KR20140022312A - Device for measuring vital signs of drivers - Google Patents

Abstract

The present invention relates to a device for measuring the vital signs of a driver. The device for measuring the vital signs of a driver according to one embodiment of the present invention comprises a main body of a vehicle; a vital sign detection part for detecting the vital signs of a driver; a control part for monitoring the state information about the driver based on the vital signs; and a state transmission part for transmitting the state information about the driver to an external device, wherein the vital sign detection part receives, from the main body of the vehicle, information about noise induced by the main body of the vehicle, removes the noise included in the detected vital signs using the information about the noise, and transmits the vital signs, which has the noise removed, to the control part. [Reference numerals] (110) Vital sign detection part; (120) Control part; (130) State transmission part; (AA) GSR, ECG, EEG, EOG detection system; (BB) Driver state monitoring system; (CC) Wired and wireless driver state monitoring signal transmission part

Description

DEVICE FOR MEASURING VITAL SIGNS OF DRIVERS

The present invention relates to an apparatus for measuring a biosignal of a vehicle driver.

The present invention acquires a driver's biosignal in relation to a driver assistance system (DAS) or an active safety system of a vehicle, and uses the same to grasp the driver's driving concentration and tiredness in real time. Therefore, the present invention relates to a biosignal measuring apparatus of a driver that supports changing a function setting of a vehicle for safety while driving.

The driver's physical and mental state can be detected by using minute current signals flowing in both hands of the driver using ECG (Electrocardiogram) and Galvanic Skin Resistance (GSR) sensors, and furthermore, Electroencephalography (EEG) and EOG Using the Electroloculogram sensor, the driver's brain activity can be detected more directly through microcurrent signals that can be detected in the skin around the head.

In particular, when the EEG sensor and the EOG sensor are used, the driver's drowsy driving situation or the driver's distraction can be detected through the driver's brain waves.

However, even when collecting the biosignal of the driver using various sensors, there is a problem that it is difficult to diagnose the exact state of the driver when the collected biosignal is mixed with noise. Accordingly, in order to accurately diagnose the drowsiness state and the emotional state of the driver, and to feed the feedback back to the driver, the biosignal of the driver from which the environmental factors (eg, noise) are removed needs to be collected.

An object of the present invention is to provide a biosignal measurement apparatus of a vehicle driver capable of collecting the biosignal of a vehicle driver from which environmental factors are removed.

According to an embodiment of the present disclosure, an apparatus for measuring a biosignal of a driver may include: a vehicle body; A biosignal detector configured to detect a biosignal of a driver; A controller configured to monitor state information of the driver based on the biosignal; And a state transmitting unit which transmits the state information of the driver to an external device. The bio signal detecting unit receives information related to noise generated from the vehicle body from the vehicle body, removes noise included in the detected bio signal using the information related to the noise, and removes the noise. The biosignal may be transmitted to the controller.

The biosignal detection unit may include: at least one first electrode disposed on a handle of the vehicle body to receive the biosignal of the driver from both hands of the driver; And at least one second electrode disposed in the headset worn by the driver so as to receive the biosignal of the driver from the driver's brain or eyeball.

The biosignal detection unit may be a sensor connected to the first electrode, a galvanic skin resistance (GSR) sensor configured to detect a skin resistance of the driver, and an ECG formed to detect an electrocardiogram of the driver. An electrocardiogram sensor, the sensor being connected to the second electrode, an electroencephalography (EGE) sensor configured to detect the brain wave of the driver, and an electrorooculogram (EOG) sensor configured to detect eye movement of the driver; Can be.

In example embodiments, the controller may analyze a cycle and a waveform change of the biosignal detected by the GSR sensor and output a drowsy driving possibility value of the driver as the driver's state information.

In example embodiments, the controller may analyze the frequency characteristic of the biosignal detected by the EEG sensor and output mental state information of the driver corresponding to the frequency characteristic as the driver's state information.

In example embodiments, the controller may analyze a waveform period and a shape of the biosignal detected by the EOG sensor and output a drowsy driving possibility value of the driver as the driver's state information.

In an embodiment, a switch is connected to the biosignal detecting unit, and the switch detects the biosignal of the driver only when the pressure is greater than or equal to a predetermined value applied to the first electrode. The turn off may be controlled according to whether or not a pressure greater than or equal to a predetermined value is applied to the first electrode.

The biosignal detection unit may include: an analog front-end circuit unit including an operational amplifier for removing the noise included in the detected biosignal; An A / D converter for converting the biosignal in analog signal form into a digital signal form; And a filter for extracting the biosignal from which the noise is removed from the sensed biosignal and may include a DSP operation unit that performs digital signal processing.

According to the present invention, the driver's emotional state can be accurately grasped by collecting the driver's biosignal from which environmental factors (eg, noise) are removed. Accordingly, an error that may occur when emotion control of the driver according to the driver's biosignal is performed may be reduced. As a result, the occurrence of an accident due to an abnormal emotional state of the driver while driving can be effectively prevented.

1 is a block diagram illustrating an apparatus for measuring a biosignal of a driver related to the present invention.
FIG. 2 is a block diagram illustrating a biosignal detector according to FIG. 1.
3 is a flowchart illustrating a method of measuring a biosignal of a driver according to FIG. 1.
4 is a conceptual diagram illustrating noise of a front seat of a vehicle according to the speed of the vehicle.
5 and 6 are conceptual views illustrating an embodiment in which a controller monitors a signal detected by an EEG sensor.
7 is a conceptual diagram illustrating an embodiment in which a controller monitors a signal detected by an EOG sensor.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art may easily implement the technical idea of the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. 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.

1 is a block diagram illustrating an apparatus 100 for measuring a biosignal of a driver related to the present invention. The biosignal measuring apparatus 100 of the driver includes a vehicle body, a biosignal detector 110, a controller 120, and a state transmitter 130.

Referring to FIG. 1, the biosignal detecting unit 110 may detect a biosignal of a driver from a driver.

The biosignal detection unit 110 may include a galvanic skin resistance (GSR) sensor configured to detect a skin resistance of the driver and an ECG (Electrocardiogram) sensor configured to detect an electrocardiogram of the driver. In addition, the biosignal detection unit 110 may include an electroencephalography (EGE) sensor configured to detect an electroencephalogram of the driver and an electrorooculogram (EOG) sensor configured to detect eye movement of the driver.

Here, the GSR sensor and the ECG sensor may detect the biosignal from both hands of the driver. Accordingly, the first electrode may be disposed on the steering wheel of the vehicle body, and the GSR sensor and the ECG sensor may be connected to the left and right divided electrodes embedded in the steering wheel of the vehicle, that is, the first electrode.

In this case, the quality of the biosignals detected by the GSR sensor and the ECG sensor may be sensitively changed depending on the state of contact with the electrode. In addition, the biosignal detected as the driver moves may be distorted.

In order to overcome this, a switch may be connected to the biosignal detecting unit 110. The switch is turned off depending on whether the biosignal detection unit 110 detects the biosignal of the driver only when a pressure greater than or equal to the preset value is applied to the first electrode, depending on whether the pressure greater than or equal to the preset value is applied to the first electrode. Can be controlled. For example, the switch may be switched to the ON state only when a pressure equal to or greater than a preset value is applied to the first electrode, and the biosignal detection unit 110 may detect the biosignal of the driver.

In addition, the EEG sensor and the EOG sensor can detect a biosignal from the driver's brain or eye. Accordingly, the second electrode may be disposed in the headset, and the EEG sensor and the EOG sensor may be connected to the second electrode.

On the other hand, as a method for detecting the micro-electrical signals caused by brain activity and eye activity, the bipolar induction method for detecting the biological signals from the frontal and frontal lobe region of the brain with the center of the forehead as a reference electrode and the forehead, etc. A unipolar induction method may be considered in which an active electrode is attached to a region of interest and a reference electrode is attached to an inactive region such as an earlobe or a lip protrusion (ear rear protrusion).

The bipolar induction method can minimize the contamination of the EEG signal by the EOG signal, such as blinking eyes, due to the symmetrical signal detection characteristic. However, in order to utilize the distortion phenomenon of the EOG signal to monitor the driver's condition, a signal detection method using a monopole induction method may be more preferred.

In this case, the second electrode used may be applied with a dry form as a priority in order to minimize the burden on the driver. The second electrode may be arranged in a headset worn by the driver to use a communication means or the like when driving. In addition, the utterance state of the driver is acquired through information obtained from the microphone included in the headset, and the distortion phenomenon of the EEG signal and the EOG signal according to the utterance of the driver can be corrected using this. On the other hand, although described with respect to the headset, the second electrode may be arranged in a separate band or other fixing means.

The biosignal detection unit 110 may receive information related to noise generated from the vehicle body from the vehicle body. That is, the biosignal detecting unit 110 may receive information related to noise characteristics induced from the vehicle, such as a rotational speed of the vehicle engine, from the vehicle body in order to remove noise included in the detected biosignal and amplify the biosignal. have.

Thereafter, the biosignal detector 110 may remove noise included in the detected biosignal. In addition, the biosignal from which the noise is removed may be transmitted to the controller 120.

The controller 120 may monitor the driver's state information based on the biosignal received from the biosignal detector 110. The driver's state information may include at least one of a driver's concentration state, a driver's emotional state, a driver's psychological state, a driver's drowsiness state, and whether the driver's sleep is present.

For example, the controller 120 may output state information (drowsy driving possibility value) quantifying the driver's drowsy driving possibility. The controller 120 may transmit the output driver's state information to the state transmitter 130.

The state transmitter 130 may transmit the driver state information to the external device. Here, the external device may include at least one of an IT device, such as a driving support system, an active safety system, a vehicle navigation system, a vehicle multimedia device, and a smart phone disposed in the vehicle, which may be provided in the vehicle.

On the other hand, the status transmitter 130 may transmit the driver's status information to an external device wirelessly using Bluetooth, ZigBee, WIFI, or the like, and may be wired using RS-232, RS-485, USB, CAN, or the like. It may be.

2 is a block diagram illustrating the biosignal detecting unit 110 according to FIG. 1. The biosignal detection unit 110 may include a GSR sensor 111, an ECG sensor 112, an EEG sensor 113, an EOG sensor 114, an analog front-end circuit unit 115, and an A / D. The converter 116 and the DSP calculator 117 are included.

Referring to FIG. 2, the biosignal detecting unit 110 may include at least one first electrode disposed on a handle of a vehicle body to receive the biosignal of the driver from both hands of the driver, and the driver from the brain or eye of the driver. It may include at least one second electrode disposed in the headset worn by the driver to receive the bio-signal of the.

Here, the GSR sensor configured to detect the skin resistance of the driver and the ECG sensor configured to detect the electrocardiogram of the driver may be connected to the first electrode, and the EEG sensor and the eye movement of the driver may be connected to the first electrode. The EOG sensor, which is configured to sense, may be connected to the second electrode.

The biosignal detecting unit 110 includes an analog front-end circuit 115 including an operational amplifier for removing noise included in the received biosignal and amplifying the biosignal. can do. Here, the OP amplifier may include an instrumental amplifier.

In addition, the biosignal detecting unit 110 includes an A / D converter for converting a biosignal in an analog signal form into a digital signal form and a DSP calculator for performing digital signal processing of the biosignal converted into a digital signal form. can do.

In detail, for effective signal processing in a driving environment of a vehicle, a microphone signal capable of detecting a driver's conversation situation, a rotation speed of an engine, and the like may be additionally input to the DSP calculating unit 117 that performs digital signal processing. have.

Meanwhile, when the engine of the vehicle operates, the spark plug also operates. When an electrical signal is applied to the spark plug, the DSP calculator 117 may recognize accurate frequency information of noise caused by the electrical signal. In addition, the DSP operation unit 117 may use a notch filter or an adaptive filter to remove noise in the 55 to 60 Hz band, which is an AC power frequency generally included in an external environment. Accordingly, the DSP calculating unit 117 can effectively shape the biosignal.

In addition, the DSP calculating unit 117 determines whether the input biosignal is contaminated by a driver's conversation input to the microphone, and utilizes a signal of the microphone and the microphone itself having a relatively low contamination level, and the EEG signal is effective. The judgment mode can be changed to use only in the signal area to monitor the driver's condition.

3 is a flowchart illustrating a method of measuring a biosignal of a driver according to FIG. 1. The driver's biosignal measuring apparatus 100 (see FIG. 1) includes a vehicle body, a biosignal detector 110 (see FIG. 1), a controller 120 (see FIG. 1), and a state transmitter 130 (see FIG. 1). do.

Referring to FIG. 3, first, a step (S110) of detecting a biosignal of a driver is performed. The biosignal detection unit 110 is configured to detect a driver's eye movement and a GSR sensor formed to detect a skin resistance of the driver, an ECG sensor formed to detect an electrocardiogram of the driver, an EEG sensor formed to detect a brain wave of the driver The EOG sensor may be included.

Next, a step (S120) in which information related to noise generated from the vehicle body is provided from the vehicle body (S120) and a step (S130) of removing noise included in the detected biosignal using the information related to the noise are performed.

The biosignal detection unit 110 may receive information related to noise characteristics induced from the vehicle, such as a rotational speed of the vehicle engine, to remove noise included in the detected biosignal and amplify the biosignal from the vehicle body. The biosignal detection unit 110 may remove noise from the detected biosignal. In this case, a notch filter or an adaptive filter may be used.

Thereafter, the step S140 of transmitting the biosignal from which the noise is removed is transmitted to the controller 120. The biosignal detector 110 may transmit the biosignal in which the noise is controlled to the controller 120.

Next, step S150 is performed in which state information of the driver is monitored based on the biosignal.

The driver's state information may include at least one of a driver's concentration state, a driver's emotional state, a driver's psychological state, a driver's drowsiness state, and whether the driver's sleep is present. For example, the controller 120 may output state information (drowsy driving possibility value) quantifying the driver's drowsy driving possibility. The controller 120 may transmit the output driver's state information to the state transmitter 130.

In more detail, the controller 120 analyzes the period and waveform change of the biosignal detected from the GSR sensor, analyzes the waveform period and the shape of the biosignal detected from the EOG sensor, and drowsiness of the driver as the driver's status information. The operability value can be output.

In addition, the controller 120 may analyze the frequency characteristic of the biosignal detected by the EEG sensor and output the driver's mental state information corresponding to the frequency characteristic as the driver's state information.

Thereafter, step S160 is performed in which the driver's state information is transmitted to the external device.

Here, the external device may include at least one of an IT device, such as a driving support system, an active safety system, a vehicle navigation system, a vehicle multimedia device, and a smart phone disposed in the vehicle, which may be provided in the vehicle.

The state transmitting unit 130 may transmit the driver's state information to an external device wirelessly using Bluetooth, ZigBee, WIFI, or the like, or may be transmitted by wire using RS-232, RS-485, USB, or CAN. .

As described above, according to the present invention, the driver's emotional state can be accurately determined by collecting the driver's biosignal from which the environmental factors (for example, noise) are removed. Accordingly, an error that may occur when emotion control of the driver according to the driver's biosignal is performed may be reduced. As a result, the occurrence of an accident due to an abnormal emotional state of the driver while driving can be effectively prevented.

4 is a conceptual diagram illustrating noise of a front seat of a vehicle according to the speed of the vehicle.

Referring to FIG. 4, the biosignal detection unit 110 may amplify the biosignal 1000 times analogously through an amplification circuit. The biosignal detector 110 may provide a common mode rejection ratio (CMRR) of 135 dB in the 60 Hz band through a circuit to which the amplified biosignal is applied to the notch filter.

In addition, the biosignal detection unit 110 removes the front seat noise in the vehicle according to the speed of the vehicle, that is, the noise of the 85 to 105 phon band using an adaptive filter, and uses a digital band pass filter and an amplifier to remove the signal from 0 to -3 dB. Band-pass filtering of ~ 35Hz ensures accurate recognition of noise-free driver biosignals.

5 and 6 are conceptual views illustrating an embodiment in which the controller 120 (see FIG. 1) monitors a signal detected by an EEG sensor.

The present invention may include a control unit 120 as a means for quantifying a parameter for determining a driver's state by analyzing a biometric signal that has been formatted through the biosignal detection unit 110.

Although not shown, ECG signal analysis may be utilized as an embodiment of the means for monitoring the driver's condition. In general, the ECG signal is used to determine the psychological state of the individual and is also used in polygraphs. The controller 120 may distinguish the driver's psychological state by continuously observing the cycle characteristics of the driver's ECG signal and the change in the waveform, thereby quantifying and outputting the driver's drowsy driving possibility value.

5 and 6, the EEG signal analysis may be utilized as another embodiment of the means for monitoring the driver's condition. As shown, EEG signals can be classified into six types according to their frequency characteristics. In general, the delta type represents sleep, the theta type sleeps, the alpha type is relaxed, the low beta is concentrated, the middle beta is alert, and the high beta is excited.

7 is a conceptual diagram illustrating an embodiment in which the controller 120 monitors a signal detected by an EOG sensor.

In the frequency analysis of the EEG signal illustrated in FIGS. 5 and 6, there is a problem in that the EEG signal is deteriorated due to the EOG signal generated by blinking eyes and the like, so that proper analysis cannot be performed. Accordingly, the driver's condition can be monitored more accurately through frequency analysis of the EEG signal.

Referring to FIG. 7, the EOG signal analysis may be additionally utilized due to the assumption that the driver usually opens his eyes while driving the vehicle. The EOG signal generated by the blinking of the driver as shown in FIG. 7 may be used as a basis signal for quantifying the drowsiness of the driver as the controller 120 analyzes the period and shape of the waveform.

As illustrated in FIGS. 5 to 7, the present invention may use each or a combination of the ECG signal, the EEG signal, and the EOG signal as the driver's condition monitoring criteria and determination criteria. In addition, the present invention prefers to use each signal at the same time on the basis that the accuracy of the determination can be improved by considering the correlation of each signal at the same time.

In addition, the present invention includes a state transmitting unit 130 for transmitting the state of the driver determined by the controller 120 to various devices provided in the vehicle. The state transmitter 130 may transmit the driver state information to the external device. Here, the external device may include at least one of an IT device, such as a driving support system, an active safety system, a vehicle navigation system, a vehicle multimedia device, and a smart phone disposed in the vehicle, which may be provided in the vehicle.

On the other hand, the status transmitter 130 may transmit the driver's status information to an external device wirelessly using Bluetooth, ZigBee, WIFI, or the like, and may be wired using RS-232, RS-485, USB, CAN, or the like. It may be.

According to the embodiment disclosed herein, the above-described method can be implemented by a code that can be read by a processor on a medium on which the program is recorded. Examples of the medium that can be read by the processor include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage, etc., and may be implemented in the form of a carrier wave (e.g., transmission over the Internet) .

In the apparatus for measuring a biosignal of a vehicle driver disclosed herein, the configuration and method of the above-described embodiments may not be limitedly applied, but all or a part of the embodiments may be selectively combined so that various modifications may be made. It may be.

Claims (8)

A vehicle body;
A biosignal detector configured to detect a biosignal of a driver;
A controller configured to monitor state information of the driver based on the biosignal; And
It includes a state transfer unit for transmitting the state information of the driver to an external device,
The biological signal detection unit,
Receives information related to noise generated from the vehicle body from the vehicle body, removes noise included in the detected biosignal using the noise related information, and transmits the noise-removed biosignal to the controller. Device for measuring the bio-signal of the driver, characterized in that the transmission. The method of claim 1,
The biological signal detection unit,
At least one first electrode disposed on a handle of the vehicle body to receive the bio signal of the driver from both hands of the driver; And
And at least one second electrode disposed in a headset worn by the driver so as to receive the driver's biosignal from the driver's brain or eyeball. 3. The method of claim 2,
The biological signal detection unit,
A sensor connected to the first electrode, the sensor includes a galvanic skin resistance (GSR) sensor configured to detect a skin resistance of the driver and an ECG (Electrocardiogram) sensor configured to detect an electrocardiogram of the driver.
A sensor connected to the second electrode, comprising: an electroencephalography (EEG) sensor configured to detect an electroencephalogram of the driver and an EOG (Electrooculogram) sensor configured to detect eye movement of the driver Signal measuring device. The method of claim 3, wherein
The control unit,
And analyzing a cycle and a waveform change of the biosignal detected by the GSR sensor, and outputting a drowsy driving possibility value of the driver as the driver's state information. The method of claim 3, wherein
The control unit,
And analyzing the frequency characteristic of the biosignal detected by the EEG sensor and outputting the mental state information of the driver corresponding to the frequency characteristic as the driver's state information. The method of claim 3, wherein
The control unit,
And analyzing a waveform period and a shape of the biosignal detected by the EOG sensor, and outputting the driver's drowsy driving possibility value as state information of the driver. 3. The method of claim 2,
A switch is connected to the biosignal detection unit,
Wherein the switch comprises:
The turn-off is controlled according to whether a pressure greater than or equal to a predetermined value is applied to the first electrode such that the biosignal sensing unit detects a biosignal of the driver only when a pressure greater than or equal to a predetermined value is applied to the first electrode. Biometric signal measuring apparatus of the driver, characterized in that. The method of claim 1,
The biological signal detection unit,
An analog front-end circuit unit including an operational amplifier for removing the noise included in the sensed biological signal;
An A / D converter for converting the biosignal in analog signal form into a digital signal form; And
And a filter for extracting the biosignal from which the noise has been removed from the sensed biosignal, and including a DSP operation unit for performing digital signal processing.

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