This application claims priority from Korean Patent Application No. 10-2005-0047193, filed on Jun. 2, 2005, in the Korean Intellectual Property Office, the disclosure of which is incorporated herein in its entirety by reference.
1. Field of the Invention
The present invention relates to an apparatus and method for attaching, to a subject, a biosignal measurement sensor that is used to measure a voltage signal generated from a living body.
2. Description of the Related Art
Sensors attached to a living body to collect information generated from the living body include an electrocardiogram (ECG) sensor and an electromyogram (EMG) sensor. The ECG sensor is attached to the chest of a living body to measure a voltage signal generated from the heart. That is, as the heart palpitates, current is generated from the chest and flows along the skin. The ECG sensor is used to measure a voltage difference between two positions on the skin where the current flows using electrodes located at the two positions.
In general, an electrocardiogram is measured by attaching electrodes on the surface of the skin in a method such as a standard limb lead method, a unipolar limb lead method, and a precordial lead method. When the electrodes are not accurately attached to the surface of the skin, a signal having a modified pattern may be generated so that an accurate diagnosis is not available. In other words, the pattern spreading from the heart has different strengths and direction according to the position from the heart. When the electrodes are not appropriately arranged according to the characteristic of the pattern, an accurate signal cannot be obtained. In particular, in the conventional technology, the electrodes are separately and manually attached to the skin. Therefore, a lot of time and expertise are required to accurately arranged and attach all electrodes. If the electrodes are not arranged accurately, incorrect data may be obtained.
To address the above problem, there is an example of forming the electrodes in an integrate body. In this case, however, an accurate diagnosis is difficult because the electrodes are arranged at almost the same positions in spite of the different position of the heart for each patient.
To address the above and/or other problems, the non-limiting embodiments of the present invention provide an apparatus and method for attaching a biosignal measurement sensor to a subject which allows the biosignal measurement sensor to be accurately and easily attached to any positions of the subject, so that an accurate biosignal is obtained.
According to an aspect of the present invention, an apparatus for attaching a biosignal measurement sensor to a subject comprises a housing having an open space at one side, an installation portion installed in the open space, on which the biosignal measurement sensor is installed, a plurality of detection electrodes installed at an open side of the housing to contact the subject, and arranged along a circumferential edge of the installation portion to form pairs of two detection electrodes facing each other with respect to a center of arrangement, an actuator installed in the housing and rotating and linearly moving the installation portion, and a circuit portion searching for the detection electrodes that provide optimal detection data based on a difference in signals between the detection electrodes forming a pair, and driving the actuator to allow a pair of sensor electrodes provided at the biosignal measurement sensor to be arranged in the same direction in which the searched detection electrodes are arranged.
The optimal detection data is detection data having the maximum correlation coefficient with respect to reference data. The circuit portion comprises a microcontroller which searches the detection electrodes having the detection data having the maximum correlation coefficient by calculating correlation coefficients between the detection data and the reference data, and providing a control signal to the actuator to allow the sensor electrodes to be arranged in the same direction in which the searched detection electrodes are arranged.
The optimal data is the detection data having the maximum peak. The circuit portion comprises a microcontroller which searches the detection electrodes having the detection data having the maximum correlation coefficient by calculating correlation coefficients between the detection data and the reference data, and providing a control signal to the actuator to allow the sensor electrodes to be arranged in the same direction in which the searched detection electrodes are arranged.
According to another aspect of the present invention, a method of attaching a biosignal measurement sensor comprises installing the biosignal measurement sensor having a pair of sensor electrodes at an installation portion, allowing detection electrodes arranged along a circumference to form pairs of the detection electrodes facing to each other, to contact a subject, obtaining detection data from a difference between signals of the detection electrodes forming each of the detection electrode pairs, searching detection electrodes having optimal detection data among the detection data, locating the biosignal measurement sensor by moving the installation portion such that the sensor electrodes are arranged in the same direction in which the searched detection electrodes are arranged, and attaching the biosignal measurement sensor to the subject and then separating the biosignal measurement sensor from the installation portion.
The above and other features and aspects of the present invention will become more apparent by describing in detail non-limiting embodiments thereof with reference to the attached drawings in which:
Referring to
The opening 111 of the housing 110 has an almost circular shape so that the detection electrodes 130 can be arranged along the circumferential edge of the opening 111. The installation portion 120 has a disc shape corresponding to the shape of the opening 111. Also, the installation portion 120 may have various shapes other than the disc shape as shown in the drawings as long as it can rotate in the opening 111.
A biosignal measurement sensor 10 is installed at the installation portion 120. The biosignal measurement sensor 10 includes a patch 11 in which an adhesive material is coated on a side thereof attached to a subject 20, and a pair of sensor electrodes 12a and 12b included in the patch 11. One of the sensor electrodes 12a and 12b is a positive electrode while the other one is a negative electrode. The biosignal measurement sensor 10 is used to measure electrocardiogram or electromyogram by being attached to the skin of the subject 20. The signals from the subject 20 measured by the sensor electrodes 12a and 12b can be transferred to a receiver 50 through RF unit 51 by wireless communication (see
The receiver 50 includes a sensor signal processing portion 53 for amplifying a difference between signals from the subject 20 measured by the sensor electrodes 12a and 12b, digitalizing the amplified signal difference, and generating sensor data, and a storing portion 55 for storing the sensor data generated by the sensor signal processing portion 53. The sensor data generated by the sensor signal processing portion 53 is stored in the storing portion 55 or displayed through a display portion 57. When the sensor signal processing portion 53 is located outside the patch 11, the sensor signal processing portion 53 may be connected to the sensor electrodes 12a and 12b by wire and receives the signals measured by the sensor electrodes 12a and 12b. The sensor signal processing portion 53 and the storing portion 55 may be included in the patch 11 with the sensor electrodes 12a and 12b to form the biosignal measurement sensor 10.
The installation portion 120 has a gripper 125 to grip and release the biosignal measurement sensor 10. The gripper 125, as shown in
The installation portion 120 may include a position detection portion 126 to detect whether the biosignal measurement sensor 10 is located therein. Also, the position detection portion 126 is used to control the gripper 125. The position detection portion 126 transfers information to the circuit portion 150 to control the gripper 125. When the position detection portion 126 detects that the biosignal measurement sensor 10 is located at the installation portion 120, the circuit portion 150 receives the information and controls the gripper 125 to change from a release position to a grip position. When the position detection portion 126 detects that the biosignal measurement sensor 10 is not located at the installation portion 120, the circuit portion 150 receives the information and controls the gripper 125 to wait at a release position.
The information provided from the position detection portion 126 can be transferred to the circuit portion 150 and used to control the actuator 140. For example, when the position detection portion 126 detects that the biosignal measurement sensor 10 is not located at the installation portion 120, the circuit portion 150 receives the information and operates the actuator 140 such that the installation portion 120 waits at an entrance of the opening 111 of the housing 110 or waits in a state of protruding from the entrance. When the installation portion 120 waits at the entrance of the opening 111 of the housing 110, the biosignal measurement sensor 10 can be easily installed at the installation portion 120. When the position detection portion 126 detects that the biosignal measurement sensor 10 is located at the installation portion 120, the circuit portion 150 receives the information and operates the actuator 140 such that, when the biosignal measurement sensor 10 is fixed to the installation portion 120 by the gripper 125, the installation portion 120 moves inwardly from the entrance of the opening 111 of the housing 110 and waits there. When the installation portion 120 is moved inwardly from the entrance of the opening 111 of the housing 110, the biosignal measurement sensor 10 can rotate in a state of being separated from the subject 20 while the detection electrodes 130 contact the subject 20.
An identification mark 160 is provided at the installation portion 120 and the biosignal measurement sensor 10 so that the sensor electrodes 12a and 12b of the biosignal measurement sensor 10 can be arranged at designated positions on the installation portion 120. The identification mark 160, as shown in
The actuator 140 for rotating and linearly moving the installation portion 120, as shown in
The detection electrodes 130 are arranged at the side of the opening 111 of the housing 110 where the installation portion 120 is installed. The detection electrodes 130 are installed at the circumferential edge of the opening 111 of the housing 110 to contact the subject 20 and obtain voltage signals. The detection electrodes 130 are arranged around the installation portion 120 such that two opposite detection electrodes, with respect to the center of the arrangement, form a pair. The detection electrodes 130 are provided in an even number, such that pairs of detection electrodes are provided. Among each pair of the detection electrodes, one functions as a positive electrode while the other functions as a negative electrode. Thus, a voltage signal is obtained from the subject 20 like the sensor electrodes 12a and 12b of the biosignal measurement sensor 10. The detection electrodes 130 are provided in multiple pairs because it is necessary to obtain a voltage signal in various directions with respect to the subject 20.
For example, as shown in
As the detection electrodes 130 are configured as above, the voltage signals sequentially obtained from various directions with respect to the subject 20, that is, the twelve directions, are provided to the circuit portion 150 before the sensor electrodes 12a and 12b are attached to the subject 20. Thus, a direction in which an optimal voltage signal of the provided voltage signals is obtained, can be searched so that the sensor electrodes 12a and 12b are arranged and attached in the same searched direction. Thus, not only an expert, but also a novice, can attach the biosignal measurement sensor 10 to the subject 20 with the sensor electrodes 12a and 12b arranged accurately and easily. As a result, an accurate biosignal is obtained so that accurate diagnosis can be made. Also, in the electrocardiogram test, accurate diagnosis can be made even when the position of the heart of a patient varies. The sensor electrodes 12a and 12b can be arranged at positions where more accurate voltage signals are obtained as the number of voltage signals obtained by the detection electrodes 130 increases. Although the twelve detection electrodes are provided in this embodiment, the number of the detection electrodes in the present invention is not limited thereto.
The detection electrodes 130 are electrically connected to the circuit portion 150 such that the voltage signals obtained by the detection electrodes 130 are provided to the circuit portion 150 to be processed. The circuit portion 150 processes the voltage signals obtained by each pair of the detection electrodes 130 and generates detection data. Then, the circuit portion 150 searches for a pair of the detection electrodes 130 that provides the optimal detection data and generates a control signal for driving the actuator 140 based on the searched result. The control signal is transmitted to the actuator 140 and the actuator 140 rotates the installation portion 120 so that the sensor electrodes 12a and 12b are arranged in the same direction as the pair of detection electrodes 130 that provides the optimal detection data, and moves the installation portion 120 to the subject 20 so that the sensor electrodes 12a and 12b are attached to the subject 20. The optimal detection data may correspond to the detection data having the maximum correlation coefficient by comparing the detection data with reference data or the detection data having the maximum peak among the detection data.
When the detection electrodes 130 are configured as shown in
The two detection signals selected by the detection signal selection portion 151 are transferred to the detection signal processing portion 152 and processed therein to generate detection data. The detection signal processing portion 152 generates the detection data by amplifying and digitalizing the difference between the detection signals. For this purpose, the detection signal processing portion 152 further includes a differential amplification portion 153 for amplifying the difference between the detection signals and an A/D conversion portion 154 for converting an analog signal received from the differential amplification portion 153 into a digital signal. The detection signal processing portion 152 further includes a filtering portion (not shown).
The detection data generated by the detection signal processing portion 152 is transferred to the microcontroller 155. The microcontroller 155 calculates a correlation coefficient by comparing the received detection data with the reference data provided by the reference data supply portion 156, searches for the detection electrode 130 having the maximum correlation coefficient, and generates a control signal to drive the actuator 140 based on the searched result. The control signal is transferred to the actuator 140. The actuator 140 rotates the installation portion 120 such that the sensor electrodes 12a and 12b can be arranged identical with the direction in which the detection electrodes 130 providing the detection data having the maximum correlation coefficient are arranged. Then, the actuator 140 moves the installation portion 120 toward the subject 20 so that the sensor electrodes 12a and 12b are attached to the subject 20. In the meantime, the microcontroller 155 can search for the detection data having the maximum peak among the detection data provided by the detection electrodes 130 and generate the control signal to drive the actuator based on the search result as described above. In this case, the reference data supply portion 156 can be omitted. The microcontroller 155 receives information from the position detection portion 126 for detecting whether the biosignal measurement sensor 10 is located at the installation portion 120 and generates the control signal to drive the actuator 140 and the gripper 125 as described above.
The reference data provided by the reference data supply portion 156 is obtained using a pair of reference electrodes 170a and 170b, as shown in
In
In
The apparatus for attaching a biosignal measurement sensor configured as above to a subject can attach the biosignal measurement sensor to the subject in the method shown in
A biosignal measurement sensor having a pair of sensor electrodes is arranged at an installation portion located at an entrance of an opening of a housing (210). In the installation portion, a position detection portion detects the location of the biosignal measurement sensor so that a gripper is operated to grip the biosignal measurement sensor and installed the same. After the biosignal measurement sensor is installed, the installation portion moves back from the entrance of the opening of the housing and waits therein.
Then, the detection electrode pairs arranged along the circumference to face each other, are made to contact the subject as a whole to provide detection signals from the detection electrodes to a circuit portion (220). When a pair of reference electrodes are further provided, the reference electrodes are attached at reference positions on the subject so that reference signals can be provided from the reference electrodes to the circuit portion.
The circuit portion which received the detection signals and the reference signals, is operated to process the voltage signals obtained from the detection electrode pairs and generate detection data (230).
Then, the circuit portion searches for a pair of detection electrodes that provided an optimal detection data of the detection data (240). A control signal to drive an actuator is generated based on the search result and transferred to the actuator. The searched optimal detection data corresponds to detection data having the maximum correlation coefficient or detection data having the maximum peak of the detection data, which is obtained by comparing the detection data with either reference data provided by the reference electrodes or previously stored reference data.
Next, the installation portion is rotated by the actuator that received a control signal from the circuit portion such that sensor electrodes are arranged in the same direction in which the detection electrodes that provided the optimal detection data are arranged (250).
Finally, the actuator moves the installation portion toward the subject so that the biosignal measurement sensor is attached to the subject (260). After the biosignal measurement sensor is attached to the subject, the gripper is operated to release the biosignal measurement sensor. Then, the installation portion is moved into the housing so that the biosignal measurement sensor is separated from the installation portion. Accordingly, since the overall apparatus is completely separated from the subject once the biosignal measurement sensor is attached to the subject, the biosignal measurement sensor attached to the subject can measure a biosignal.
As described above, according to the present invention, not only an expert but also a novice can accurately and easily attach the biosignal measurement sensor at any position on the subject. Thus, the user's convenience is improved and also an accurate biosignal can be obtained so that accurate diagnosis can be obtained. Furthermore, in an electrocardiogram test, since the application of the apparatus is possible even when the position of the heart varies according to patients, accurate diagnosis can be obtained.
While this invention has been particularly shown and described with reference to non-limiting embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.
Number | Date | Country | Kind |
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10-2005-0047193 | Jun 2005 | KR | national |
Number | Name | Date | Kind |
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4375219 | Schmid | Mar 1983 | A |
5046504 | Albert et al. | Sep 1991 | A |
6282439 | Ruha | Aug 2001 | B1 |
Number | Date | Country | |
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20060282007 A1 | Dec 2006 | US |