KR101091725B1 - Diagnosis system and method for human adjustability - Google Patents

Abstract

The present invention relates to a system and method for diagnosing the balance function of a human body, the disturbance driving unit applying a disturbance of a predetermined size to a diagnosis subject in an upright position, and detecting an angle change of a joint portion of a human body to maintain balance in response to the disturbance. And a detection unit for obtaining a change in angle data, and a balance function calculation unit for calculating a balance function of a diagnosis subject based on the magnitude of the disturbance and the angle data detected by the detection unit.

Thereby, a human body balance function diagnosis system and diagnostic method that can objectively and accurately quantify the human body balance function are provided.

Human body, balance, maintenance, disturbance, balance function

Description

Diagnosis system and method for human adjustability

The present invention relates to a human body balance diagnosis system and diagnostic method.

In general, the balance function of the human body may cause abnormalities such as cognitive function, reaction rate, signal integration function of the central nervous system, or may be degraded by aging. When an abnormality of the balance function occurs, it becomes difficult to stand and walk in a balanced state, which is a very fatal obstacle in daily life such as frequent fall.

In particular, this impairment of balance function has emerged as a social problem due to the frequent fall of the elderly in the modern society where aging is accelerating, and as a result, it becomes a fatal factor that impairs healthy old life.

Accordingly, as a recent study for diagnosing the balance function of the human body, a study on a method for diagnosing the balance and gait of the human body through an analysis of the center of pressure, electromyography or movement characteristics of the human body Has progressed.

In addition, as a result of such research, Biodex Co., Ltd. developed a balance function trainer for diagnosing and correcting the balance function of the human body using the pressure center value of the force plate, and Immersive virtual environments. As a visual stimulus system using), a device for diagnosing the balance function has been developed by applying a visual stimulus to the human body and interpreting the change in posture as a pressure-based movement amount.

However, among the conventional methods of diagnosing the balance function of the human body and the balance function diagnosis device using the same, the analysis of the pressure center of the human body or the use of electromyography is performed using the multivariate physical quantity, and the upper and lower body interactions of the human body made of multiple joints There was a problem that can not be interpreted comprehensively.

In addition, the method of using a simple output response of muscle activity, such as EMG, has a problem in that it has a limitation in analyzing the command system of the central nervous system and the musculoskeletal system and the balance maintenance function of the human body against disturbance.

That is, conventional methods and devices for diagnosing the balance function of the human body have a problem in that an accurate and objective diagnosis of the balance function of the human body is impossible because the balance function of the human body cannot be objectively quantified.

Accordingly, it is an object of the present invention to provide a human body balance function diagnosis system and diagnostic method capable of objectively and accurately quantifying the balance function of a human body.

According to the present invention, in the human body balance function diagnosis system, the disturbance driving unit for applying a disturbance of a predetermined size to the diagnosis subject of the upright position, and detects the change in the angle of the human joint part for maintaining balance in response to the disturbance And a detection unit for obtaining a change in angle data, and a balance function calculation unit for calculating a balance function of a diagnosis subject based on the magnitude of the disturbance and the angle data detected by the detection unit. Achieved by the system.

Here, the disturbance driving unit has a platform in which the diagnosis subject stands in an upright position, a platform driver for flowing the platform in a disturbance of a predetermined size, and a ground reaction device for measuring the driving torque of the platform and transmitting it to the balance function calculation unit. It is preferable.

The detection unit captures a marker attached to the knee joint and the hip joint of the diagnosis subject, and the flow of the marker according to the movement of the diagnosis subject corresponding to the disturbance of the platform to obtain the angle and the angular velocity of each joint. And, it is effective to have a motion capturer for transmitting the angle and angular velocity to the balance function calculation unit.

Alternatively, the sensing unit may be an angle measuring device for measuring the joint angle of the knee and hip joint worn on the body of the diagnosis target.

In addition, it is more preferable that the balance function calculation unit quantitatively calculates a rate of change of a gain value for maintaining balance of the human body corresponding to disturbance based on the driving torque and the angle data.

On the other hand, according to another field of the present invention, in the method for diagnosing the balance function of the human body, applying a disturbance of a predetermined size to the diagnosis subject of the upright position, and capturing the flow of the ankle and hip joint of the diagnosis subject And obtaining a gain value of the diagnosis subject based on the magnitude of the disturbance and the flow of the diagnosis subject.

Here, the step of applying the disturbance to the diagnosis subject is preferably a step of measuring the driving torque generated in the process of applying a disturbance of a predetermined size to the diagnosis subject in the upright position.

In addition, the step of capturing the flow of the ankle and hip joint of the diagnosis subject is effective to obtain the angle data by measuring the angle and the angular velocity of each joint.

In addition, the step of obtaining the gain value of the diagnosis subject based on the drive torque generated in the process of applying a disturbance of a predetermined size to the diagnosis subject and the angle and the angular velocity data of the ankle and hip joint according to the flow of the diagnosis subject More preferably, the step of quantitatively calculating a change in gain value for maintaining balance of the human body corresponding to disturbance.

Thereby, a human body balance function diagnosis system and diagnostic method that can objectively and accurately quantify the human body balance function are provided.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

1 is a simplified configuration diagram of a human body balance diagnosis system according to the present invention. As shown in this figure, the human body balance function diagnosis system 1 according to the present invention is balanced in response to disturbances transmitted from the disturbance drive unit 10 and the disturbance drive unit 10 to disturb the diagnosis subject in an upright posture. It is an operation for maintaining the detection unit 20 for detecting the change in the angle of the joint portion of the human body to obtain the data, based on the magnitude of the disturbance applied by the disturbance driving unit 10 and the angle data detected by the detection unit 20 And a balance function calculation unit 30 for quantitatively calculating the balance function of the diagnosis subject.

The disturbance driving unit 10 includes a platform 11 on which a diagnosis subject stands in an upright position, a platform driver 13 for flowing the platform 11 into a disturbance of a predetermined size, and a ground reaction force for measuring driving torque of the platform 11. It can be composed of a group (15).

The platform 11 preferably has an area such that the diagnosis subject can stand comfortably in an upright position. The diagnosis subject standing on the platform 11 should stand in an upright position with his arms folded so as not to maintain the balance using the arm, and be careful not to maintain the balance by lifting the heel, thereby restoring the sole to the platform 11. Keep a close position. In this platform 11, markers 21 for motion capture are attached to the ankle and hip joints of the diagnosis subject.

The platform driver 13 flows in at least the front-rear direction, preferably front-rear, left-right, and arbitrary directions of the platform 11. The platform driver 13 may provide an appropriate drive structure such as a sliding drive structure using power under the platform 11 to drive the platform 11 in a predetermined disturbance. At this time, the disturbance condition of the platform 11 is, for example, to add a disturbance size of 7 kinds of displacement 3, 4, 5, 6, 7.5, 9, 10.5, 12, 15 cm in the range of 3 to 15 cm to 275 ms. It is preferable. Here, of course, the size and displacement of the disturbance may vary.

In addition, the ground reaction machine 15 measures the driving torque generated during the driving process of the platform 11 and transmits it to the balance function calculation unit 30.

The detection unit 20 is a marker 21 attached to the body of the diagnosis subject standing upright on the platform 11 and a motion capturer 23 for capturing the movement of the diagnosis subject corresponding to the disturbance of the platform 11. It can be prepared as). Here, the marker 21 is attached to the ankle joint and hip joint site of the diagnosis target, the motion capture is attached to the ankle joint and hip joint site when the movement of the diagnosis target to balance the disturbance of the platform 11 The movement of the marker 21 is captured to obtain angle data of each joint. The angle data of each joint thus obtained is transmitted to the balance function calculation unit 30.

In this case, the detection unit 20 may use various devices capable of acquiring the angle data of the diagnosis target, such as a joint angle measurer, which is worn on the body of the diagnosis target, in addition to the marker 21 and the motion capture unit 23. It may be.

On the other hand, the balance function calculation unit 30 is the angle and the angular velocity of the ankle joint and hip joint of the diagnostic subject acquired and transmitted from the drive torque measured by the ground reaction machine 15 of the disturbance drive unit 10 and the detection unit 20 Based on the angle data of the back, the rate of change of the gain value for maintaining the balance of the human body corresponding to the disturbance is calculated quantitatively.

Here, the basis for measuring the balance ability of the human body by the rate of change of the gain value for maintaining the balance of the human body calculated by the balance function calculation unit 30 will be described.

Approaching the posture response of the human body from the feedback point of view of the mechanical system, the mechanism of generating torque in each joint can be explained through the concept of full-state feedback.

A gain matrix is needed for torque feedback to maintain balance in response to disturbances. In this case, as the magnitude of the disturbances changes, a specific gain value increases or decreases linearly with a constant rate of change.

As the disturbance increases, the ankle gain (T _ankle / θ _ankle ) of the _ankle joint decreases, and the hip gain (T _hip / θ _hip ) of the hip joint increases. It is to measure the function.

Gain change means a change in posture response strategy. When the disturbance is small, it responds to the primary mode around the ankle joint.When the disturbance increases, the secondary mode using the hip joint ( Balance around the hip mode. This can be quantified using the rate of change of gain and is used to measure the balance function.

On the other hand, the method of obtaining the gain value, using the linear regression method as the initial value setting, to obtain the full-state feedback gain value using the torque and motion data.

After implementing the state-space equation of the human body model, the simulation process using the gain value is implemented in the feedback loop.

The optimization is then used to generate a simulation that fits the experimental values (torque, motion) well, and then extracts the gain values used. The initial value of the optimization is the gain value obtained by the linear regression. At this time, the optimization is effective to use the Matlab fmincon function.

On the other hand, as shown in Figures 3 and 4, since the change in the response strategy according to the size of the disturbance in the case of a normal person well, the gain slope (gain slope) is also greater than the rate of change of the balance function abnormal people. In other words, it is possible to measure the balance ability of the human body through the rate of change of the gain value according to the increase of disturbance, that is, the slope.

As described above, the disturbance of the X-axis is normalized by dividing 3-15 cm (7 types) by the height or the maximum COP of the test subject. The gain value on the Y axis is normalized by dividing the height and weight of the subject.

Gain scaling refers to the slope of the linear fit that best fits the seven data points in the graph of FIG. 3 (minimizes the root mean square), and can be used as a kind of balance index indicating the balance ability of the human body. .

Hereinafter, a method of diagnosing the balance function of the human body will be described by calculating a rate of change of a gain value according to an increase in disturbance using the balance diagnosis system 1 according to the present invention.

As shown in FIG. 2, the method for diagnosing the balance function of the human body includes applying a disturbance to the diagnosis subject (S01), capturing the flow of the ankle and hip joints of the diagnosis subject (S02), and size of the disturbance. And obtaining a gain value of the diagnosis subject based on the flow of the diagnosis subject (S03).

The step of applying disturbance to the diagnosis subject (S01) is a platform on the platform 11 of the disturbance driving unit 10 in an upright position, and the marker 21 is attached to the knee joint and hip joint of the diagnosis target platform. The actuator 13 is driven to flow to the platform 11 in a disturbance of a predetermined size, and the driving torque generated in the driving process of the platform 11 is measured by the ground reaction machine 15 to the balance function calculation unit 30. It is a delivery process.

And, in step S02 of capturing the flow of the ankle and hip joint of the diagnosis subject motion capture the movement of the marker 21 attached to the knee joint and hip joint of the diagnosis subject during the disturbance is applied to the diagnosis subject It consists of a process of transferring the angle data of each joint obtained by capturing (23) to the balance function calculation unit (30).

On the other hand, obtaining the gain value of the diagnosis subject based on the size of the disturbance and the flow of the diagnosis subject (S03) is the drive torque measured by the ground reaction machine 15 and the transfer of the diagnosis subject acquired by the detection unit 20 Comprising a step of quantitatively calculating the rate of change of the gain value for maintaining the balance of the human body corresponding to the disturbance based on the angle data, such as the angle and angular velocity of the ankle and hip joint.

3 and 4, as the disturbance increases, ankle gain (T _ankle / θ _ankle ) of the _ankle joint decreases, and hip gain (T _hip / θ _hip ) of the hip joint is reduced. This increases, but by comparing the gain change rate obtained by using the abnormal person as a diagnosis target in a state where data on the rate of change of gain has been accumulated in advance as a normal person, it is possible to quantitatively measure the balance ability of the diagnosis subject.

At this time, the data on the change rate of gain is classified according to the physical condition of the diagnosis subject, and the gain change rate data of the normal person for each physical condition is accumulated in advance, and the data of the normal person and the abnormal person corresponding to the physical condition of the abnormal person are compared. . Thereby, the abnormal degree of the human body balance maintenance function of an abnormal person can be confirmed by the ordered numerical value.

 Figure 4 is a graph comparing the function of maintaining the balance of the human body of the normal and abnormal in a specific physical condition obtained by this method. As you can see in this graph,

The normal slope of a certain physical condition changes the response strategy according to the magnitude of disturbance, so the gain slope is also greater than the change rate of the person with abnormal balance function. Therefore, it is possible to quantitatively measure the balance of the human body's ability to maintain the balance, ie, the balance index, through the rate of change of the gain value of the normal and abnormal persons, that is, the slope.

In addition to the gain scaling described above, the maximum ankle torque or hip torque may be used as the balance index.

Typically, the maximum torque occurs in the disturbance of the largest magnitude, so the maximum ankle torque or hip torque can be used as a balance index.

In other words, as shown in FIG. 5, the maximum ankle torque or the maximum hip torque value is lowered in the order of the young group, the senior group, and the patient group, so that the balance function of the diagnosis subject can be evaluated by making a database.

Meanwhile, the maximum allowable ankle torque or hip torque may be measured by the method described above.

Thus, according to the human body balance function diagnosis system and diagnostic method according to the present invention, it is possible to objectively and accurately quantify the balance function of the human body.

1 is a simplified configuration diagram of a human body balance diagnosis system according to the present invention,

2 is a flow chart for diagnosing a human balance function according to the present invention;

3 and 4 are graphs of the human body balance maintenance ability calculation of normal and abnormal persons calculated by the human body balance function diagnosis system and diagnostic method according to the present invention.

* Explanation of symbols for the main parts of the drawings

10: disturbance drive unit 11: platform

13: platform driver 15: ground reaction machine

20: detector 21: marker

23: motion capture 30: balance function calculation unit

Claims (10)

In the human body balance diagnosis system, Disturbance driving unit for applying a disturbance of a predetermined size to the person diagnosed in the upright position, A detection unit for detecting an angle change of a joint portion of a human body to maintain balance in response to the disturbance, and obtaining changed angle data; It includes a balance function calculation unit for calculating the balance function of the diagnosis subject based on the magnitude of the disturbance and the angle data detected by the detection unit, The disturbance driving unit The platform on which the diagnosis subject stands in an upright position, A platform driver for flowing the platform into a disturbance of a predetermined size; It is provided with a ground reaction device for measuring the driving torque of the platform and transmits to the balance function calculation unit, The balance function calculation unit Diagnosing the balance function of the human body, characterized in that to calculate the rate of change of the gain value of the ankle joint and the gain value of the hip joint quantitatively defined as follows to maintain the balance of the human body corresponding to the disturbance based on the drive torque and the angle data system. Gain value of ankle joint = T _ankle / θ _ankle Gain value of hip joint = T _hip / θ _ankle T _ankle only _: torque acting on the ankle joint θ _ankle: ankle joint angle T _hip : Torque applied to hip joint θ _ankle : Hip joint angle delete The method of claim 1, The sensing unit Markers attached to the knee and hip joint of the diagnosis subject, Capturing the flow of the marker according to the movement of the diagnosis subject corresponding to the disturbance of the platform to obtain the angle and angular velocity of each joint, and has a motion capturer for transmitting the angle and angular velocity to the balance function calculation unit Human body balance diagnosis system. The method of claim 1, The detection unit is a body balance function diagnostic system, characterized in that the joint angle measuring device for measuring the joint angle of the knee joint and hip joint worn on the body of the diagnosis subject. delete In the method of diagnosing human balance function, Applying a disturbance of a predetermined size to a diagnosis subject in an upright position, Capturing the flow of the ankle and hip joints of the diagnosis subject; Obtaining a gain value of the diagnosis subject based on the magnitude of the disturbance and the flow of the diagnosis subject, Obtaining the gain value of the diagnosis subject is In order to maintain the balance of the human body corresponding to the disturbance based on the angular velocity and the angular velocity data of the ankle and hip joints according to the driving torque generated in the process of applying the disturbance of the predetermined size to the diagnosis subject. Comprising a step of quantitatively calculating the rate of change of the gain value of the ankle joint and the gain value of the hip joint defined. Gain value of ankle joint = T _ankle / θ _ankle Gain value of hip joint = T _hip / θ _ankle T _ankle only _: torque acting on the ankle joint θ _ankle: ankle joint angle T _hip : Torque applied to hip joint θ _ankle : Hip joint angle The method of claim 6, The step of applying the disturbance to the diagnosis subject is a method for diagnosing the balance function of human body, characterized in that for applying a disturbance of a predetermined size to the diagnosis subject in the upright position and measuring the driving torque generated in the process of applying the disturbance. The method of claim 6, Capturing the flow of the ankle and hip joint of the diagnosis subject is a method for diagnosing the balance function of human body, characterized in that to obtain an angle data by measuring the angle and angular velocity of each joint. delete In the method of diagnosing human balance function, Applying a disturbance of a predetermined size to a diagnosis subject in an upright position, Capturing the flow of the ankle and hip joints of the diagnosis subject; Obtaining the maximum ankle torque and the maximum hip torque of the diagnosis subject based on the magnitude of the disturbance and the flow of the diagnosis subject.

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