KR20090043682A - Microwave blood sugar level monitoring instrument with multi port - Google Patents

Abstract

Disclosed are a radio wave glucose measuring apparatus having multiple ports and a control method thereof.

Radio wave blood glucose measurement apparatus having a multi-port according to the present invention, generating and outputting a test signal for measuring the blood glucose level, and receiving the result signal for the test signal through at least two cables and the main body for measuring the result signal; ; Having a plurality of input and output ports connected to each of the cables, the impedance is changed when the body of the subject is measured irradiates the test signal to the body of the subject of the test signal input through any one of the input and output ports, And a sensor unit configured to transfer the result signal for the checked signal to the main body through the plurality of input / output ports.

According to the present invention, it is possible to ensure the reliability of blood glucose measurement by collecting various data from the reflected waves of microwaves irradiated to the subject in the blood glucose measurement apparatus using radio waves to calculate the blood glucose level.

Description

Radio wave blood glucose measurement apparatus having multiple ports and control method thereof {Microwave blood sugar level monitoring instrument with multi port}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio wave glucose measurement apparatus having a multi-port and a control method thereof. The present invention relates to a radio wave glucose measuring apparatus having multiple ports that can be guaranteed.

In general, a diabetic patient is shocked if the blood sugar in the blood increases above a certain level, it is very important to maintain the blood sugar level within a stable range. Therefore, the diabetic patient should visit the hospital every certain period in order to measure their blood sugar and measure the blood sugar directly, or check the blood sugar through a direct blood glucose meter.

Conventional blood glucose meter to check the blood sugar level through a chemical reaction by taking the blood of the patient. By the way, the conventional method is not only cumbersome, but also has to collect blood every time the blood sugar is measured, there is a problem that if the wrong way is contaminated with germs causing side effects.

Therefore, recently, a technology for detecting blood glucose levels through a sensor attached to a human body without blood collection has been developed. This technique uses changes in the electrical characteristics of the human body according to blood glucose changes, and transmits radio waves to the human body of the patient and detects the reflected waves reflected by the sensor, and calculates the dielectric constant or conductivity of the blood using the reflection coefficient which is the ratio of the reflected waves. To detect blood sugar levels.

Such a conventional blood glucose measurement apparatus has a sensor unit for contacting a blood glucose measurement site of a subject to irradiate microwaves and to receive reflected microwaves. Most of these sensor units have one port, and provide the reflected wave for the irradiated microwave to the processor through the corresponding port. Accordingly, the processor calculates the reflection coefficient of the reflected wave to measure the change in blood glucose, and the only data that can be obtained are the information of the reflection coefficient magnitude and phase.

As such, data obtained through a sensor in a conventional blood glucose measurement apparatus using radio waves is limited to reflection coefficients and phase information, and thus, accuracy or reproducibility of measurement is low, and measurement errors are high. have.

Therefore, the problem to be solved by the present invention, by collecting a variety of data from the reflected wave of the microwave irradiated to the subject in the blood glucose measurement apparatus using radio waves to calculate the blood glucose level, having a multi-port that can ensure the reliability of blood glucose measurement An apparatus for measuring radio wave glucose and a control method thereof are provided.

In order to solve the above problems, the present invention includes a main body for generating and outputting a test signal for measuring blood glucose levels, and receiving a result signal for the test signal through at least two cables; Having a plurality of input and output ports connected to each of the cables, the impedance is changed when the body of the subject is measured irradiates the test signal to the body of the subject of the test signal input through any one of the input and output ports, It provides a radio wave glucose measuring apparatus having a multi-port characterized in that it comprises a sensor unit for transmitting the result signal for the test signal to the main body through the plurality of input and output ports.

Here, the main body measures the voltage level of the result signal input through each cable, and calculates a result value for measuring blood glucose level of the subject based on the voltage level of the output test signal and the measured result signal. It is possible to calculate.

The resultant for measuring blood glucose level of the subject may include a reflection coefficient and a transfer coefficient.

In addition, the cable, it is possible to include a coaxial cable for transmitting the test signal and the result signal in the TEM mode (Transverse Electromagnetic Mode).

On the other hand, the sensor unit, a plate-like dielectric; A metal shielding portion configured to shield an outer surface of the dielectric and expose an upper portion of the dielectric to expose a predetermined region; The body of the subject is mounted in contact with the dielectric region of the exposed part, and the electrical characteristics of the body of the subject change according to the contact, and the test signal is input to the body of the subject through the input / output port. It is possible to include a diagnostic contact for transmitting the result signal according to the plurality of input and output ports.

The diagnostic contact unit may include: a coplanar waveguide (CPW) line in which the body of the subject is in contact with the test signal; It is possible to include a metal pattern for resonance of the CPW line.

The metal pattern may be mounted in an nλ-sized ring pattern in an adjacent region of the CPW line.

In addition, the metal pattern may be mounted on the CPW line in the form of a spiral pattern of nλ / 4 size.

On the other hand, according to another field of the present invention, the blood glucose measurement apparatus for measuring the blood glucose level of the subject on the basis of the impedance of the sensor to be changed when the body of the subject changes, wherein the blood in contact with the sensor unit Irradiating a test signal for measuring the blood glucose level to a body of a measurer; Measuring at least two result signals for the test signals; The method may also be solved by a control method of an apparatus for measuring a blood glucose level having multiple ports, comprising calculating a result value for measuring a blood glucose level of the subject based on the measured at least two result signals.

The measuring of at least two result signals with respect to the inspection signal may include: measuring a reflection coefficient of the sensor unit in the inspection signal; It is possible to include the step of measuring the transmission coefficient of the sensor unit in the inspection signal.

According to the multi-port propagation glucose measuring apparatus and control method thereof, the blood glucose measurement apparatus using radio waves collects various data from the reflected waves of microwaves irradiated to the subject to calculate blood glucose levels, thereby ensuring reliability of blood glucose measurement. can do.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

However, embodiments of the present invention illustrated below may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. Embodiments of the invention are provided to more fully illustrate the invention to those skilled in the art.

1 is a state diagram used in the radio wave glucose measuring apparatus having a multi-port according to the present invention. Radio wave glucose measuring apparatus according to the present invention is configured in a similar form to a network analyzer, it is configured to measure the blood glucose level of the subject by a non-blood collection method using a test signal, for example, microwaves.

Thus, as shown in Figure 1, a multi-port propagation blood glucose measurement apparatus according to the present invention, having two or more cables (16, 18) for signal input and output, generates a test signal to the cable (16, 18) Connected to each cable 16, 18 of the main body 10 through the main body 10 for analyzing the signal input to each cable (16, 18) while outputting through a plurality of input and output ports 106, 108 The sensor unit 100 irradiates the test signal to the body of the subject and transmits the reflected signal and the transfer signal, which are result signals of the irradiated test signal, to the main body 10 through the plurality of input / output ports 106 and 108. It includes. Here, FIG. 1 illustrates a case in which the sensor unit 100 includes two input / output ports 106 and 108. The first cable 16 and the second cable 18 provided in the main body 10 may include a sensor. It is connected to each input / output port 106, 108 of the unit 100.

The main body 10 includes an input unit 12 for user operation such as start / end of a blood glucose measurement function, microwave output setting, and a display unit 14 on which data such as a measurement function execution state and a measurement result are displayed. The main body 10 outputs the test signal generated for measuring blood glucose levels of the subject to the sensor unit 100 through the first cable 16, and according to the output test signal, the first cable 16 and the first test signal. Receives the resultant signal input to the two cables 18. Here, the test signal applied to the sensor unit 100 is reflected according to the impedance of the sensor unit 100 and input again through the first cable 16, and the test signal passing through the sensor unit 100 is the second cable. It may be input to the main body 10 through 18. Thus, the body 10 may measure the blood glucose level of the subject by calculating a reflection coefficient and a transmission coefficient based on the magnitudes of the resultant signals input through the first cable 16 and the second cable 18. For example, the main body 10 may measure the reflection coefficient and the transfer coefficient through the magnitudes of the voltage values of the output test signal and the received result signal. It is possible to measure the blood glucose level of the subject using the electrical property change value.

The first cable 16 and the second cable 18 are configured as coaxial cables for transmitting signals input and output between the main body 10 and the sensor unit 100 in a TEM mode (Transverse Electromagnetic Mode).

The sensor unit 100 has input / output ports 106 and 108 for connection with the first cable 16 and the second cable 18, and a part of the body of the subject, for example, a fingertip node of the subject The resultant signal for measuring the reflection coefficient and the transmission coefficient of the test signal irradiated on the body of the person to be measured is output to the main body 10 through the first cable 16 and the second cable 18, respectively. When the human body of the sensor 100 is in contact with the sensor 100, the impedance of the sensor 100 is changed. Here, the blood of the human body changes its electrical properties, such as permittivity and conductivity, according to blood sugar levels, so that the sensor 100 ) Has different impedances depending on the blood glucose level of the subject. Accordingly, the sensor unit 100 examines the test signal on the body of the subject, and simultaneously provides the result signal for measuring the reflection coefficient and the transmission coefficient to the main body 10 through the two input / output ports 106 and 108. do.

As such, in the present invention, when the blood glucose measurement apparatus for measuring blood glucose level of a subject is measured by a non-blood sampling method, a result signal for measuring a reflection coefficient and a transmission coefficient through a plurality of input / output ports 106 and 108 is measured. Simultaneously input the blood sugar level of the subject to be calculated. Thus, blood glucose levels may be measured based on the increased data using various data than conventional methods using a single data, thereby improving the reliability of the measured values. In addition, as in the prior art, when using only the reflection signal, the phase and magnitude of the reflection coefficient should be measured, and a more complicated measurement circuit is required to measure the phase of the radio wave. However, the present invention also has the advantage that it is possible to measure the blood glucose using the reflection signal and the transmission signal only by the size of each reflection coefficient and the transfer coefficient, it can be implemented through a simpler measurement circuit.

2A is a perspective view of a sensor unit having a plurality of input / output ports 106 and 108 of FIG. 1, and FIG. 2B is a plan view of an upper surface of the sensor unit 100 having a plurality of input / output ports 106 and 108 of FIG. 1. . As shown in Figure 2a and 2b, the sensor unit 100 of the present invention is configured in a planar form that is easy to contact the human body. When the sensor unit 100 comes into contact with the human body, the system impedance value representing the characteristics of the transmission line is changed according to the glucose concentration in the blood, thereby changing the reflection coefficient and the transfer coefficient value. In this case, since the measurement error does not occur only when the electrical property is changed only in a part in direct contact with the human body, other parts besides the human body part should be cut off from the outside through the metal.

Thus, as shown in FIG. 2A, the sensor unit 100 shields the plate-like dielectric 104 and the outer surface of the dielectric 104 and exposes the exposed portion 110 to expose a predetermined region on the upper surface. The formed metal shield 102 and the diagnostic contact portion 200 mounted on the dielectric 104 of the exposed portion 110 are in contact with the body of the subject.

The dielectric 104 is made of an insulating material such as a low loss ceramic in which electricity does not flow and charges are induced on a surface thereof, and may be provided in a planar shape to facilitate human contact.

The metal shield 102 shields an outer surface of the dielectric 104 and an exposed portion 110 is formed in a predetermined area of the upper surface to expose the diagnostic contact portion 200. Accordingly, the user who wants to check the blood sugar contacts the body part with the diagnostic contact part 200 of the exposed part 110. In addition, both side surfaces of the metal shield 102 are provided with a first input / output port 106 and a second input / output port 108 connected to the coaxial cables 16 and 18 of the main body 10.

The diagnostic contact 200 is mounted in a coplanar waveguide (CPW) line shape in a region of the dielectric 104 that is not shielded by the metal shield 102, as shown in FIG. 2B. CPW line is a kind of transmission line used in the mode indicated by the electromagnetic wave transmitted through free space or two-wire coaxial line, and has excellent transmission characteristics and stabilizes the effective dielectric constant. Via holes 202a and 202b are formed at both ends of the diagnostic contact portion 200 to connect the first input / output line 204a and the second input / output line 204b that are wired inside the dielectric 104. Here, the first I / O line 204a and the second I / O line 204b are connected to the first I / O port 106 and the second I / O port 108 of the metal shield 102, and thus the first I / O port 106. ) Is supplied to the diagnostic contact unit 200 through the first input / output line 204a, and the resultant signal is first input / output through the first input / output line 204a and the second input / output line 204b. It is output to the port 106 and the second input / output port 108. The test propagation supplied through the first I / O line 204a is reflected by the impedance change of the diagnostic contact unit 200, and a part of the test propagation is reflected through the first I / O line 204a and the radio wave transmitted through the diagnostic contact unit 200 is It is output to the second input / output port 108 through the second input / output line 204b. The impedance of the diagnostic contact unit 200 is changed differently according to the blood sugar level of the test subject in contact with the diagnostic contact unit 200, and the reflection coefficient and the transfer coefficient have different values according to the blood sugar level of the user. Accordingly, the reflection coefficient may be measured through the signal output to the first input / output port 106 of the sensor unit 100, and the transmission coefficient may be measured through the signal output to the second input / output port 108.

On the other hand, the shape of the diagnostic contact mounted on the sensor unit 100 may be modified in various forms to improve the sensitivity. 3 to 5 are plan views of the upper surface of the sensor unit 100 according to the embodiment of the present invention.

FIG. 3 illustrates a case where the diagnostic contact part 300 is formed of a ring pattern 310 in the vicinity of the CPW line and the CPW line. Via holes 302a and 302b are formed at both ends of the CPW line to connect the first input / output line 204a and the second input / output line 204b that are wired inside the dielectric 104. Here, the first I / O line 204a and the second I / O line 204b are connected to the first I / O port 106 and the second I / O port 108 of the metal shield 102, and thus the first I / O port 106. ) Is supplied to the diagnostic contact unit 300 through the first input / output line 204a, and the resultant signal is first input / output through the first input / output line 204a and the second input / output line 204b. It is output to the port 106 and the second input / output port 108.

The ring pattern 310 is designed to have a size of nλ so that the resonance frequency can be oscillated when the subject is in contact with the body. Accordingly, the change in the reflection coefficient and the transfer coefficient according to the contact of the subject in the hyperglycemic state may be amplified to improve reliability of the test result.

4 illustrates a case in which the diagnostic contact 400 is configured in the form of adding a circular pattern 410 on the CPW line. Via holes 402a and 402b are formed at both ends of the CPW line to connect the first input / output line 204a and the second input / output line 204b that are wired inside the dielectric 104. Here, the first I / O line 204a and the second I / O line 204b are connected to the first I / O port 106 and the second I / O port 108 of the metal shield 102, and thus the first I / O port 106. ) Is supplied to the diagnostic contact unit 400 through the first input / output line 204a, and the resultant signal is first input / output through the first input / output line 204a and the second input / output line 204b. It is output to the port 106 and the second input / output port 108.

The circular pattern 410 is designed to have a size of nλ / 2 so that the resonant frequency may be oscillated when the body of the subject contacts the body. In this case, when the diameter of the circle is nλ / 2, resonance occurs and changes in the reflection coefficient and the transfer coefficient due to the contact of the subject in the hyperglycemic state are amplified, thereby improving reliability of the test result.

FIG. 5 illustrates a case in which the diagnostic contact portion 500 is configured to add a spiral pattern 510 to a CPW line. Via holes 502a and 502b are formed at both ends of the CPW line to connect the first input / output line 204a and the second input / output line 204b that are wired inside the dielectric 104. Here, the first I / O line 204a and the second I / O line 204b are connected to the first I / O port 106 and the second I / O port 108 of the metal shield 102, and thus the first I / O port 106. ) Is supplied to the diagnostic contact unit 500 through the first input / output line 204a, and the resultant signal is transmitted through the first input / output line 204a and the second input / output line 204b. It is output to the input / output port 106 and the second input / output port 108.

The spiral pattern 510 is designed to have a size of nλ / 4 so that the resonant frequency may be oscillated when the subject contacts the body. Here, resonance occurs when the length of the overlapping lines of the spiral pattern 510, that is, the length of one line is nλ / 4 size. That is, the change in the reflection coefficient and the transfer coefficient according to the contact of the subject in the hyperglycemic state may be amplified to improve the reliability of the test result.

As illustrated above, the diagnostic contacts 200, 300, 400, and 500 of the sensor unit 100 may be implemented in various forms according to their size and design environment. In the case of adding a λ / 2 size pattern to the diagnostic contacts 200, 300, 400, and 500, resonance occurs on the touch of the subject, thereby increasing the reflection coefficient and the transfer coefficient according to the blood glucose level. The reliability of the measurement results can be improved. In addition, it is possible to increase the reliability of the reflection coefficient and the transmission coefficient measurement value by adjusting the design values of the input / output ports 106 and 108 provided in the sensor unit 100.

FIG. 6 is a graph illustrating output simulation results of a multi-port propagation glucose measuring apparatus according to the present invention, in which a saline solution having a glucose concentration of 0% and a 20% concentration are present in a sensor unit 100 having a structure shown in FIGS. 2A and 2B. If the glucose solution is reacted, the output is simulated.

As shown in FIG. 6, the first input / output port 106 and the second input / output port 108 of the sensor unit 100 are respectively connected to the first cable 16 and the second cable 18 of the main body 10. The test radio wave is connected to the sensor unit 100 through the first input / output port 106. When the body of the subject is in contact with the sensor unit 100, the impedance of the sensor unit 100 changes according to the blood glucose level of the subject, so that some of the test radio waves supplied to the sensor unit 100 may be connected to the first input / output port ( It is reflected toward the 106 and part of which is energized by the sensor unit 100 is output to the second input and output port 108. Accordingly, the reflection coefficient S11 may be measured by detecting the radio wave reflected by the first input / output port 106, and the transmission coefficient S21 may be measured through the radio wave output to the second input / output port 108. .

The impedance change indicated by the dotted line in the Smith chart of the reflection coefficient (S11) and the transmission coefficient (S21) is when the saline solution with a glucose concentration of 0% is contacted, and the impedance change indicated by the solid line indicates that the glucose concentration is 20%. The case where the saline is in contact is shown.

As described above, since the present invention obtains two data of the reflection coefficient and the transmission coefficient through the sensor unit 100, the reliability of the present invention can be improved compared to the conventional reflection coefficient measuring method in which only one data is obtained. It is also possible to increase the measurement sensitivity through a mathematical combination of reflection and transmission coefficients.

FIG. 7 is a Smith chart showing the impedance of the sensor unit according to the simulation result of FIG. 6, and illustrates the case where the impedance of the sensor unit 100 is calculated using the vector sum of the reflection coefficient and the transfer coefficient. As shown in FIG. 7, it can be seen that the simulation result shows more change when the vector sum is used as compared to the case of measuring only the reflection coefficient S11 for the same glucose concentration change as shown in FIG. 6.

Also, in addition to simple vector sums, parameters for characteristic evaluation with various equations can be created.

(S11:반사계수, S21:전달계수)의 수식을 적용한 혈액 특성 평가 파라미터를 예시한 것으로서, 글루코스 농도 변화에 따른 평가 파라미터의 변화가 확연하게 표시됨을 알 수 있다.8 is a parameter graph for evaluating characteristics of the sensor unit 100 according to the simulation result of FIG. 6. 8 is a graph

As an example of the blood characteristic evaluation parameter to which the formula of (S11: reflection coefficient, S21: transmission coefficient) is applied, it can be seen that the change of the evaluation parameter according to the glucose concentration is clearly displayed.

은 글루코스 농도 변화에 따른 반사계수 및 전달계수를 연산하여 그 측정치의 변화를 확연하게 표시하기 위해 적용된 수식으로서, 예시된 수식 이외에 다양한 수식들 중 각 센서 구조에 따라 가장 큰 변화를 갖는 파라미터 값을 이용해 측정의 감도를 향상시키는 것도 가능하다. The formula used here,

Is a formula applied to calculate the reflection coefficient and the transfer coefficient according to the glucose concentration clearly and clearly display the change of the measured value.In addition to the illustrated formula, the parameter value having the largest change according to each sensor structure among various formulas is used. It is also possible to improve the sensitivity of the measurement.

As described above, the present invention includes two or more input / output terminals in the sensor unit, and collects various data capable of measuring the characteristic change of the sensor unit according to the body contact of the subject, and based on this, By measuring the blood sugar level, the reliability of the measured value of the radio wave glucose measuring apparatus is increased.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, the technical configuration of the present invention described above may be modified in other specific forms by those skilled in the art to which the present invention pertains without changing its technical spirit or essential features. It will be appreciated that it may be practiced. Therefore, the embodiments described above are to be understood as illustrative and not restrictive in all aspects. In addition, the scope of the present invention is represented by the claims to be described later rather than the detailed description. Also, it is to be construed that all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts are included in the scope of the present invention.

1 is a state diagram used in the radio wave glucose measuring apparatus having a multi-port according to the present invention.

2A is a perspective view of the sensor unit of FIG. 1.

2B is a plan view of an upper surface of the sensor unit of FIG. 1.

3 is a plan view of the upper surface of the sensor unit according to the first embodiment of the present invention.

4 is a plan view of an upper surface of a sensor unit according to a second embodiment of the present invention.

5 is a plan view of an upper surface of a sensor unit according to a third embodiment of the present invention.

Figure 6 is a graph of the output simulation result of the radio wave glucose measuring apparatus having a multi-port according to the present invention.

FIG. 7 is a Smith chart showing an impedance of a sensor unit according to the simulation result of FIG. 6.

8 is a parameter graph for evaluating characteristics of a sensor unit according to the simulation result of FIG. 6.

*** Explanation of symbols for the main parts of the drawing ***

10: main body 12: input unit

14 display unit 16 first cable

18: second cable 100: sensor

102: metal shield 104: dielectric

106: first input and output port 108: second input and output port

110: exposed part

200, 300, 400, 500: diagnostic contacts

202a, 302a, 402a, 502a: first via hole

202b, 302b, 402b, 502b: second via hole

204a: first I / O line 204b: second I / O line

310, 410, 510: pattern

Claims (10)

A main body generating and outputting a test signal for measuring blood glucose levels, and receiving a result signal for the test signal through at least two cables; Having a plurality of input and output ports connected to each of the cables, the impedance is changed when the body of the subject is measured irradiates the test signal to the body of the subject of the test signal input through any one of the input and output ports, And a sensor unit for transmitting the result signal for the test signal to the main body through the plurality of input / output ports. The method of claim 1, The main body, Measuring a voltage level of the resultant signal input through each cable, and calculating a result value for measuring blood glucose level of the subject based on the voltage level of the output test signal and the measured resultant signal; Radio wave glucose measurement apparatus having multiple ports. The method of claim 2, The result value for measuring the blood glucose level of the subject, Propagation blood glucose measurement apparatus having a multi-port characterized in that it comprises a reflection coefficient and a transmission coefficient. The method of claim 1, The cable, Propagation blood glucose measurement apparatus having a multi-port characterized in that it comprises a coaxial cable for transmitting the test signal and the result signal in a TEM mode (Transverse Electromagnetic Mode). The method of claim 1, The sensor unit, A plate-like dielectric; A metal shielding portion configured to shield an outer surface of the dielectric and expose an upper portion of the dielectric to expose a predetermined region; The body of the subject is mounted in contact with the dielectric region of the exposed part, and the electrical characteristics change according to the body contact of the subject, and the test signal is input through the input / output port to allow the subject to contact the subject. And a diagnostic contact unit for transmitting the resultant signal to the plurality of input / output ports. The method of claim 5, wherein The diagnostic contact portion, A coplanar waveguide (CPW) line in which the body of the subject is in contact with the test signal; Propagation blood glucose measurement apparatus having a multi-port characterized in that it comprises a metal pattern for the resonance of the CPW line. The method of claim 6, The metal pattern is, An apparatus for measuring radio wave glucose with multiple ports, wherein the CPW line is mounted in an nλ-sized ring pattern in an adjacent region of the CPW line. The method of claim 6, The metal pattern is, An apparatus for measuring radio wave glucose with multiple ports, mounted on the CPW line in the form of a spiral pattern having a size of nλ / 4. In the radio wave blood glucose measurement apparatus for measuring the blood sugar level of the subject on the basis of the impedance of the sensor unit that changes when the body of the subject changes, Irradiating a test signal for measuring the blood glucose level to the body of the subject in contact with the sensor unit; Measuring at least two result signals for the test signals; And calculating a result value for measuring a blood glucose level of the subject based on the measured at least two result signals. The method of claim 9, Measuring at least two result signals for the test signal, Measuring a reflection coefficient of the sensor unit in the inspection signal; And controlling the transmission coefficient of the sensor unit in the test signal.

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