflation. 
The Australian Economic Review, 32(3), 237-248. https://doi.org/10.1111/1467-8462.00111

Atkeson, A., & Ohanian, L. (2001). Are Phillips curves useful for forecasting inflation? Federal Reserve 
Bank of Minneapolis Quarterly Review, 25(2001), 2-11.

Bjornland, H., Jore, A., Smith, C., & Thorsrud, L. (2008). Improving and evaluating short term forecasts 
at the Norges Bank. Norges Bank Staff Memo, No 4.

Buelens, C. (2012). Inflation forecasting and the crisis: assessing the impact on the performance of 
different forecasting models and methods. Economic papers 451/March2012.

Canova, F. (2007). G-7 inflation forecast: random walk, Phillips curve or what else? Macroeconomic 
Dynamic, 11, 1-30. https://doi.org/10.1017/S136510050705033X

Chen, S. (2009). Oil price pass-through into inflation. Energy Economics, 31(1), 126-133. 
https://doi.org/10.1016/j.eneco.2008.08.006

Christoffersen, P., & Diebold, F. (1998). Cointegration and long- horizon forecasting. Journal of Business 
and Economics Statistics, 16(4), 450-458. https://doi.org/10.2307/1392613

Clark, T., & McCracken, M. (2006). The predictive content of the output gap for inflation: resolving 
in sample and out of sample evidence. Journal of Money, Credit and Banking, 38(5), 1127-1148. 
https://doi.org/10.1353/mcb.2006.0068

Cologni, A., & Manera, M. (2008). Oil price inflation and interest rates in a structural cointegrated VAR 
model for G-7 countries. Energy Economics, 30, 856-888. https://doi.org/10.1016/j.eneco.2006.11.001

Dedeoglu, D., & Kaya, H. (2014). Pass- through of oil price to domestic prices: Evidence from an oil- 
hungry but oil-poor emerging market. Economic Modelling, 43(2014), 67-74. 
https://doi.org/10.1016/j.econmod.2014.07.038

Dotsey, M., Fujita, S., & Stark, T. (2011). Do Phillip curve conditionally help to forecast inflation. Work-
ing Paper Research Department, Federal Reserve Bank of Philadelphia.

Energy Information Administration. (2013). What drives crude oil prices? Independent Statistic Analy-
sis. Retrieved from http://www.eia.gov/finance/markets/supply-opec.cfm

Engle, F., & Yoo, B. (1987). Forecasting and testing in co-integrated systems. Journal of Econometrics, 
35(1987), 143-159. https://doi.org/10.1016/0304-4076(87)90085-6

Engle, R., & Granger, C. (1987). Co-integration and error correction: representation, estimation, and 
testing. Econometrica, 55(2), 251-276.

Fanchon, P., & Wendel, J. (1992). Estimating VAR models under non – stationarity and co-integration: 
Alternative approaches for forecast cattle price. Applied Economics Journal, 1992(24), 207-217. 
https://doi.org/10.1080/00036849200000119

http://www.foreignpolicy.com/articles/2012/10/08/think_again_the_brics
http://www.foreignpolicy.com/articles/2012/10/08/think_again_the_brics
https://doi.org/10.1111/1467-8462.00111
https://doi.org/10.1017/S136510050705033X
https://doi.org/10.1016/j.eneco.2008.08.006
https://doi.org/10.2307/1392613
https://doi.org/10.1353/mcb.2006.0068
https://doi.org/10.1016/j.eneco.2006.11.001
https://doi.org/10.1016/j.econmod.2014.07.038
http://www.eia.gov/finance/markets/supply-opec.cfm
https://doi.org/10.1016/0304-4076(87)90085-6
https://doi.org/10.1080/00036849200000119


Business, Management and Education, 2019, 17(2): 152–172 171

Fritzer, F., Moser, G., & Scharler, J. (2002). Forecasting Austrian HICP and its Component using VAR 
and ARIMA models. OeNB Working Paper 73, July 2002. Retrieved from https://ideas.repec.org/p/
onb/oenbwp/73.html

Gabrielyan, D. (2016). Forecasting inflation using the Phillips curve: evidence from Swedish data. The 
University of Tartu Feba, ISSN-L 1406- 5967. https://doi.org/10.2139/ssrn.2854067

Garcia, M., Medeiros, M., & Vasconcelos, G. (2017). Real-time inflation forecasting with high-dimen-
sional models: The case of Brazil. International Journal of Forecasting, 33(2017), 679-693. 
https://doi.org/10.1016/j.ijforecast.2017.02.002

Global Sherpa. (2014). Globalization, sustainable development and social impact in world rankings, coun-
tries and cities. Retrieved from http://www.globalsherpa.org/bric-countries-brics

Gupta, R., Eyden, R., & Waal, A. (2015). Do we need a global VAR model to forecast inflation and 
output in South Africa? Applied Economics, 47(25), 2649. 
https://doi.org/10.1080/00036846.2015.1008769

Hoffman, D., Anderson, R., & Rasche, R. (2002). A vector error-correction forecasting model of the US 
economy. Journal of Macroeconomic, 24, 560-598. https://doi.org/10.1016/S0164-0704(02)00067-8

Hooker, M. (2002). Are oil shocks inflationary? Asymmetric and nonlinear specification versus change 
in regime. Journal of Money, Credit, and Banking, 34(2), 540-561. 
https://doi.org/10.1353/mcb.2002.0041

Kelikume, I., & Salami, A. (2014). Time series modelling and forecasting inflation: evidence from Ni-
geria. The International Journal of Business and Finance Research, 8(2), 41-51. 
https://ssrn.com/abstract=2322918

Lack, C. (2006). Forecasting swiss inflation using VAR models. Swiss National Bank Economics Studies, 
No. 2. ISSN 1661-142X.

LeBlance, M., & Chinn, M. (2004). Do high oil prices presage inflation? The evidence from G-5 coun-
tries. UC Santa Cruz Economics Working Paper No. 561; SCCIE Working Paper No. 04-04. 
https://doi.org/10.2139/ssrn.509262

Lee, U. (2012). Forecasting inflation for targeting countries: A comparison of the predictive performance 
of alternative inflation forecast model. Journal of Business Economics Studies, 18(1), 75-95, 136.

Mandal, K., Bhattcharya, I., & Bhoi, B. (2012). Is the oil price pass- through in India any different? 
Journal of Policy Modelling, 34(2012), 832-848. https://doi.org/10.1016/j.jpolmod.2012.06.001

Mitra, D., & Rashid, M. (1996). Comparative accuracy of forecasts of inflation: A Canadian Study. Ap-
plied Economics, 28(12), 1633-1637(5). https://doi.org/10.1080/000368496327606

Nadal-De Simone, F. (2000) Forecasting inflation in Chile using state space and regime switching 
models. IMF Working Paper WP/00/162, Washington, DC. Retrieved from https://www.imf.org/
external/pubs/ft/wp/2000/wp00162.pdf

Organization of the Petroleum Exporting Countries. (2019). Member countries. Retrieved from https://
www.opec.org/opec_web/en/about_us/25.htm

Ogunc, F., Akdogan, K., Baser, S., Chadwick, M., Ertug, D., Hulagu, T., Kosem, S., Ozmen, M., & Tekali, 
N. (2013). Short-term inflation forecasting models for Turkey and a forecast combination analysis. 
Economic Modelling, 33(July 2013), 312-325. https://doi.org/10.1016/j.econmod.2013.04.001

Onder, O. (2004). Forecast inflation in emerging markets by using Philip curve and Alternative time 
Series model. Emerging Markets Finance and Trade, 40(2), 71-82. 
https://doi.org/10.1080/1540496X.2004.11052566

Ozkan, H., & Yazgan, M. (2015). Is forecasting inflation easier under inflation targeting? Empirical 
Economics, 48(2), 609. https://doi.org/10.1007/s00181-013-0793-3

Perron, P. (1989).The great crash, the oil price shock and the unit root hypothesis. Econometrica, 57, 
1361-1401. https://doi.org/10.2307/1913712

https://ideas.repec.org/p/onb/oenbwp/73.html
https://ideas.repec.org/p/onb/oenbwp/73.html
https://doi.org/10.2139/ssrn.2854067
https://doi.org/10.1016/j.ijforecast.2017.02.002
http://www.globalsherpa.org/bric-countries-brics
https://doi.org/10.1080/00036846.2015.1008769
https://doi.org/10.1016/S0164-0704(02)00067-8
https://doi.org/10.1353/mcb.2002.0041
https://ssrn.com/abstract=2322918
https://doi.org/10.2139/ssrn.509262
https://doi.org/10.1016/j.jpolmod.2012.06.001
https://doi.org/10.1080/000368496327606
https://www.imf.org/external/pubs/ft/wp/2000/wp00162.pdf
https://www.imf.org/external/pubs/ft/wp/2000/wp00162.pdf
https://www.opec.org/opec_web/en/about_us/25.htm
https://www.opec.org/opec_web/en/about_us/25.htm
https://doi.org/10.1016/j.econmod.2013.04.001
https://doi.org/10.1080/1540496X.2004.11052566
https://doi.org/10.1007/s00181-013-0793-3
https://doi.org/10.2307/1913712


172 O. V. Ajayi. Comparing multivariate models’ forecasts of inflation for BRICS and OPEC countries

Pretorious, C., & Rensburg, T. (1996). The forecast performance of alternative models of inflation. Oc-
casional Paper No. 10. Pretoria: South African Reserve Bank.

Rossi, B. (2012). Advances in forecasting under instability. Working paper 11-20. Duke University, 
Department of economics.

Sa-ngasoongsong, A., Bukkapatnam, S., Kim, J., Iyer, P., & Suresh, P. (2012). Multi-step sales forecast-
ing in automotive industry based on structural relationship identification. International Journal of 
Production Economics, 140(2012), 875-887. https://doi.org/10.1016/j.ijpe.2012.07.009

Sarantis, N., & Stewart C. (1995). Monetary and asset market models for sterling exchange rates: a 
cointegration approach. Journal of Economic Integration, 10(3), 335-371. 
https://doi.org/10.11130/jei.1995.10.3.335

Shan, C., & Ghonasgi, N. (2016). Determinants and forecast of price level in India: a VAR Framework. 
Journal of Quantitative Economics, 14, 57-86. https://doi.org/10.1007/s40953-015-0019-y

Shoesmith, L. (1992). Cointegration, error correction and improved regional VAR forecasting. Journal 
of Forecasting, 11, 91-109. https://doi.org/10.1002/for.3980110202

Shoesmith, L. (1995b). Multiple cointegrating vectors, error correction and forecasting with Litterman’s 
model. International Journal of Forecasting, 11, 557-567. 
https://doi.org/10.1016/0169-2070(95)00613-3

Shoesmith, L. (1995a). Long-term forecasting of non-cointegrated and cointegrated regional and national 
models. Journal of Regional Science, 35, 43-64. https://doi.org/10.1111/j.1467-9787.1995.tb01399.x

Stock, H., & Watson, M. (1999). Forecasting Inflation. Journal of Monetary Economics, 44(2), 293-335. 
https://doi.org/10.3386/w7023

Stock, H., & Watson, W. (2003). Forecasting output and inflation: the role of asset prices. Journal of 
Economic Literature, 4(3), 788-829. https://doi.org/10.1257/jel.41.3.788

Stock, H., & Watson, M. (2008). Philip curve inflation forecasts. Working Paper 14322. NBER. 
https://doi.org/10.3386/w14322

Taylor, B. (2000). Low inflation, pass-through, and the pricing power of firms. European Economic 
Review, 44(7), 1389-1408. https://doi.org/10.1016/S0014-2921(00)00037-4

The Goldman Saches Group. (2007). BRICS and beyond. Retrieved from http://www.goldmansachs.
com/our-thinking/archive/archive-pdfs/brics-book/brics-full-book.pdf

The Reuter. (2016). Algeria’s economic policy may accelerate inflation  – IMF On line. Retrieved from 
https://af.reuters.com/article/algeriaNews/idAFL5N1UJ512

Timothy, D., & Thoma, A. (1998). Modelling and forecasting cointegrated variables: some practical 
experience. Journal of Economics and Business, 50, 291-307. 
https://doi.org/10.1016/S0148-6195(98)00005-8

Vogelsang, T., & Perron, P. (1998). Additional tests for a unit root allowing for a break in the trend 
function at an unknown time. International Economic Review, 39(4), 1073-1100. 
https://doi.org/10.2307/2527353

World Economic Outlook. (2019). Real GDP growth annual percentage change. International Mon-
etary Fund. Retrieved from https://www.imf.org/external/datamapper/NGDPD@WEO/OEMDC/
ADVEC/WEOWORLD

https://doi.org/10.1016/j.ijpe.2012.07.009
https://doi.org/10.11130/jei.1995.10.3.335
https://doi.org/10.1007/s40953-015-0019-y
https://doi.org/10.1002/for.3980110202
https://doi.org/10.1016/0169-2070(95)00613-3
https://doi.org/10.1111/j.1467-9787.1995.tb01399.x
https://doi.org/10.3386/w7023
https://doi.org/10.1257/jel.41.3.788
https://doi.org/10.3386/w14322
https://doi.org/10.1016/S0014-2921(00)00037-4
http://www.goldmansachs.com/our-thinking/archive/archive-pdfs/brics-book/brics-full-book.pdf
http://www.goldmansachs.com/our-thinking/archive/archive-pdfs/brics-book/brics-full-book.pdf
https://af.reuters.com/article/algeriaNews/idAFL5N1UJ512
https://doi.org/10.1016/S0148-6195(98)00005-8
https://doi.org/10.2307/2527353
https://www.imf.org/external/datamapper/NGDPD@WEO/OEMDC/ADVEC/WEOWORLD
https://www.imf.org/external/datamapper/NGDPD@WEO/OEMDC/ADVEC/WEOWORLD