2.1 Related Work

Understanding consumer behavior has been a topic of interest since the beginning of consumer psychology in the early twentieth century. The discipline of neuromarketing, which links psychology, marketing, and neuroscience, was consolidated in 2002 when Ale Smidts coined its name.

Bibliometrics show that researchers have paid increasing attention to this discipline in recent years [⁴¹]. Although little is still known about the origin of consumer preferences and how they relate to attention and memory processes in purchase decision making, the use of neuroscientific data can minimize existing market research techniques [²⁸].

Several studies have been conducted to analyze consumer preferences in relation to taste, but three works have been of particular relevance to the development of this research. In 2004, in [¹⁷] a study was conducted using functional magnetic resonance imaging (fMRI) to detect that purchase decisions are made in the prefrontal cortex and also the perceived value of products lies in that area of the human brain.

In [⁹] it was determined that consumer neuroscience is an effective tool for evaluating emotional responses, providing information on food characteristics, and improving marketing strategies in food products, using techniques such as fMRI, electroencephalography, and measurement of skin conductance (SCM).

Finally, research conducted in [⁵] measured brain responses using fMRI while testing combinations of four basic tastes, concluding that the combination of sweet and salty is the one most associated with consumer emotion.

2.2 Neuromarketing: First Steps

It is currently a challenge for companies to emotionally understand the desires of consumers due to consumers being more informed about what they want to purchase. According to Agarwal et al. in [¹], neurological research argues that a product or service correlates with the consumer’s behavior when making a real purchase.

Analyzing brain activity can provide greater effectiveness in understanding consumer buying decisions. Furthermore, decision making is largely emotional and unconscious, accounting for 85-88% of the process [³⁴, ¹⁶, ¹⁹]. Advancements in neuroscience have supported the development of more accurate techniques and tools for studying the unconscious processes of an individual’s brain when making a purchasing decision.

Therefore, companies can acquire information directly from the consumer’s brain during their research, rather than relying on their responses, as it has been shown that consumers’ responses to market research may not necessarily reflect what they truly think or feel, leading to false purchases [³⁸].

These advancements have opened the door to neuromarketing, which is derived from consumer neuroscience.

The latter is considered the science that offers the most possibilities for recording brain activity by regions because it provides precise information for determining which neurons are activated by certain stimuli provided to different consumers.

Moreover, this interdisciplinary field detects that purchasing decisions can be influenced by subconscious processes in certain areas of the brain [²³]. When the beta brain waves observed in the frontal regions of awake individuals coincide with the gamma waves that detect the characteristics of an object, activity is associated with perception.

In addition, Roopun et al. in [³⁰] found that these waves interact through wave concatenation, able to merge, mentioning that this interaction is important for cognitive function and plays a role in human sensory perception and selective attention, supporting the purchase decision.

It was also found that low-frequency oscillations in the prefrontal cortex are related to decision-making as follows:

The purchasing decision is located in the cerebral cortex, where complex cognitive functions are performed such as thinking, perception, and judgment.

More specifically, in the subdivision of the cerebral neocortex responsible for decision-making, where the frontopolar 1 of the prefrontal cortex is located, located in the front of the brain, just behind the forehead. This is the main reason why EEG was considered the relevant tool for this study.

In addition to allowing real-time measurement of brain activity, EEG identifies emerging patterns and turns them into a tool to investigate how consumers process and evaluate marketing stimuli, as well as how they respond to them emotionally, in order to predict consumer preference [⁶].

2.3 Definition of Principal Component Analysis

Principal Component Analysis (PCA) is a fundamental statistical technique in multivariate data analysis. PCA aims to transform a set of p highly correlated variables into other new variables whose number is less than p and are not correlated with each other. The importance of PCA lies in its ability to reduce the complexity of the original data set, thereby facilitating its interpretation and further analysis.

In addition to reducing the dimensionality of the data, PCA is used to identify hidden patterns and structures in the original data. In this way, PCA can be used as an exploratory technique to identify important underlying variables and their relationship to the data set. By identifying these variables, a better understanding of the structure of the data and its relationship to the original variables can be obtained.

Although PCA generates new variables from the original variables, it is not guaranteed that all these new variables are significant in terms of their interpretation.

However, even when the new variables are not significant, their use remains valuable for tasks such as data collection and cluster verification. These tasks allow one to identify patterns in the data to be used for a wide range of applications.

Consider that each individual is described by k variables. Data from n subjects can be represented by the matrix n×k X. The data in the matrix make up a cloud of n points in a k-dimensional space. Equation 1 can also be interpreted as a population having a covariance matrix Σ or correlation for the variables involved k:

Let x1,…,xk be a basis of ℜk, let M1,M2,…Mn denote the k-dimensional cloud with n points, where x1,…,xk correspond to the point Mi in the (xi1,xi2,…,xik) basis. Each row of the matrix X, defined in Equation 1, corresponds to the components of a point in the cloud in the coordinate system induced by this basis.

In this way, considering a different basis, u1,…,uk is a basis of ℜk. In addition, take into account the coordinates (zi1,zi2,…,zik) of the point Mi on this new base, to build the matrix Z of order n×k, as follows:

To relate Z to X, we consider U as the step matrix from the base x1,…,xk to the new basis. The matrix U is a matrix k×k whose columns have the coordinates of the vectors u1,…,uk in the initial basis, which are linear combinations. In other words:

where u1,…,uk are unknown, x1,…,xk are vectors containing weights of linear combinations. We need the first principal component u1 to explain the maximum possible variance, resulting from the linear combinations of the initial variables in x¯.

Now, a restriction needs to be imposed on the magnitude of the elements of u1¯, because if not done, var(u1) will increase excessively, making it difficult to find a vector u1¯. It is generally assumed that the length of u1¯ is 1, that is, ‖u1‖=1 once the solution and the optimal weight vector u1¯ are found. The linear combination u1¯′x¯ is called the first principal component.

The next step is to find a second vector u2¯ such that the second component u2=u2¯′x¯ has the following properties:

This procedure seeks to ensure no correlation to achieve the aim of ending up with the smallest number of linear combinations, taking into account the largest possible portion of the variances of the initial variables.

Once this set of u2¯ values is found, the linear combinations u2¯′x¯ are called the second principal component. This process can be performed until we find k vectors u1¯,…,uk¯ appearing on the right side of Equation 3.

By construction, the successive principal components are uncorrelated, and formally there are as many principal components as the variables studied.

Furthermore, Equation 4 can define the step matrix U, as follows:

Therefore, the relationship between Z, X and U is depicted by Equation 5 as follows:

Since U is invertible, it can be deduced that:

If the vectors u1,…,uk form an orthonormal basis, the matrix U satisfies the relation UTU=I, and therefore (UT)−1=U In summary, Principal Component Analysis is a powerful and versatile statistical technique that has a wide range of applications in research and data analysis.

By allowing the reduction of data complexity and the identification of hidden patterns and structures, PCA is an essential tool in the exploration and analysis of large data sets.

2.4 Acquisition of EEG Signal

An EEG signal is the measurement of electricity flowing during synaptic excitation of dendrites in pyramidal neurons of the cerebral cortex. When neurons are activated, electricity is produced inside the dendrites, generating a magnetic and electric field that is measured with EEG systems.

The human head contains different layers (the brain, skull and scalp) to attenuate the signal and add external and internal noise, thus only a large group of active neurons can emit a potential that can be measured or recorded using surface electrodes [³¹].

The electrical activity of the brain can be captured on the scalp, at the base of the skull with the brain exposed, or in deep brain locations. The electrodes that acquire the signal can be superficial, basal, or surgical. For EEG, superficial electrodes are used [³²].

Generally, for the acquisition and recording of the brain’s electrical activity in BCI systems, surface electrodes are used on the scalp. There are several ways to accommodate them, called acquisition systems or simply arrays, e.g., Illionis, Montreal Aird, Lennox, etc., but the most used for research purposes, and certainly in this study, is the International 10-20 Positioning System [⁴].

The 10-20 International System is a standardized protocol based on longitudinal anatomical references of the inion and nasion and transverse earlobes, ensuring that electrodes are placed in the same areas, regardless of head size. Furthermore, this system is named after its use of 10% or 20% of the anatomically specified distances to place the electrodes as shown in Figure 1 from the Nasion to the Inion and from the earlobes [¹⁴], indicating that it is the center.

Fig. 1 International Electrode Positioning System 10-20. In this work the Fp1 electrode is used 

This work uses the ThinkGear TGAM1, an EEG device that collects neural signals and inputs them into the ThinkGear chip to process the signal into a sequence of usable data and filter any interference digitally. Raw brain signals are amplified and processed to provide concise contributions to the device.

The device considered as the interface between the brain and the computer is the NeuroSky ThinkGear module, Figure 2, since it meets the requirement of being a noninvasive method while also having a reliability rate of 98%. The electrode is placed in position Fp1 [²², ³⁵].

Fig. 2 Sensor ThinkGear ASIC Module v1.0 (TGAM1) 

2.5 Experimental Methodology

In this section we describe the methodology used to measure the brain response of the panelists while tasting eight samples of functional products containing the four-basic taste sensations: sour, bitter, salty, and sweet.

A laptop model Machenike T58 and the COLAB platform with Phyton code were used to record the data.

We applied EEG as a neuroscientific technique in Phase 1 of an ongoing study on the use of neuromarketing to understand consumer behavior.

This phase started with the preparation of the panelists to acquire the first data, pointing out the preference of the consumer for functional products. This article focuses on the results obtained in Phase 1, and the viability of continuing the research will be considered.

Phase 1 was divided into four subphases related to the sense of taste: i) the collection of the panelists’ preference beliefs, ii) brain measurement through EEG, iii) verification of information, and iv) determination of the waves having a connection. These data will allow the process to be replicated on a larger scale in the research. Once Phase 1 is completed, the next Phase 2 related to the combination of the basic taste senses will proceed.

Sixteen people were recruited into a panel service, where they expressed their taste preferences and dislikes on a response application when tasting a functional food for the first time. For each panelist, two samples of each basic taste sensation were provided and they were asked to indicate whether they liked or disliked each sample. The responses of the panelists were compared with the EEG data, leaving a gap between each sample to taste an unsalted cookie and a water sip to remove any taste detected by the panelist before, Figure 3.

Fig. 3 Facial expressions indicating whether they like or dislike a functional product sample 

The panelists aged 20 to 29 years (median = 25). Prior consent was obtained from all panelists. 43. 7% of the 16 panelists were women and 56.3% men. Brain activity was measured using an EEG and the facial expressions of the panelists were recorded while tasting the samples as a test for the next phase.

Our outcomes were studied to assess the relationship between the panelists’ responses and the measurements of brain activity. These results can provide valuable information to the food industry to create products that meet consumer preferences.

3.1 EEG Data Base

The electroencephalographic sample database consists of 124 samples that vary in time but contain between nine thousand and fifteen thousand samples, equivalent to 18-30 seconds.

Table 1 shows a sample of 10 values of brain activity, from raw signals and preprocessed signals such as Delta, Theta, Low Alpha, High Alpha, Low Beta, High Beta, Low Gamma, and High Gamma frequency-bands (Figure 4), along with the subject’s percentage of Attention (Atte) and Meditation (Med) during the test (Figure 5). The TGAM1 EEG sensor sampling rate is 512 samples per second only for the RAW time series, while the rest of the time series is one sample per second.

Fig. 4 Example of brain activity when a panelist eats a functional product 

Fig. 5 Example of a panelist’s attention when eating a functional product 

3.2 Analysis of Principal Components

To be successful in Principal Component Analysis, we separate the samples. All separated samples are divided according to brain activity when the functional product was liked or disliked.

The divided samples are compressed into a file called flavour.zip and uploaded to a Google Drive folder, Figure 6. For this example, we use the EEG DCNN folder, and the following instructions are used for decompression inside the site:

import zipfile

import os

path = ’/content/drive/MyDrive/EEG_DCNN/flavor.zip’

with zipfile.ZipFile(path, ’r’) as zip_ref:

     zip_ref.extractall()

Fig. 6 QR code on Google Drive where the EEG Database can be downloaded 

To store all samples, it is necessary to read and store them in a list, highlighting the inclusion of RAW data as follows:

def ReadExcelEEG(emotion):

all_data = pd.DataFrame()

For j in FilesEmotions:

     path=os.path.join(’/content/flavor’,j,emotion,’eeg’)

     print(path)

     for file in os.listdir(path):

          ts_path=os.path.join(path,file)

          TimeSeriesData = pd.read_excel(ts_path)

          all_data = pd.concat([all_data, TimeSeriesData], ignore_index=True)

return all_data

Then, a function is generated to find the loadings from one to eleven dimensions, i.e., Delta, Theta, Low Alpha, High Alpha, Low Beta, High Beta, Low Gamma, and High Gamma frequency-bands, along with the subject’s percentage of Attention (Atte) and Meditation (Med).

To do this, the data is first standardized and the principal components of n dimensional, and their respective loadings are calculated using these data as follows:

def PcaEeg (all_data,NoComponents):

     signals = [’RAW’, "Delta", "Theta", "LowAlpha", "HighAlpha", "LowBeta", "HighBeta", "LowGamma", "HighGamma", ’Atte’,’Med’]

     cols=signals[0:NoComponents]

     data = all_data.loc[:, cols].values

     data_standardized = (data - data.mean()) / data.std()

     pca = PCA(n_components=NoComponents)

     principalComponents = pca.fit_transform(data_standardized)

     principalDf = pd.DataFrame(data = principalComponents, columns = cols)

     loadings = pd.DataFrame(pca.components_.T, index=cols, columns = cols)

     display(loadings)

     fig, ax = plt.subplots(figsize=(12, 10))

     sns.heatmap(loadings, annot=True, cmap=’coolwarm’, ax=ax)

     plt.show()

     return loadings

To compare two components, the following function is performed, generating a scatter plot to compare the loadings of the electroencephalographic signals. The function is performed as follows:

def PlotPCA2D (loadings,ComponentA,ComponentB):

     signals = [’RAW’,"Delta", "Theta", "LowAlpha", "HighAlpha", "LowBeta", "HighBeta", "LowGamma", "HighGamma",’Atte’,’Med’]

     fig, ax = plt.subplots()

     display(pd.to_numeric(loadings.iloc[:, ComponentA], errors=’coerce’))

     ax.scatter(pd.to_numeric(loadings.iloc[:, ComponentA], errors=’coerce’), pd.to_numeric(loadings.iloc[:, ComponentB], errors=’coerce’))

     plt.xlabel(’Principal Component ’+ str(ComponentA+1))

     plt.ylabel(’Principal Component ’+ str(ComponentB+1))

     for i, name in enumerate(signals):

          ax.annotate(name, (pd.to_numeric(loadings.iloc[i,ComponentA],errors=’coerce’),pd.to_numeric(loadings.iloc[i, ComponentB]errors=’coerce’)))

     plt.show()

     return

4.1 Digital Signal Processing

The Digital Signal Processing involves the use of two tools in the literature, namely Power Spectral Density [⁴⁰, ³⁶, ²⁹] and Self-Affine Analysis [²⁴, ³⁷, ³, ³³].

In this subsection, we aim to understand the nature of EEG time series so that they are analyzed in both frequency and time domains from panelists’ brain activity in order to estimate the sample variability over time.

Due to the large number of samples and panelists, we conducted two experiments:

Fig. 7 Digital processing of the EEG signal of Panelist 1 when tasting the salty flavor of a functional product they like (in green) and dislike (in red) 

Fig. 8 Digital processing of the EEG signal of Panelist 11 when tasting the salty flavor of a functional product they like (in green) and dislike (in red) 

Fig. 9 Digital processing of EEG signal from Panelist 2 when tasting the bitter taste of a functional product they like (in green) and dislike (in red) 

Fig. 10 Digital processing of EEG signal from Panelist 7 when tasting the bitter taste of a functional product they like (in green) and dislike (in red) 

It is worth to note that in all cases the subscripts in Figures 7, 8, 9, and 10 denote the following:

All these four experiments show some common elements, for example:

Due to our findings proving the existence of a difference in the panelists’ brain activity when they eat a functional food that they like and dislike, we can now establish what are the main frequency bands (δ, θ, α, β or γ;) influencing a panelist’s decision-making.

4.2 Principal Component Analysis

The present study was conducted for assessing the brain activity of 16 individuals via EEG tests. A total of 124 EEG tests were collected, recorded and analyzed to identify possible patterns of brain activity associated with certain stimuli.

Furthermore, the acceptance of 8 different samples of functional products was evaluated by a group of the 16 panelists. In this regard, a total of 1 291 photographs of the tasted samples were analyzed, which were liked or disliked by the subjects or panelists surveyed.

In addition, 1 330 facial expressions were evaluated to demonstrate whether the taste sample was liked or disliked. Our results suggest a relationship between brain activity and the perception of the evaluated functional products.

The first step is to read all the brain activity samples from the panelist and place them in a list in Python. On the one hand, Principal Component Analysis is performed on only the samples that were liked by the panelists. Table 2 and Figure 11 show the results of the eleven dimensions or components in this work.

Fig. 11 Analysis of Principal Components 6 and 8 when the panelists like the functional product 

On the other hand, the same analysis was performed on samples that were not liked by the panelists, and the results of this are found in Table 3 and Figure 12.

Fig. 12 Analysis of Principal Components 6 and 8 when the panelists don’t like the functional product 

When comparing images in Figures 11 and 12, supported by Tables 2 and 3, certain signals in specific Principal Components can be observed to clearly behave positively when the panelist likes a functional product and negatively when they do not. Based on this, the following four Principal Components can be highlighted:

When contrasting the value of the loadings, we can observe that few of them have a value greater than one, and that these outcomes are consistent with the low beta and low gamma frequency bands and with the Attention and Meditation percentages of the panelists. Therefore, in this contrast we subtract the loadings obtained when panelists like and dislike the product. These observations can be seen in Table 4 and Figure 13.

Fig. 13 Overall Analysis of Principal Components 6 and 8 when the panelists test functional products 

Now, when we isolate the principal components 6 and 8 for analysis of the interaction with other frequency bands, we can observe in Figures 14, 15 and 16 that the only relevant bands are Low Beta and Low Gamma. Similarly, in Components 10 and 11, Figures 17, 18 and 19, the Attention and Meditation percentages of the participants are the only relevant factors, while all frequency bands are close to zero.

Fig. 14 Analysis of Principal Components 6 and 8 when the panelists like the functional product 

Fig. 15 Analysis of Principal Components 6 and 8 when the panelists don’t like the functional product 

Fig. 16 Overall Analysis of Principal Components 6 and 8 when the panelists test functional products 

Fig. 17 Analysis of Principal Components 10 and 11 when the panelists like the functional product 

Fig. 18 Analysis of Principal Components 10 and 11 when the panelists don’t like the functional product 

Fig. 19 Overall Analysis of Principal Components 10 and 11 when the panelists test functional products 

Based on the above outcomes, we suggest a clear relationship between brain activity and the perception of the evaluated functional products.