TW201733530A - Method for detecting lower limb spasm by judging whether the torque outputted by the motor in the rehabilitation process is greater than a threshold value to be aware of the spasm occurrence of a patient - Google Patents

Abstract

A method for detecting lower limb spasm is to first place the lower limb of a patient to a lower limb support frame on a gait rehabilitation device. Then, a motor of the gait rehabilitation device is started to drive the lower limb support frame to rehabilitate the lower limb of the patient, and a statistical distribution data is obtained according to the torque change outputted by the motor within a predetermined time, and is used to calculate a threshold value from the statistical distribution data. Finally, the torque outputted by the motor in the rehabilitation process is judged whether to be greater than the threshold value. If yes, it indicates that the patient has spasm phenomenon. At this moment, the motor should be stopped immediately. Therefore, the detection method of this invention can detect whether the patient has spasm phenomenon during the rehabilitation process without using additional sensor, thereby effectively reducing the equipment cost.

Description

Method for detecting lower extremity paralysis

The invention relates to a method for rehabilitation of lower limbs, in particular to a method for detecting lower limb paralysis.

For patients with lower limbs caused by spinal cord injury, stroke, nerve damage, etc., in addition to the daily life depends on the movement and positioning of the body, the rehabilitation work must be assisted by the relevant auxiliary devices. However, in the process of rehabilitation, the lower body of the patient may be paralyzed due to muscle fatigue or other factors. At this time, the rehabilitation work must be stopped immediately until the patient rests enough to continue.

For the related conventional technology, for example, U.S. Patent No. 2014/0343459 uses a strain gauge and a potentiometer to detect an instantaneous signal generated when a sputum occurs, and another example is US Patent Publication No. 2008/0312549. The angle, angular velocity and myoelectric signal are obtained through several normal movements. Then, during the rehabilitation process, the relationship between the myoelectric signal and the fixed threshold and the angle and angular velocity recorded beforehand is detected. Awkward phenomenon. However, both of the aforementioned patents require the use of an additional sensor to achieve the effect, thus causing the problem of expensive equipment.

The main object of the present invention is to provide a method for detecting a lower limb paralysis, which directly judges the torque signal from the motor, and does not require an additional sensor, thereby effectively reducing the equipment cost.

In order to achieve the above object, the detection method provided by the present invention includes the following steps. First, let a patient enter a one-step rehabilitation machine, and place the lower limb of the patient on one of the lower limb support frames of the gait rehabilitation machine, and then start one of the motors of the gait rehabilitation machine to enable the motor to drive the motor The lower limb support frame rehabilitates the lower limb of the patient, and then obtains a statistical distribution data according to the torque change outputted by the motor within a predetermined time, and calculates a threshold value from the statistical distribution data, and finally determines the motor. Whether the torque output during the rehabilitation process is greater than the threshold value. If yes, it indicates that the patient is paralyzed. At this time, it is necessary to immediately control the motor to stop running. If not, it indicates that the patient has not abnormal condition. This motor can be kept running.

In an embodiment of the present invention, the statistical distribution data is divided into a positive half cycle interval and a negative half cycle interval, and the threshold value of the positive half cycle interval is defined as TH ^up = μ ^up ±3σ ^up , and the negative half cycle interval The threshold is defined as TH ^down =μ ^down ±3σ ^down , where TH ^up is the threshold of the positive half-period interval, μ ^up is the average of the positive half-cycle interval, and σ ^up is the criterion for the positive half-period interval Poor, TH ^{down is} the threshold of the negative half cycle interval, μ ^{down is} the average of the negative half cycle interval, and σ ^{down is} the standard deviation of the negative half cycle interval. In addition, the foregoing two equations can be adjusted in accordance with the operating speed of the motor, the stride size of the patient, and the detection sensitivity of the gait rehabilitation machine to meet the needs of different patients.

Detailed steps or features relating to the detection method provided by the present invention will be described in the detailed description of the subsequent embodiments. However, it should be understood by those of ordinary skill in the art that the present invention is not limited by the scope of the invention.

Please refer to FIG. 1 first. The detection method of the present invention includes the following steps:

Step a): Let a patient enter the one-step rehabilitation machine 10, as shown in Fig. 2, and place the lower limb of the patient on one of the lower limb support frames 12 of the gait rehabilitation machine 10.

Step b): Start one of the motors 14 of the gait rehabilitation machine 10, and cause the motor 14 to drive the lower limb support frame 12 to rehabilitate the lower limbs of the patient.

Step c): Obtain a statistical distribution data according to the torque change outputted by the motor 14 for a predetermined time, and calculate a threshold value from the statistical distribution data.

As shown in Figure 3, the statistical distribution data is divided into a positive semi-circular interval and a negative semi-circular interval. The projections of the positive and negative semi-circumferential intervals on the Y-axis form a normal distribution, respectively. If the normal signal falls into this Within a normal distribution, the concept of the confidence interval is used to determine whether the data of a certain measurement point is a normal signal. If the data of the measurement point is a normal signal, the data of the measurement point will fall in the positive and negative half. The average of the weekly interval is within the range of 3 standard deviations. Therefore, in step c), after calculating the average and standard deviation of the positive and negative half-period intervals, the concept of the confidence interval is used to define the thresholds of the positive and negative half-period intervals, so that the following two equations can be obtained. : TH ^up =μ ^up ±3σ ^up TH ^down =μ ^down ±3σ ^down where TH ^up is the threshold of the positive half-period interval, μ ^up is the average of the positive half-period interval, and σ ^up is the standard for the positive half-period interval Poor, TH ^down is the threshold of the negative half cycle interval, μ ^down is the average of the negative half cycle interval, and σ ^down is the standard deviation of the negative half cycle interval.

Step d): judging whether the torque outputted by the motor 14 during the rehabilitation process is greater than a threshold value. If yes, as shown in Fig. 4, P1 represents a paralysis phenomenon of the patient, and the motor 14 needs to be controlled immediately. Stopping the operation, if it is no, it means that the patient has not had an abnormal condition, and the motor 14 can be continuously operated at this time.

On the other hand, since each patient's stride size is different, and the operating speed set by the motor 14 may also be different for the patient's needs, the present invention utilizes a surface fitting method. Calculate a correction parameter (as shown in Figure 5) for the running speed of the motor 14 and the stride size of the patient, so that the threshold of the positive half-period interval is corrected to TH ^up = μ ^up ±3σ ^up +S _V , negative The threshold of the half-cycle interval is corrected to TH ^down = μ ^down ±3σ ^down -S _V , where S _V is the correction parameter. Therefore, as can be seen from P2 of Fig. 6, assuming that the operating speed of the motor 14 is changed at the 300th second, the threshold is automatically corrected and does not need to be recalibrated.

In addition, the present invention can further add a sensitivity parameter, so that the threshold of the positive half-period interval is further corrected to TH ^up = μ ^up ±3σ ^up +S _V +S _ω ^up , and the threshold of the negative half-cycle interval is corrected to TH. ^Down =μ ^down ±3σ ^down -S _V +S _ω ^down , where S _ω ^up and S _ω ^down are the 痉挛 detection sensitivity parameters of the gait rehabilitation machine, and the sensitivity parameter satisfies the following equation: S _ω ^up =( μ ^up -μ ^data )*ω S _ω ^down =(μ ^data -μ ^down )*ω where μ ^data is the total average of the statistical distribution data, ω is the weight and is between 0 and 1, with 0 being the most sensitive 1 represents the least sensitive. With this sensitivity parameter, the patient can adjust the threshold range according to his own condition, as shown in Fig. 7, to achieve the effect of changing the detection sensitivity.

In summary, the detection method of the present invention utilizes the torque outputted by the motor 14 as a signal source, and can detect whether a patient is paralyzed during the rehabilitation process without using an additional sensor, so Effectively save equipment costs. In addition, during the rehabilitation process, the patient can adjust the speed at any time without recalibration, and can also adjust the detection sensitivity according to his own needs, so that the purpose of increasing the convenience of use can be achieved.

10‧‧‧gait rehabilitation machine
12‧‧‧ Lower limb support
14‧‧‧Motor

Figure 1 is a flow chart of the present invention. Fig. 2 is a schematic view showing the structure of a lower limb training machine used in the present invention. Figure 3 is a plot of the torque versus time of the motor. Figure 4 is similar to Figure 3 and shows the state of paralysis in patients. Fig. 5 is a coordinate diagram of the present invention, mainly showing a correction curved surface of a correction parameter. Figure 6 is a graph showing the relationship between the torque of the motor and the time, mainly showing the state of the threshold after the correction parameter is added. Figure 7 is a graph showing the relationship between the torque of the motor and the time, mainly showing the state of the threshold after the sensitivity parameter is added.

Claims (5)

A method for detecting lower extremity paralysis includes the following steps: a) allowing a patient to enter a one-step rehabilitation machine and placing the lower limb of the patient on one of the lower limb support frames of the gait rehabilitation machine; b) starting a motor of the gait rehabilitation machine, the motor driving the lower limb support frame to rehabilitate the lower limb of the patient; c) obtaining a statistical distribution data according to the torque change outputted by the motor within a predetermined time period, Calculating a threshold value from the statistical distribution data; and d) determining whether the torque output by the motor during the rehabilitation process is greater than the threshold value, and if so, controlling the motor to stop operating. The method for detecting a lower extremity as described in claim 1, wherein the statistical distribution data is divided into a positive semi-circular interval and a negative semi-circular interval, and the threshold of the positive semi-circular interval is defined as TH ^up = μ ^up ± 3σ ^Up , the threshold of the negative half-period interval is defined as TH ^down =μ ^down ±3σ ^down , where TH ^up is the threshold of the positive half-period interval, μ ^up is the average of the positive half-period interval, and σ ^up is The standard deviation of the positive half cycle interval, TH ^{down is} the threshold of the negative half cycle interval, μ ^{down is} the average value of the negative half cycle interval, and σ ^{down is} the standard deviation of the negative half cycle interval. The method for detecting a lower extremity as described in claim 2, wherein the threshold of the positive half cycle interval is defined as TH ^up = μ ^up ±3σ ^up + S _V , and the threshold of the negative half cycle interval is defined as TH ^down = μ ^Down ±3σ ^down -S _V , where S _V is a correction parameter calculated by surface fitting of the torque outputted by the motor and the stride of the patient. The method for detecting a lower extremity as described in claim 3, wherein the threshold of the positive half cycle interval is defined as TH ^up = μ ^up ±3σ ^up +S _V +S _ω ^up , and the threshold of the negative half cycle interval is defined as TH ^Down = μ ^down ±3σ ^down -S _V +S _ω ^down , where S _ω ^up and S _ω ^down are the detection sensitivity parameters of the gait rehabilitation machine. The method for detecting a lower extremity as described in claim 4, wherein the sensitivity parameter satisfies the following equation: S _ω ^up = (μ ^{up -} μ ^data ) * ω S _ω ^down = (μ ^{data -} μ ^down ) * ω μ ^data is the total average of the statistical distribution data, ω is the weight and is between 0 and 1, with 0 being the most sensitive and 1 being the least sensitive.