Bitcoin and stock markets: a revisit of relationship

3.1 Data collection

We use daily series data from 20 July 2010 until 26 April 2019, the series are collected in USD. Considering the fact this study investigates multi countries, converting the local currencies for BTC makes it difficult; therefore, this study obtains series according to USD from the following sources. The data on BTC and Asian stock indexes was collected from (www.investing.com/) and (www.wsj.com/market-data/quotes/index). We furnish the information regarding the data based on country basis as well as BTC and market index. We further convert the index values using the formula of R=ln[VitVit−1] where R represents return for BTC index and equity indexes, Vi is current index value, Vi_t-1 is the previous value, and ln represents natural log. In the calculation of index return, we followed Shuyue Yi et. al (2018) and choose the ending date of the sample because the market capitalization rank of cryptocurrencies is updated on a week-by-week basis. Furthermore, owing to availability of data for multiple countries, this study only investigates the weekday’s data for the period of study. Our data is rich in terms of its total number of observations and captures divergence in volatilities and correlation of BTC and Asian markets because of 2013’s April meltdown, the Fammed 2013 Bubble, the bankruptcy of Mt. Gox BTC Exchange, the summer sale of 2017, and China’s Stern intervention. We excluded days for weekend given the fact of missing data in stock indexes during the analysis period. We opted five Asian emerging economies as these countries show tremendous growth in different types of cryptocurrencies and recorded good momentum in BTC and other assets. The details of indexes used are shown in the table below Table 1:

This paper adopts multiple techniques to investigate the relationship between BTC and equity market returns in selected developed and developing countries. The approached methodology follows the traditional econometric method of VECM in combination with the time-frequency domain analysis via Wavelet techniques. VECM restricts the long run behavior of the endogenous variable to cointegrate while allowing short run adjustment. The cointegrating term is known as an error correction term, as the deviation from long-run equilibrium is corrected gradually through a series of partial short-run adjustments. In this research, VECM approach examines the equilibrium between the price of BTC index and equity market indices for five selected countries. We also use the M-GARCH to identify the changes in correlation and volatilities of BTC and Asian stock markets indices over time together with its directions (positive or negative) and magnitude (stronger or weaker). Following that, we also analyze the time frequency domain using Wavelet investigation and balance its findings through cross-correlation and cross-coherence analysis. Initially, it expresses how the cross-correlation between the two series varies across multiple scales, followed by the time-based evolution of the co-movement between the series along with directional leadership. Thus, the cross-coherence analysis helps us unravel new evidence on whether the higher price of BTC is influencing the prices of selected equity markets or the opposite, for instance, higher equity market prices are happening as a result of increased BTC price. Moreover, as wavelet analysis operates in a time-frequency domain (i.e. time horizon), the significance of the hypothesized interactions and the magnitudes of interactions are also discoverable. In the following sections, we explain in detail the estimations of the three tools.

3.2 Long-run and short-run associations using time series analysis (VECM and Granger causality)

Vector error correction model (VECM) also called restricted VAR, is designed to use non-stationary variables that are known to be cointegrated. VECM restricts the long run behavior of the endogenous variables to converge to their cointegrating relationship while permitting for short-run dynamic adjustment. VECM distinguishes short- and long-term associations in a model. In this content, the lagged structure of error term refers to short term deviation from long term equilibrium. The VECM also enables for Granger causality relations and Error Correction Term. The Granger causality test is also implemented in this research to understand the relationship of the dependent variables and explanatory variable. The general equation for VECM is presented as follows:

where X_t is used to denote the chosen endogenous variables for each model and ε_t is disturbance error term. From equation (1), the VECM model for this study can be illustrated as the equation below:

For market index (MI) for each country (i = Japan, Korea, Singapore, Philippines and Hong Kong):

where MI is market index and BTC refers to BTC price index (BTC) which is the ratio of price and standard deviation of BTC. Causality test is implemented to understand the direction of the relationship between variables. In regression modeling, the underlying theory will indicate the direction of causality between Y and X, which is in the context of single equation models, is generally from X to Y. Hence, to understand this relationship and its directions, this research applies the Granger causality test.

3.3 Multivariate generalized autoregressive conditional heteroscedasticity (M-GARCH)

Multivariate GARCH-DCC is the modified version of Bollerslev’s (1990) constant conditional correlation (CCC-GARCH) as introduced by Engle and Sheppard (2001) and Engle (2002). This research uses MGARCH-DCC to explore two important phenomena; first, to investigate the fluctuations in correlation and volatilities of BTC return and Asian stock market indices over time. Second, to determine the directions and magnitude of existing correlations. MGARCH-DCC eases the assumption of CCC-GARCH on the conditional correlations of series as persistent following the assumption of having positive amount for the time dependent conditional correlation matrix. This assumption is impractical in various empirical investigations. In the process of using MGARCH-DCC, two stages were observed; first, the estimation of standard deviation (SD) from univariate GARCH, and second, using SD to calculate the standardized residuals and correlation matrix. By referring to Engle (2002), the equation for multivariate conditional covariance matrix (H_t) for this research can be written as follows:

The log-likelihood of the above estimator can be written as follows:

The conditional variances for any individual asset can be obtained from the univariate GARCH model as follows:

Having obtained the conditional variances for any individual asset, the dynamic correlation structure can thus be written as follows:

The component of R_t will be Pijt=qijtqiiqjj and the matrix R_t will be positive definite/constant. The K is covariance H_t is positive definite/constant and can be written as H_t = D_t R_t D_t. The breakdown of H_t allows separate specification of the conditional volatilities and conditional correlations. For instance, one can use the GARCH (1, 1) model for the variance σi,t−12, namely:

3.4 Continuous wavelet transform

Researches in finance and economics are witnessing the growth on the usage of wavelet transformation analysis. There are some points on the aspects of wavelet methodology that suit the model of the current study. By implementing wavelet analysis, researchers are able to fetch high quality information confined into a signal in various scales. Because the VECM analysis of this research uses the traditional econometric testing for short and long run relationship between BTC and equity market indices, wavelet testing is placed exclusively to not only perform the robustness check on VECM results, but to also explore new visions in the time-frequency domain by using cross-correlation and coherency analysis.

Using a wavelet transform requires a restricted waveform expressed as Ψ(t)W(t), called commonly a mother wavelet. While the mother wavelet integrates to zero, its harmonizing normalized counterpart ϕ integrates to 1 and is known as a father wavelet. The former is used for interrogating signals in greater details and is, therefore, more relevant for higher frequency testing. As such, we go on to build a wavelet function by forging a series of plans including mother and father wavelets. We achieve this by transformation and scaling Haar (Daughter) Wavelets, expressed mathematically as:

In the two equations above, s = 1,…, S, where S and k are scaling and translation parameters and j is dilation index respectively. Also, the wavelet transformation of a signal can be represented as:

At this stage, the cross-wavelet spectrum of BTC returns and equity market indices for individual equity market series are as follow;

Accordingly, the cross-wavelet spectrum’s cross-coherency is achieved by taking the absolute value of the squares of the smoothed spectrums, as follows:

Equation (14) is useful for capturing the degree to which two time-series co-moves across time and frequencies, an improvement over Fourier transforms which deal with frequencies alone. A CC(τ,s)2value ranges from 0 to 1, where 0 indicates no co-movement and 1 as perfect strong co-movement.

4.1 Descriptive statistics

Table 2 provides a description of the data used for analysis. The data is described based on mean, maximum, minimum and standard deviation. In terms of mean values, STI index recorded higher mean value followed by BTC, JPN, PHIL, HK and KOR. In terms of maximum values, BTC obtained higher value as compared to others. The same goes for minimum value as well in which BTC recorded minimum values. We can observe that large dispersion occurs at BTC market where the standard deviation is of 0.070157 followed by JPN, HK, PHIL, KOR and STI. The total number of observations are 1,909 because the data collected are in the daily basis mode.

4.2 Long- and short-run associations using time series analysis (VECM and Granger causality)

Several steps were performed, and they include the unit root test, optimal lag selections test as well as cointegration test. In this research, we use augmented Dickey–Fuller (ADF) and the Phillips-Perron (PP) for the test of unit root for BTC and five Asian emerging economies’ indices. Table 3 shows the analysis of unit root at level and first difference. The null hypotheses have a unit root which cannot be rejected by both ADF and PP tests. Apparently, after incorporating the first difference, both unit root tests rejected the null hypothesis, concluding that all variables are not stationary at the level basis but it stationary in first difference.

The identification of lag will be more difficult as lag variables incorporate exogenous variable in the system (Ender, 1995). Thus, for lag selection, we use the shortest lag based on Akaike Information Criteria (AIC). We conducted optimal lag selection for the indices of Asian emerging economies. Referring to Table 4, the Asian countries’ index lag chosen are: JPN (lag = 3), KOR (lag = 3), STI (lag = 3), PHIL (lag = 4) and HK (lag = 4).

Case in hold, we can observe that each of the series is stationary, and therefore, we can evaluate whether there is the presence of long-run equilibrium or vice versa for model test in this study. To assess the existence of long-run association, we refer to Johansen–Juselius cointegration tests based on trace and maximum eigenvalue analysis. Again, we analyze the cointegration test using the lag selected in Table 4. As per disclosed in the Table 5, the co-integration result shows that all the Asian emerging economies have co-integration at 1% significance level. The trace statistics and maximum eigenvalue postulate the existence of one co-integrating vector, thus confirming that there is a unique co-integrating vector controlling the long-run association between Asian market indices and BTC. These variables are knotted together in the long run, and their eccentricities from the long-run equilibrium path would be rectified. Furthermore, the existence of co-integration also reveals the non-causality among the variables.

Table 6 shows the long-run association of market indices with BTC. All market indices are statistically significant at 5% significance level. Looking at the market index, there seem to be a negative relationship between market indices and BTC for JPN, KOR, STI and HK. For example, in the context of JPN, the negative sign of BTC coefficient reveals that when BTC increases by 1%, it will trigger the decreasing number of JPN market index by 37.97% (to quantifying the long-run relationship between BC and the stock index, the error correction speed coefficient has been multiplied by the cointegrating coefficient). The similar discussion is also applied for other Asian countries which have negative association. A high decrease in market index occurs at KOR where a 1% increase in BTC causes a shrink in market index at 4.977%, followed by HK and STI markets. A possible reason to this (i.e. increase in BTC leads to decrease in market for Korea) is because of the strong information technology (IT) infrastructure within the country. Furthermore, the economic slowdown and increase in employment rate in Korea also cause Koreans to look for a better way to invest, especially digitally. On the other hand, we can notice a positive association between BTC and PHIL equity market in the long run. The Philippines is considered a good market for BTC given the fact that the country has an active BTC community and the country has a special economic zone in which foreign crypto exchanges are licensed for operation. Furthermore, the rise of fintech in Philippines also contributes to the rapid development of the BTC market in addition to the equity market. This will have a positive long-term economic impact toward Philippines’s financial landscape.

Table 7 discloses information on the ECT for the market indices of each Asian country. ECT basically looks at the speed of adjustment toward long-run equilibrium. All Asian equity markets obtained negative ECT. For simplicity, Japan is selected as sample for discussion. The ECT of Japan’s market Index with BTC is −0.006063 (the error correction speed coefficient has been multiplied by the cointegrating coefficient) = 37.97%, meaning that 37.97% of that disequilibrium dissipated before the next period and 62.03% remained. This value is significant at 10%. There may be other factors which this study did not consider augmenting or detract from the disequilibrium in the next period.

We further our investigation to see the dynamic interactions between these variables. In Table 8, we show the result of the pair wise Granger causality with a lag selected in Table 4 which is enough to whiten the noise process. From Table 7, some general findings can be concluded. Most of the equities index do not have any short-run association with the BTC market except for Korea where there is evidence of a short-run association between BTC and Korean index. This supports the idea that BTC investment is suitable for long-term investment instead of short-term. Lee et al.’s (2018) study confirms that BTC and other cryptocurrencies are better options for investment and diversification in the long-term as correlation between cryptocurrencies is lower as compared to other traditional assets.

4.3 Multivariate generalized autoregressive conditional heteroscedasticity (M-GARCH) – dynamic conditional correlation

First, we performed the MGARCH-DCC to analyze the association between BTC and selected Asian equity markets’ index. Basically, the MGARCH-DCC improves the volatility modeling by relaxing some of its assumptions, especially in terms of its means and variances of the factors. We show both Gaussian-DCC model and t-DCC model. In addition, there are the plotting of estimated conditional correlations and volatilities as well. The main purpose of showing both analyses is to determine model suitability and appropriation to measure the research objective. Table 9 postulates the value of maximum likelihood (ML) prediction of λ₁ and λ₂ (parameters of volatility) and δ₁ and δ₂ (mean reverting parameters) for each of the return sequences. All the estimated coefficients (λ₁ and λ₂) are less than 1, disclosing that DCCs are following the mean reverting process. This means that BTC and stock indexes do not follow I-GARCH and the estimates of λ_1i, I = 1, 2, 3, 4, 5, 6 are close to 1, implying a steady volatility decay. Furthermore, all volatility decay structures are at the significant level. We also present the analysis of t-DCC model to identify the model suitability (Table 10). The maximum likelihood (ML) of t-DCC postulates that all volatility forecasts are statistically significant, and the estimated values are also close to one. Like Gaussian-DCC model, these ML estimates for t-DCC also indicate gradual volatility decay. The ML value for t-DCC is 34,153.2, higher than 33,676.9 and the degree of freedom for t-DCC is 7.4280, less than 30. Given these facts and based on M-GARCH rules, t-DCC model is more suitable and fit for analysis with the series and fat tails. Thus, the discussion of analysis will be based on Table 9. The sum of estimated coefficients (λ₁ and λ₂) is less than 1 for most of the preferred parameters. For example, λ1_ JPN + λ2_ JPN (0.79256 + 0.0615 = 0.9714) basically signals that the volatility of JPN Index returns appears to deviate from the IGARCH approach. A similar outcome is also applied for indexes return and shocks to the volatilities for all indexes, which are not tenacious. The lambda totaling of BTC λ1_ BTC + λ2_ BTC (0.78431 + 0.17795 = 0.96226) still shows that the value is less than 1, meaning that the volatilities also do not follow IGARCH, thus any shocks to the volatilities are not insistent. Let us say the volatility of any asset is obstinate given the shock in the economy; retail and institutional investors could have a chance of losing all their investment money in the long run although they have made short run profit given the uncertainty level in the BTC market. The t-DCC result confirms that the volatilities of BTC and Asian stock indexes are not persistent and would significantly alarm investors on whether the investment is safe for them. This outcome is also consistent with a study done by Rahim and Masih (2016).

Table 11 displays the result of unconditional correlation and volatilities of BTC and Asian stock market indexes. The on-diagonal shows unconditional volatilities while off-diagonal indicates the unconditional correlation of each asset. When the unconditional volatility is closer to 0, the asset thus contains least volatility. However, if the unconditional volatility is close to 1, the asset encounters higher level of volatility, meaning higher risk. To make it clear, we sort the BTC and Asian stock indices from the highest to the lowest volatility (Table 12). Table 11 illustrates the orders of the unconditional volatilities of the five Asian stock indexes with BTC. Interestingly, all the indexes recorded low unconditional volatilities ranging from 0.008534 to 0.014019. The five stock markets are less volatile whenever there is uncertainty in BTC. The BTC logged unconditional volatility of 0.070765 which can be considered as a relatively moderate volatile. STI-Singapore index recorded the lowest volatility is. In the news highlighted by DBS Singapore (2018), Singapore investment encounters less volatility as it offers plenty of diversification opportunities to investors.

Looking at the off-diagonal components in Table 11, we notice that three stock market indexes have negative correlations, namely, KOR, STI and HK. On the other hand, the other two markets (i.e. JPN and PHIL) have a positive correlation. Results of the unconditional correlation in Table are like Table 5 of the long run relationship between BTC and Asian stock indexes. This shows the consistency in our results as predicted by the VECM and t-DCC model. This is except for one Asian country, where we find a positive correlation (BTC and JPN stock index). The Japanese government has legalized (for medium of exchange and investment purposes) the BTC currency and the spillover effect has caused the share price to increase. To illustrate, for small exchange listed firms incorporating BTC as part of their business transaction, the share price tends to increase as BTC prices increase, which coincides with BTC’s rally (bitcoin.com, 2017).

Details of the time framework proportion are given in the footnote [1]. As we observe in Figure 1, the co-movements of BTC with Asian stock indexes are unpredictable. However, one thing is very clear, and that is BTC return is more volatile than stock indexes. During the period of 2010 to 2015, we can see that the volatility was not so explosive, but after 2015, the returns of BTC are tremendously volatile. Forbes (2019) reported that bitcoin is still a very speculative asset and most of the time will follow the “Bart Simpson” pattern in which the price would increase, drop and increase again. The 2013’s April meltdown, Fammed 2013 Bubble, bankruptcy of Mt. Gox BTC Exchange, summer sale of 2017, and China’s Stern intervention contribute significantly toward these volatiles. A similar sentiment is shared by Cheung et al. (2013) and Corbet et al. (2018c). Comparatively, stock indexes are less volatile than BTC as revealed in Figure 1. The degree of volatilities for BTC is higher than the stock indexes during the analysis period in terms of the conditional correlation (Figure 2). Looking at the unconditional correlation, the degree of relationship can see from different time horizons. During 2010 and 2011, the correlation between BTC and HK stock index peaked quite significantly while KOR recorded lowest correlation with BTC recording negative value. Other stock indexes observe mixed movement with BTC. For example, from 2010 until 2015, there was inconsistent movement but with the same direction, meaning that the correlations co-move together. JPN recorded strong correlation with BTC, indicated by the blue color line during the analysis period, followed by PHIL. As these two countries actively promote digital currency and cryptocurrency, this could be the main reason contributing to this movement. KOR, STI and HK logged inconsistent movement with negative correlation during 2010 until 2019. From 2015 onwards, JPN and BTC correlation shows peak level of correlation. However, for STI, the correlation is most of time in the negative–positive, especially during 2012, 2013, 2014, 2016, 2017 and 2019. As mentioned earlier, STI market offers a quite diversified assets platform for investors which influences this movement. The results of Figure 2 and Table 10 (off-diagonal indicates unconditional correlation of each asset) postulate a similar outcome. Thus, given the correlation between stock indexes and BTC, we can now classify which markets can be considered a safe investment or safe heaven. Generally, in finance, investors tend to opt for the negative correlation as they can diversify investment risk (Jones, 2014). With this concept, the ones to offer a good investment opportunity (safe zone) in the case of heavy volatility in BTC would be STI, HK and KOR. JPN and PHIL may not be considered as a safe zone because of the strong interdependence which would be very risky for investors. However, this is subject to the investors’ attitude toward risk factors.

4.4 Time frequency domain using continuous wavelet transform

Before we further discuss the wavelet analysis, we first need to understand their classification prior to making any judgment. Basically, the horizontal line represents the number of years while the vertical line shows the frequency component (scale), with the shorter frequency range closest to the origin of the BTC return fluctuation. Red areas show higher coherency of BTC with stock indexes while blue areas indicate lower co-movement between BTC and stock indexes. Additionally, the black solid silhouettes correspond that the co-movement is statistically significant at 5% given a time and frequency. For example, as we look at the Wavelet Coherence for BTC and JPN, the blue color covers a large proportion of the cone. This means that the time domain co-movement is commonly weak. However, we may notice that the blue area dominates the low scale area (blue color is more prevalent in the higher level of axis y), meaning that the co-movement is more obvious in the long term than it is in the short term. Furthermore, as time progresses, the blue color is less dominant, showing an increase in the co-movement between BTC and JPN. The wavelet phase-difference specifies the dynamic relationship of return or price by looking at the lead-lag association between the paired sets (example: A and B). The arrows set out the lead-lag relationship between the series. If the phase arrow points to the right, this signals that the relationship follows a positive co-movement (in phase: A and B). If the arrow points to the left, the relationship is out of phase (negative co-movement: A and B). If the arrow points down, this implies the price or return of A leads to the price or return of B. If the arrow points up, then B leads A.

4.5 CWT for BTC with Japan, Korea, Singapore, Philippines and Hong Kong

As discussed earlier, the CWT reveals the dominance of blue which covers a large proportion of the cone, showing that the co-movement between BTC and JPN is relatively low. However, as time progresses, we can observe the increasing dominance of red, meaning that the co-movement is getting stronger (short term, medium and long term). These values are statistically significant at 5%. The outcome is quite pragmatic under the scale of 64 to 256. This result is also consistent with the finding revealed in the M-GARCH analysis of the unconditional correlation between BTC and JPN stock index which recorded positive correlation. The lead-lag relationship postulates a positive co-movement between BTC and JPN stock index where most of the arrows point to the right. In other words, the lead-lad relationship between BTC and JPN stock index is within the phase category. If the BTC goes up, then the stock index will also move up. This is consistent with the unconditional correlation shown by our M-GARCH analysis as well (Figure 3). The CWT for BTC and KOR indicates quite similar results with BTC and JPN but for this case, the blue color domain covers the entire cone with little red color areas. This highlights that the degree of co-movement is very low even though time progresses. The red color can be observed at the scale of 16 to 64 and 64 to 256 but at minimal level. On the other hand, few arrows are available and most of the arrows point up when looking at the lead-lag relationship, meaning that BTC does not lead the KOR stock but the KOR stock index leads the BTC. This happens in the medium and long periods. This finding is consistent with the M-GARCH unconditional correlation where the relationship is negative (Figure 4). The difference is mainly cause by different time horizons involved. As it is very difficult to see the relationship in the short-term. As time progresses medium term onwards, thus the co-movement will be strong and the phenomena can be notice in the long-term as well.

Like KOR, the outcome for STI is also more or less similar with blue covering most areas in the cone. Just a small proportion of red is available under the scale of 64 to 256. This again shows the degree of co-movement which is very low between BTC and STI. Again, the wavelet phase difference demonstrates limited arrows that point upward, meaning that the STI stock index leads the BTC (Figure 5). This can be evidenced at scales of 64 to 256 which occur at long term.

In terms of the degree of co-movement between BTC and PHIL for short and long scales, it is very clear that blue dominates over red. However, in the medium scale from 16 to 64, red colors some areas. Moreover, the lead-lag relationship shows the arrows pointing to the left. This is an out of phase relationship as the relationship shows a negative co-movement between BTC and PHIL during the medium term but not in the short and long periods. Finally, for BTC and HK, again blue is dominant, which shows that the co-movement between these two remains low. As time progresses, blue remains a dominant color in the cone. Just a small proportion of red color can be observed inside the cone, which only happens at short and medium scale. A limited number of arrows are available inside the cone which can predict the wavelet phase difference. The arrows are available only at the medium scale, such as 16 to 64. The outcome shows that in the short term, the arrow points to the right while in the long term, the arrow points to the left. Basically, there are in-and-out phases for the lead-lag relationship (Figure 6 and Figure 7).