KR102031958B1 - Prefrontal based cognitive brain-machine interfacing apparatus and method thereof - Google Patents

Abstract

A frontal lobe-based cognitive brain-mechanical interface device and method, the frontal lobe-based cognitive brain-mechanical interface device, EEG measuring instrument for measuring the EEG signal of the prefrontal lobe to be measured, a memory storing the cognitive brain-machine interface program and And a processor for executing a program stored in the memory. At this time, the processor recognizes the brain region corresponding to the EEG signal of the prefrontal lobe measured by the EEG measuring apparatus among the plurality of brain regions on the prefrontal lobe previously classified according to the execution of the cognitive brain-machine interface program, and the recognized brain region. Detects the degree of activity of each star, calculates causal linkages between two or more brain regions based on the degree of activity of each brain region, extracts the prefrontal activation pattern, and generates a plurality of prefrontal activation patterns for the measurement target in advance. A corresponding prefrontal activation pattern is input to the classifier to identify corresponding driving conditions among preset brain-machine interface driving conditions, and to generate and output a predetermined machine driving control signal based on the identified result.

Description

Prefrontal lobe-based cognitive brain-machine interface device and method {PREFRONTAL BASED COGNITIVE BRAIN-MACHINE INTERFACING APPARATUS AND METHOD THEREOF}

The present invention relates to a device and a method for processing a brain-machine interface (BMI), and more particularly to a cognitive brain-machine interface device and method using an EEG signal of the frontal lobe.

A study of brain-machine interface (BMI) or brain-computer interface (BCI) technology that controls a computer according to human intention by using EEG signals. Is actively underway. Among them, techniques for processing an interface between the brain and a machine (or computer) by analyzing parameters according to cognitive features of EEG signals have been developed.

In this regard, Republic of Korea Patent No. 10-1518575 (name of the invention: method for analyzing user intention for BCI), the EEG (electroencephalogram) in the pre-processing unit to obtain the user's EEG data measured from the device, the identification unit After converting the EEG data into a frequency signal, classify the frequency domain related to the motor sensation according to the band of the converted frequency signal, and analyze the features appearing according to the user's motion imagery in the EEG data of the frequency domain in the detector. The present invention discloses a method of detecting intention recognition of a user, and displaying a detection result of the intention on the display unit such that the user can confirm the intention. Specifically, the EEG data is an EEG signal measured by attaching 14 channels of electrodes having a sampling rate of 128 SPS (2048 Hz) to the user, and the electrode is an international standard law 10-20 (ten-twenty electrode system). Attached to the 14 areas of the scalp AF3, F7, F3, FC5, T7, P7, O1, O2, P8, T8, FC6, F4, F8, AF4 Disclosed is a method of analyzing whether a user intends to classify a mu rhythm (μ) region of an EEG using a digital notch filter (DNF).

As described above, the conventional BMI (or BCI) technology mostly uses EEG signals in the occipital or parietal lobe. However, the intention recognition method based on the EEG signal of the occipital lobe or parietal lobe is difficult to express various intentions of human, and thus there is a limit to the kind of BMI driving signals that can be used. That is, the intention recognition method using the brain wave signals of the occipital or parietal lobe cannot match the contents of the user's thoughts with the contents of the BMI driving.

Human high-level cognitive function is taking place in the frontal area of the brain (more specifically, the frontal area). Therefore, when the EEG signal of the corresponding brain region is used as the BMI (or BCI) signal, the high-level intention of the user can be recognized and distinguished, and thus a multi-class signal can be used as the BMI driving signal. Furthermore, the frontal lobe is an area responsible for human decision making, and if the contents of the user's thoughts are captured as the EEG signals of the frontal lobe, they can be matched with the contents of the BMI driving. Therefore, there is a need for a BMI technology capable of high-dimensional intention recognition based on the EEG signals of the frontal lobe.

On the other hand, EEG is an important biological signal showing the state of human brain activity, the EEG is faster or slower depending on the type of cognitive function being performed. However, if brain function is abnormal (eg patients with attention deficit disorder (ADD) or have low intelligence), brain waves are slower than normal. In addition, abnormal brain waves of various characteristics may appear depending on the disease. For example, epilepsy has a strong 3 Hz EEG, and autism, mental retardation, attention deficit and hyperactivity disorder (ADHD), attention deficit disorder (ADD) or dementia all become very strong in theta waves. In addition, depression causes the right brain to oscillate faster than the left brain.

Biofeedback technology is being developed as a technology that controls the abnormal brain rhythm to change to a normal rhythm. In particular, the biofeedback technology that controls the brain waves is called neurofeedback by combining neuro-prefixed neuro. There is a great need for a BMI (or BCI) technique that can be applied to such neurofeedback rehabilitation. Therefore, it is necessary to develop a BMI technology that can be applied to neurofeedback rehabilitation, in addition to the BMI technology capable of high-level intention recognition.

Republic of Korea Patent No. 10-1518575 (Name of the invention: method for analyzing user intention for BCI, 2015.03.16)

An embodiment of the present invention is to provide a frontal lobe-based cognitive brain-machine interface device and method for processing cognitive brain-machine interfacing using the brain wave signals of the frontal lobe.

In addition, an embodiment of the present invention is to provide a brain-mechanical interface device and method that can be applied to neurofeedback rehabilitation of the process of processing cognitive brain-machine interfacing using a frontal lobe EEG signal.

However, the technical problem to be achieved by the present embodiment is not limited to the technical problems as described above, and other technical problems may exist.

Prefrontal lobe-based cognitive brain-machine interface device according to an aspect of the present invention for achieving the above technical problem, EEG measuring unit for measuring the EEG signal of the prefrontal lobe to be measured; Memory in which a cognitive brain-machine interface program is stored; And a processor for executing a program stored in the memory, wherein the processor is configured to measure the frontal lobe of the prefrontal lobe measured by the EEG of a plurality of brain regions on the prefrontal lobe previously separated according to the execution of the cognitive brain-machine interface program. Recognize the brain region corresponding to the EEG signal, detect the activity level by the detected brain region, extract the prefrontal lobe pattern by calculating the causal connection between two or more brain regions based on the activity level by the brain region, Inputting the extracted prefrontal activation pattern into a classifier generated by machine learning a plurality of prefrontal activation patterns for the measurement target in advance to identify corresponding driving conditions among preset brain-machine interface driving conditions, and Generate a preset machine drive control signal based on the And power. In this case, the classifier is generated by machine learning a prefrontal activation pattern, each labeled for each of a plurality of intentions based on the EEG signals of the frontal lobe of the measurement target.

In addition, the prefrontal lobe-based cognitive brain-machine interface method according to another aspect of the present invention, receiving the EEG signal of the frontal lobe of the measurement target from the EEG; Recognizing a brain region corresponding to an EEG signal of the frontal lobe measured by the EEG from among a plurality of brain regions on a prefrontal lobe previously classified; Detecting the degree of activity of each recognized brain region and extracting a prefrontal lobe activation pattern by calculating causal connections between two or more brain regions based on the degree of activity of each brain region; Identifying a corresponding driving condition among predetermined brain-machine interface driving conditions by inputting the extracted prefrontal activation pattern to a classifier generated by pre-machine learning a plurality of prefrontal activation patterns for the measurement target; And generating and outputting a predetermined machine drive control signal based on the identified result. In this case, the classifier is generated by machine learning a prefrontal activation pattern that is labeled for each of a plurality of intentions based on the EEG signals of the frontal lobe of the measurement target.

According to any one of the above-described means for solving the problem of the present invention, by acquiring the driving signal of the brain-machine interfacing based on the brain wave signal of the frontal lobe, it is possible to recognize the high-dimensional intention of the user. Accordingly, various signals corresponding to the intention of the user can be distinguished.

In addition, according to any one of the problem solving means of the present invention, the brain wave signal corresponding to the case where the user directly imagines the intended can be extracted directly from the frontal lobe region can be used as a driving signal of brain-machine interfacing, the user's thinking You can match the contents of the BMI with the contents of the BMI drive.

In addition, according to any one of the problem solving means of the present invention, the results of the prefrontal lobe-based brain-machine interfacing to the user in real time by repeatedly or continuously a process of directly associating the user's intention to achieve any purpose By doing so, it can be used for enhancing the function of the frontal lobe and rehabilitation utilizing neurofeedback.

In addition, according to any one of the problem solving means of the present invention, by using a signal in the frontal lobe region where the disturbance factors of the EEG signal measurement by the hair is relatively small, the acquisition efficiency and accuracy of the EEG signal is increased and the non-invasive BMI method It can contribute to the progressive performance improvement of the system and can be applied to the invasive BMI.

In addition, according to any one of the problem solving means of the present invention, by performing the EEG measurement position confirmation through the 3D scanner, by minimizing the error for each anatomical origin position to be detected the frontal lobe signal that can be generated by repeated measurements, The reliability and accuracy of the extraction and classification of attributes of EEG signals can be improved.

In addition, according to any one of the problem solving means of the present invention, the signal processing stage for performing the EEG signal control and EEG can be implemented integrally, the brain-machine interface device by performing a wireless communication with the external device, portable It can be used as an EEG based BMI device.

1 is a block diagram of a prefrontal lobe-based cognitive brain-machine interface device according to an embodiment of the present invention.
2 is an exemplary view for explaining the overall concept of prefrontal lobe-based cognitive brain-machine interfacing according to an embodiment of the present invention.
3 is an exemplary diagram for explaining the difference between the conventional method of the prefrontal lobe-based cognitive brain-machine interfacing method according to an embodiment of the present invention.
4 is an exemplary diagram for explaining a prefrontal lobe-based cognitive brain-machine interfacing process according to an embodiment of the present invention.
5 is an exemplary diagram of a Broadman region for explaining a brain region for acquiring an EEG signal according to an embodiment of the present invention.
6 is a block diagram illustrating an electrode attachment position checking function of the prefrontal lobe-based cognitive brain-machine interface device according to an embodiment of the present invention.
7 is a flowchart illustrating a prefrontal lobe based cognitive brain-machine interface method according to an embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is "connected" to another part, this includes not only "directly connected" but also "electrically connected" with another element in between. . In addition, when a part is said to "include" a certain component, which means that it may further include other components, except to exclude other components unless otherwise stated.

In the present specification, the term 'part' or 'module' includes a unit realized by hardware or software, and a unit realized using both, and one unit is realized by using two or more pieces of hardware. Two or more units may be implemented by one hardware.

1 is a block diagram of a prefrontal lobe-based cognitive brain-machine interface device according to an embodiment of the present invention.

The prefrontal lobe-based cognitive brain-machine interface device (hereinafter, abbreviated as 'brain-machine interface device' for convenience of explanation) 100 is an EEG detector 110, a memory 120, a processor 130, and a communication module 140. ).

Additionally, as shown in FIG. 1, the brain-machine interface device 100 according to an embodiment of the present invention may further include a 3D scanner 150. In this case, the processor 130 of the brain-machine interface device 100 may transmit and receive data by wired or wireless communication with the 3D scanner 150 through the communication module 140.

Before describing each configuration of the brain-machine interface device 100, the frontal lobe base processed by the brain-machine interface device 100 according to an embodiment of the present invention with reference to FIGS. 2 and 3. The cognitive brain-machine interfacing process is briefly described.

2 is an exemplary view for explaining the overall concept of prefrontal lobe-based cognitive brain-machine interfacing according to an embodiment of the present invention. 3 is an exemplary diagram for explaining the difference between the prefrontal-based cognitive brain-machine interfacing method and the conventional cognitive brain-machine interfacing method according to an embodiment of the present invention.

Referring to FIG. 2, the brain-machine interface device 100 includes an EEG signal of the frontal lobe (particularly, the frontal lobe region) P10 that reflects decision making, planning, evaluation of an ongoing operation, error monitoring, and intentional judgment. The EEG acquisition process, which extracts electroencephalograms (EEGs), is performed. As such, when the BMI is driven based on the acquired prefrontal EEG, an 'external-device control' process is performed in which the idea of the subject and the operation of the external device through the BMI are directly matched. can do. At this time, the brain-machine interface device 100 performs 'feature extraction and classification' processing based on the acquired prefrontal EEG, and performs external device control based on the processing result. As a result, the result driven by the external device is real-time feedback to the measurement target, so that the measurement target can check the driving state of the external device that directly corresponds to the intention associated with the measurement target.

This BMI driving paradigm is a "goal-oriented BMI" technology, which uses EEG signals that directly reflect the high-level intention of the user as the BMI driving signals. The brainwave signal of the prefrontal lobe is a modality-independent signal of peripheral sense such as visual, auditory, and tactile. It contains only the higher-order cognitive intention of the object to be measured. . Therefore, in the BMI driving method using the prefrontal EEG, it is less affected by the type of BMI task (ie, behavior or imagination irrespective of the preset device driving direction) that the measurement target must perform for specific control.

Referring to FIG. 3, an example of performing BMI driving to open a window to the left based on the EEG is illustrated.

In the example illustrated in FIG. 3A, the conventional cognitive BMI technique is used. An EEG corresponding to indirect thinking, such as imagining a hand movement irrelevant to opening a window, is used for driving a BMI. . For example, in the conventional motor-imagery-based BMI technology, the movement-related cortical potential is used as the BMI driving signal.

On the other hand, the example shown in (B) of FIG. 3 is a case of using the prefrontal-based cognitive BMI technology according to an embodiment of the present invention, the EEG of the frontal lobe is used for BMI driving. That is, intuitive BMI driving is possible based on the brainwave signal of the frontal lobe generated when the user directly imagines the operation of opening the window to the left.

Furthermore, prefrontal lobe-based cognitive BMI can be applied to real-time neurofeedback for patients affected by the frontal lobe to apply for rehabilitation of the brain region or to enhance the function of the corresponding region of normal people. For example, the effect of rehabilitation in obsessive-compulsive or ADHD, such as by the user to repeat the imagination of the operation of the external device that you want to control, and to control the external device to execute the operation of the content directly corresponding to the imaginary content, Can be obtained. In other words, neurofeedback is continuously promoted in functionally or neurologically damaged frontal lobe regions through neurofeedback, leading to neurological rehabilitation and functional rehabilitation due to changes in neural plasticity in the brain region. can do. In addition, even in patients with damage to the occipital or parietal lobe, which is an area for obtaining brainwaves, the conventional BMI technology has the advantage of driving BMI using brainwaves generated from the normal frontal lobe.

1, the configuration and operation of the brain-machine interface device 100 according to an embodiment of the present invention will be described in detail.

The EEG meter 110 measures the EEG of the measurement target. In this case, the EEG measuring instrument 110 measures the weight of the EEG of the frontal lobe (particularly, the frontal lobe) of the measurement target.

The EEG 110 may measure EEG in a contact or non-contact manner, and the type of the measurement method is not limited. In addition, the EEG measuring instrument 110 may be an EEG measuring device itself including an EEG measuring means (ie, an EEG measuring electrode, etc.) or may be connected to an EEG measuring device to obtain a measured EEG signal by controlling its operation.

For reference, as shown in FIG. 6 below, at least one configuration 100-1 of the brain-machine interface device 100 is integral with an EEG measuring device (indicated in FIG. 6 that is the EEG 110 itself). It can be implemented as. For example, the EEG measuring apparatus 110 may be implemented in the form of a headset equipped with an EEG measuring means (ie, the electrode 111, etc.) at a plurality of preset positions.

The EEG 110 may continuously measure EEG sizes in a plurality of brain regions on a predetermined frontal lobe. In this case, the EEG measuring means of the EEG measuring instrument 110 may act at positions corresponding to each of a plurality of predetermined brain regions.

The memory 120 stores a cognitive brain-machine interface program for generating a brain-machine interface driving signal according to the direct intention of the object to be measured, based on the prefrontal EEG measured by the EEG detector 110. Processes by such a cognitive brain-machine interface program will be discussed in detail in the description of processor 130 below.

The memory 120 refers to a nonvolatile storage device that maintains stored information even when power is not supplied, and a volatile storage device that requires electric power to maintain stored information.

The processor 130 executes a program stored in the memory 120 and performs processes accordingly.

Hereinafter, the processing of the processor 130 according to the execution of the cognitive brain-machine interface program will be described in detail with reference to FIGS. 4 and 5.

4 is an exemplary diagram for explaining a prefrontal lobe-based cognitive brain-machine interfacing process according to an embodiment of the present invention. FIG. 5 is an exemplary diagram of a broadman region for describing the prefrontal region for acquiring an EEG signal according to an embodiment of the present invention.

In an embodiment of the present invention, the brain-machine interface device 100 will be described for measuring the EEG through a plurality of electrodes (hereinafter, referred to as 'sensor electrodes') attached to the scalp of the measurement target. As illustrated in FIG. 4, a measurement target may wear a headset (ie, an EEG 110) having electrodes disposed at a plurality of positions corresponding to predetermined brain regions.

In order to process the prefrontal lobe-based BMI, it is important to extract the brainwave signal of the frontal lobe precisely from the anatomical location. For example, among the prefrontal regions, the dorsolateral PFC region (e.g., 9 and 46 in the Broadmann area, BA, etc.) may be used for final analysis of information processing that is insensitive or dynamic. And the ventromedial PFC region (e.g., 10, 11, 12, 13, 14, 25, 32, etc. in the Broadman region) is responsible for the final analysis of emotional or static information processing. . Based on this, the brain-machine interface device 100 classifies different regional activities of the frontal lobe and uses them for driving BMI.

At this time, the processor 130 analyzes the EEG measured at the scalp-level and anatomically accurately tracks the location of the brainwave, and tracks the anatomical corresponding brain of the tracked source-level. Use local activity as a BMI feature.

The activity of the various cortical regions of the brain induces electromagnetic activity in the scalp region, and thus the activity of each scalp region is inferred to be generated due to the composition and combination of several source regions. In general, the position at which EEG is measured in the scalp as a result of brainwave signals originating in the brain is limited, whereas the inverse calculation of the brainwave origin is based on the EEG measured in the scalp. This is the "inverse problem" in which an infinite solution exists. To solve this inverse problem, processor 130 models an optimized forwarding model from the source of brainwaves to the sensor electrodes on the scalp, and mathematically calculates backwards based on this. Proceed to obtain the brainwave signal (brainwave signal) from the source required for BMI characterization. The processor 130 performs the modeling of the form that can best distinguish the signals of the frontal lobe and the signals according to the anatomical regions through the optimized forward model.

The processor 130 receives the EEG (hereinafter, referred to as a 'sensor-level signal') measured on the scalp of the prefrontal region of the object to be measured from the EEG detector 110, and then analyzes the source of the sensor level signal. (source-localization) is processed to convert to a prefrontal cortex (PFC) signal of the cortical level (ie, source-level).

The processor 130 uses an inverse program to determine the source region of the brainwave signal, and the PFC signal of the source region corresponding to the EEG (i.e., sensor level signal) in the scalp region. That is, the source level signal) can be calculated. Inverse program is a technique that can detect the degree of activity of the brain at the cortical level, for example, a dipolar model and a distributed source model and the like can be used.

In detail, the processor 130 performs source localization analysis based on sensor level signals measured for each of the prefrontal regions. In this case, a low resolution electromagnetic tomography (LORETA) technique and a cortical current density source model may be used as localization analysis techniques. The processor 130 calculates the source activity degree as a result of the EEG source localization analysis. In other words, the activated brain source region corresponding to the EEG measured at the scalp level of the measurement target and the degree of activity of each region are calculated.

The processor 130 may convert the EEG measured from the scalp of the measurement target into a brain signal of the Broadman region at the source level in real time. For example, the processor 130 may classify the frontal lobe of the left and right hemispheres into five regions, as shown in Table 1 below, to match the corresponding Broadman region, and utilize the activity of each region to drive the BMI. . For reference, the Broadman region is a region in which cortex is grouped by neuronal cell type and characteristics, and the same Broadman region functions functionally identical or similar. In addition, Figure 5 shows the location on the Broadman region of the prefrontal region contained in Table 1 below. However, FIG. 5 is a side view of the brain viewed from one side (left side), and some prefrontal regions of a location where direct expression is difficult for convenience (ie, the other side of the brain) are omitted.

Prefrontal Name Broadman area and features Extremity frontal lobe
(Dorsolateral PFC) BA 9, 46
(Inhibition function, operation function, monitoring function, continuous attention function, etc.) Abdominal prefrontal lobe
(Ventrolateral PFC) BA 44, 45
(Withdrawal and retention of information, action plan updates, etc.) Abdominal frontal lobe
(Ventromedial PFC) BA 12, 13, 14, 25, 32
(Decision making function, emotion control function, etc.) Anterior prefrontal lobe
(Anterior PFC) BA 10
(Multi-task, intent retention, etc.) Orbital Frontal Lobe
(Orbitofrontal cortex) BA 11, 47
(Enhancement behavior function by evaluation / compensation / punishment, emotion control function, etc.)

The processor 130 extracts causal connectivity between brain signals of different prefrontal regions based on the PFC signal as brain signal characteristics (ie, BMI characteristics) according to high-dimensional intention of a measurement target.

There are significant differences in the prefrontal EEG measured from the measurement target according to the cognitive properties according to what the measurement object suggests. Through this, the centrally activated brain region of the plurality of frontal lobe regions to be measured can be detected. At this time, the processor 130 selects two or more brain regions showing causal connectivity and extracts brain signal characteristics. The processor 130 may sequentially select two or more brain regions showing the largest causal connection from the most activated brain region (ie, the brain region with the highest activity).

The processor 130 analyzes directional causality over two selected brain regions over time, and detects causal connectivity between the selected two or more brain regions. In this case, the processor 130 may detect causal functional connectivity by analyzing two or more selected prefrontal EEG signals (PFCs) through a Granger causality technique.

For reference, Granger causality analysis can be used to determine whether a causal relationship exists between two phenomena. Accordingly, the processor 130 detects directional causality (ie, causal connectivity) between two or more activated prefrontal regions of the measurement target through the Granger causality analysis. For example, the degree of causal connectivity can be obtained through a directed transfer function using a multivariate autoregressive model for EEGs obtained from a plurality of sensor electrodes.

As shown in FIG. 4, the causal linkage between the plurality of activated root sites and the activated root sites may be indicated by the color of the arrow and the linking direction may be indicated by the direction of the arrow. have. Using this Granger causality technique, "directional associations (ie causal connections)" between prefrontal regions can be expressed in the form of a mosaic matrix. As in the "classification" step shown in Figure 4, the degree of causal connectivity from j to i on the mosaic matrix is indicated in various colors. In the mosaic matrix, the numbers of the i-axis and the j-axis represent respective Broadman regions.

As such, causal connectivity characteristics are different between the prefrontal regions activated in response to the association of the measurement object. For example, when the measurement target is associated with any motion, the first prefrontal region and the second frontal region may be most activated, and the activation order may have causal connectivity characteristics having any orientation. In addition, when the object to be measured is associated with another operation, the degree of activation or direction may be different even if the prefrontal region different from the first and second prefrontal lobes is most activated or the same prefrontal region is activated. Accordingly, different causality characteristics (ie, BMI characteristics) are displayed for each content associated with the measurement object.

As such, the processor 130 recognizes the prefrontal activation pattern according to causal connectivity between the prefrontal regions. The processor 130 identifies a preset BMI control operation based on the recognized prefrontal activation pattern.

In detail, the processor 130 classifies the extracted brain signal characteristics into different BMI signals through machine learning. In this case, the processor 130 may classify the brain signal characteristics of the frontal lobe into different BMI signals using machine learning methods such as linear discriminant analysis (LDA), support vector machine (SVM), and deep-learning. have. For reference, the type of machine learning method that the processor 130 uses as the classifier is not limited.

The processor 130 processes an operation as a sorter, but machine-learns a prefrontal activation pattern that is previously labeled for a plurality of measurement targets (ie, reminding that the measurement target is intended). The processor 130 generates a control signal by identifying the prefrontal activation pattern according to the EEG of the current measurement target through a machine-learned classifier.

In other words, the processor 130 analyzes the EEG of the measurement target to perform the BMI driving corresponding to the high-dimensional cognitive property of the measurement target, and processes the reference object for a plurality of measurement targets (that is, through BMI). The initial process of learning the prefrontal activation pattern. In this case, the processor 130 may process a calibration for setting a standard value of the classifier by machine learning a feature extracted from a labeled training EEG signal measured for each measurement target. In addition, the prefrontal activation pattern identified through the classifier may be matched with control signals that control the operation of a plurality of external devices, respectively.

Through this, it is possible to distinguish high-dimensional brain signal characteristics corresponding to the object to be measured and to use a control signal matched with the distinguished brain signal characteristics as a BMI driving signal (for example, a preset machine driving control signal). Therefore, the performance accuracy of the BMI drive can be increased.

Meanwhile, referring back to FIG. 1, the brain-machine interface device 100 may use the 3D scanner 150 to precisely convert the spatial accuracy of the EEG measured on the scalp of the measurement object into the EEG source signal of the cerebral cortex level. . This will be described in detail with reference to FIG. 6.

6 is a block diagram illustrating an electrode attachment position checking function of the prefrontal lobe-based cognitive brain-machine interface device according to an embodiment of the present invention.

The EEG may have variations in the EEG measurement position (ie, the position of the electrode) every time it is measured. This variation is a factor in reducing accuracy when converting sensor level signals into source level signals. Therefore, in order to minimize the variation of the measurement position of the electrode every time the EEG measurement, the brain-machine interface device 100 three-dimensional scanning the two images of the electrode and the measurement object.

Referring to FIG. 6, in the EEG 110, electrodes 111 are densely arranged on the frontal lobe region P10 to favor brain source signal extraction. As shown in FIG. 6, a plurality of electrodes 111 may be disposed on a brain region other than the frontal lobe region P10.

For example, on the EEG 110, a plurality of electrodes 111 may be disposed by applying, for example, a 10-10 international system for EEG electrode positions. 10-10 The international system consists of a centerline (first axis) connecting two axes in the head, nasion and inion, and a line connecting both ears through the vertex (second axis). ) Is a high density EEG electrode positioning method in which electrodes are arranged at positions distributed at 10% intervals when viewed at 100%.

In addition, the 3D scanner 150 may recognize the three-dimensional coordinate values of the plurality of electrodes 111, and the landmark electrode may be formed on at least one portion corresponding to the forehead, left / right temples, etc. on the EEG 110. 113) is attached. In this case, the 3D scanner 150 may check or estimate the positions of the respective electrodes 111 based on the distance and angle with respect to the landmark electrode 113.

The 3D scanner 150 scans the position of the head of the measurement target and the positions of the electrodes 111 and 113 of the EEG 110 worn by the measurement target, so that the 3D scanners 150 Create dimensional coordinates. The 3D scanner 150 transmits each generated 3D coordinate value to the processor 130.

When the processor 130 receives three-dimensional coordinate values for each electrode 111 and 113 through the 3D scanner 150, the processor 130 determines whether the preset reference position and the scanned position of each electrode 111 and 113 are the same. do. The processor 130 may output information (visual or audio information, etc.) according to the verification result through an output means (such as a monitor, etc.).

For example, the electrode positioning information may be information indicating whether each electrode 111 and 113 of the EEG 110 is identical to a preset reference position or disposed at a position, and three-dimensional about a head of the measurement target. The information may be visually displayed by matching three-dimensional coordinate values of the electrodes 111 and 113 on the model. The kind and output method of such electrode positioning information are not limited.

The processor 130 may set a reference position with respect to the electrode position based on a result of scanning the head image of the measurement target. For example, the processor 130 matches a predetermined brain region model (eg, a Broadman region model) with respect to the head of the three-dimensional scanned measurement object, and corresponds to the predetermined brain region on the brain region model. The position can be set as the reference position. Further, the processor 130 is based on the previous EEG measurement position, such as the EEG measurement position first performed on the measurement target, the EEG measurement position performed during the initial processing of learning the prefrontal lobe activation pattern, or the EEG measurement position performed immediately before. It is also possible to set the reference position.

The processor 130 may perform the electrode position correction EEG measurement before performing the EEG measurement for driving the BMI in order to minimize the electrode position variation during repeated measurement of the EEG. In this case, the processor 130 outputs a control signal for repeating the EEG measurement until the electrode position of the EEG measuring instrument 110 matches the preset reference position, and the electrode position of the EEG measuring unit 110 coincides with the reference position. After it is confirmed that the brain wave measurement and analysis for the actual BMI can be performed.

As such, by checking whether the EEG electrode position at the time of EEG measurement for BMI driving is the same as the reference position, the problem at the time of source-localization of the EEG signal due to the EEG electrode position variation by repeated measurement is prevented. In addition, the above-mentioned immobilization of the EEG electrode position can be utilized during co-registration of the brain image and the EEG signal.

On the other hand, as shown in Figure 6, the brain-machine interface device 100 according to an embodiment of the present invention may be provided as a separate device from the 3D scanner 150. In this case, the brain-machine interface device 100 refers to the remaining components (ie, the memory 120, the processor 130, and the communication module 140) as a kind of real-time signal analysis device in the portable EEG 110 itself. Hereinafter, referred to as an EEG analysis unit 100-1) may be implemented in a mounted form.

For example, the EEG analysis unit 100-1 transmits a driving signal generated based on real-time prefrontal broadman area activity to the BMI device (ie, an external device) via the communication module 140 via wired / wireless. It can be implemented in hardware. In this case, the EEG analyzing unit 100-1 may be mounted on the back of the head on the EEG measuring unit 110.

The brain-machine interface device 100 may be linked with various BMI equipment. For example, a door lock, which is one of security devices, may be applied as an interlocked BMI device. For reference, the door lock includes a means (not shown) for opening and closing the door, and transmits and receives data to and from the processor 130 of the control module (not shown) and the brain-machine interface device 100 for controlling the operation of the opening and closing means. It may further include a communication module (not shown) for. In this case, when the measurement target is associated with a specific operation (for example, pressing a password of the door lock) associated with the door lock, the frontal lobe activation pattern is extracted by analyzing the EEG signal measured from the scalp of the measurement target in response to the association. In addition, the extracted prefrontal activation pattern may be identified through a machine-learned classifier to generate a matched control signal. The brain-machine interface device 100 may transmit a control signal to perform a mode for receiving information for opening the door lock when the object to be measured is associated with opening the door lock. And when the measurement target is sequentially associated with the numbers corresponding to the password of the door lock, the brain-machine interface device 100 can be controlled to open by transmitting the corresponding numbers sequentially to the door lock.

The BMI device interworking with the brain-machine interface device 100 is not limited to a kind of robot, a smartphone, etc. equipped with a communication function, and is not limited to a kind of driving signal for driving the BMI device.

Hereinafter, a frontal lobe-based brain-machine interface method according to an embodiment of the present invention will be described with reference to FIG. 7.

7 is a flowchart illustrating a prefrontal lobe based cognitive brain-machine interface method according to an embodiment of the present invention.

The prefrontal lobe-based cognitive brain-machine interface method described below may be processed through the processor 130 of the brain-machine interface device 100 described above.

Prior to performing BMI driving based on prefrontal EEG signals, the prefrontal EEG signals of the measurement target measured by the EEG measuring instrument 110 are inputted while the measurement target is already aware of the specific intentions associated with the pre-frontal EEG signals. Receive. As such, the measured EEG signals are labeled for intentions associated with the subject being measured. And feature extraction based on the labeled learning EEG signal. At this time, the most active two or more prefrontal regions of the object to be measured are detected based on the labeled learning EEG signal, and causal connectivity between the detected brain regions is extracted as a prefrontal activation pattern. The extracted prefrontal activation patterns are machine-learned (supervised or unsupervised machine learning) to generate a classifier for the prefrontal activation patterns.

As shown in FIG. 7, when the BMI is driven based on the prefrontal EEG signal, the EEG signal (EEG) of the prefrontal region of the measurement target directly associated with the intention is measured (S710).

Then, the anatomical EEG generation position (ie, root region) corresponding to the measured EEG signal is tracked (S720).

Next, the characteristics of the high-order cognitive EEG signals (ie, the prefrontal activation pattern) are extracted based on the activity of each tracked brain region (ie, the prefrontal region) (S730).

At this time, a source localization analysis is performed on the sensor level signal (ie, the EEG) and converted into a source level signal (ie, the PFC signal). After detecting the prefrontal region activated according to the activity level of the source level signals, causal connectivity is detected by selecting two or more prefrontal regions showing the largest causal connection from the most active prefrontal region. As such, directional causal connectivity between two or more selected prefrontal regions can be extracted as a prefrontal activation pattern.

Next, the extracted brain region activation pattern (ie, the prefrontal activation pattern) is input to the machine-learned classifier as described above, and the characteristics corresponding to the corresponding EEG signal characteristics among the predetermined BMI driving conditions are distinguished (S740).

In operation S750, the control signal is generated and output according to the classification result.

That is, after identifying the BMI driving conditions that directly correspond to the content of the intention of the measurement object, which is labeled in advance, the control signal for performing the content of the intention of the measurement object is transmitted to the corresponding BMI equipment.

On the other hand, in the prefrontal lobe-based cognitive brain-machine interface method according to an embodiment of the present invention, prior to performing the step S710, the electrode positioning process through the 3D scanner 150 may be performed first. This electrode positioning process is the same as or similar to that described above with reference to FIG. 6.

The prefrontal lobe-based cognitive brain-machine interface method according to an embodiment of the present invention as described above may be implemented in the form of a recording medium including instructions executable by a computer, such as a program module executed by a computer. Computer readable media can be any available media that can be accessed by a computer and includes both volatile and nonvolatile media, removable and non-removable media. In addition, computer readable media may include both computer storage media and communication media. Computer storage media includes both volatile and nonvolatile, removable and non-removable media implemented in any method or technology for storage of information such as computer readable instructions, data structures, program modules or other data. Communication media typically includes computer readable instructions, data structures, program modules, or other data in a modulated data signal such as a carrier wave, or other transmission mechanism, and includes any information delivery media.

The foregoing description of the present invention is intended for illustration, and it will be understood by those skilled in the art that the present invention may be easily modified in other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are exemplary in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope of the present invention is shown by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

100: Frontal lobe-based cognitive brain-machine interface device
110: brain wave detector 120: memory
130: processor 140: communication module
150: 3D scanner P10: frontal lobe area

Claims (14)

In a prefrontal lobe based cognitive brain-machine interface device,
EEG measuring instrument for measuring the EEG signal of the frontal lobe of the measurement target;
Memory in which a cognitive brain-machine interface program is stored; And
A processor for executing a program stored in the memory;
According to the execution of the cognitive brain-machine interface program, the processor recognizes a brain region corresponding to the EEG signal of the frontal lobe measured by the EEG from among a plurality of brain regions on the prefrontal lobe previously classified, and recognizes Detects the degree of activity of each brain region, calculates causal connections between two or more brain regions based on the degree of activity of each brain region, extracts prefrontal activation patterns, and pre-machines a plurality of prefrontal activation patterns for the measurement target. Inputting the extracted prefrontal activation pattern to a classifier generated by learning to identify a corresponding driving condition among predetermined brain-machine interface driving conditions, and generating and outputting a predetermined machine driving control signal based on the identified result But
The classifier is generated by pre-frontal lobe-cognitive brain-machine interface device machine learning, respectively, based on the EEG signals of the frontal lobe of the measurement target, each of the prefrontal activation patterns labeled for each of the intended content. The method of claim 1,
The processor,
EEG (electroencephalogram) measured on the scalp of the measurement target is converted into a prefrontal cortex (PFC) signal by analyzing EEG signal source localization, and detects the degree of activity of the converted prefrontal cortex signal, Prefrontal lobe based cognitive brain-machine interface device. The method of claim 2,
The processor,
The EEG is converted into a brain signal of the broadman region, and the brain region is detected by dividing the brain region into at least one broadman region of the extrafrontal frontal lobe, the lateral prefrontal lobe, the abdominal prefrontal lobe, the anterior frontal lobe, and the orbital frontal lobe. Cognitive brain-machine interface device. The method of claim 1,
The processor,
A prefrontal lobe-based cognitive brain-mechanical interface device that recognizes causal connectivity by analyzing directional causality over time by two or more brain region-specific EEG signals through a Granger causality technique. The method of claim 4, wherein
3D scanner which is to be worn by the head and the measurement target of the measurement target, and generates a three-dimensional coordinate value for each electrode for measuring the EEG by three-dimensional scanning the EEG measuring device having a plurality of EEG measuring electrodes arranged for each predetermined brain region location ; And
Further comprising a communication module for transmitting and receiving data with external devices including the 3D scanner,
The processor is a frontal lobe-based cognitive brain-mechanical interface device for outputting the electrode position confirmation result by confirming whether or not match with a predetermined reference position for each electrode for electroencephalogram based on the three-dimensional coordinate value for each electrode for electroencephalogram measurement . The method of claim 5,
The brain wave detector is integrally provided with the memory, a processor, and a communication module,
A prefrontal lobe-based cognitive brain-machine interface device for communicating with the 3D scanner by wire or wirelessly through the communication module to receive the 3D coordinate value and the result of 3D scanning of the head. In a prefrontal lobe-based cognitive brain-machine interface method using a prefrontal lobe-based cognitive brain-machine interface device,
Receiving an EEG signal of a frontal lobe of a measurement object from an EEG meter;
Recognizing a brain region corresponding to an EEG signal of the frontal lobe measured by the EEG from among a plurality of brain regions on a prefrontal lobe previously classified;
Detecting the degree of activity of each recognized brain region and extracting a prefrontal lobe activation pattern by calculating causal connections between two or more brain regions based on the degree of activity of each brain region;
Identifying a corresponding driving condition among predetermined brain-machine interface driving conditions by inputting the extracted prefrontal activation pattern to a classifier generated by pre-machine learning a plurality of prefrontal activation patterns for the measurement target; And
Generating and outputting a predetermined machine drive control signal based on the identified result;
The classifier,
The prefrontal lobe-based cognitive brain-machine interface method is generated by machine learning each of the prefrontal activation patterns labeled for each of a plurality of intentions based on the EEG signals of the frontal lobe of the measurement target. The method of claim 7, wherein
Recognizing the brain region,
The EEG (electroencephalogram) measured on the scalp of the measurement target is converted to a prefrontal cortex (PFC) signal by analyzing EEG signal source localization, prefrontal cortex-based cognitive brain-machine interface method. The method of claim 8,
The EEG is converted into a brain signal of the broadman region, and the brain region is detected by dividing the brain region into at least one broadman region of the extrafrontal frontal lobe, the lateral prefrontal lobe, the abdominal prefrontal lobe, the anterior frontal lobe, and the orbital frontal lobe. Cognitive brain-machine interface method. The method of claim 8,
The EEG signal source localization analysis technique, using a low resolution electromagnetic tomography (LORETA) technique and a cortical current density source model (cortical current density source model), the frontal lobe based cognitive brain. -Machine interface method. The method of claim 8,
Extracting the prefrontal lobe activation pattern,
Detecting a degree of activity of the converted prefrontal cortex signal; And
Based on the degree of activity, the frontal lobe-based cognitive includes recognizing causal connectivity by analyzing directional causality of two or more brain regions by directional causality over a Granger causality technique. Brain-machine interface method. The method of claim 11,
A prefrontal lobe-based cognitive brain-machine interface method, using a multivariate autoregressive model to calculate the degree of causal connectivity through a directed transfer function. The method of claim 11,
Recognizing the causal connectivity,
And sequentially selecting two or more brain regions having the largest causal connection from the most activated brain region based on the degree of activation for each brain region. The method of claim 7, wherein
The EEG measuring instrument is a plurality of EEG measuring electrodes are arranged for each predetermined brain region location,
Before receiving the EEG signal of the frontal lobe of the measurement target,
Receiving a three-dimensional coordinate value for each electrode for measuring the EEG as a result of the three-dimensional scanning of the head of the measurement target and the EEG measuring instrument worn by the measurement target from a 3D scanner linked in advance;
Confirming whether or not a coincidence with a predetermined reference position for each of the EEG measuring electrodes is based on a three-dimensional coordinate value for each of the EEG measuring electrodes; And
And outputting electrode positioning information based on the result of the confirmation.