WO2016006432A1 - 脚相移行タイミング判定方法、脚相移行タイミング判定装置、歩行支援制御方法及び歩行支援装置 - Google Patents
脚相移行タイミング判定方法、脚相移行タイミング判定装置、歩行支援制御方法及び歩行支援装置 Download PDFInfo
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- WO2016006432A1 WO2016006432A1 PCT/JP2015/067956 JP2015067956W WO2016006432A1 WO 2016006432 A1 WO2016006432 A1 WO 2016006432A1 JP 2015067956 W JP2015067956 W JP 2015067956W WO 2016006432 A1 WO2016006432 A1 WO 2016006432A1
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- Prior art keywords
- phase
- leg
- transition timing
- walking
- rigidity
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- 230000007704 transition Effects 0.000 title claims abstract description 132
- 238000000034 method Methods 0.000 title claims description 36
- 210000002414 leg Anatomy 0.000 claims abstract description 145
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- 230000001133 acceleration Effects 0.000 claims description 14
- 230000008859 change Effects 0.000 claims description 14
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- 238000004364 calculation method Methods 0.000 abstract description 11
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Definitions
- the present invention relates to a technique for determining a user's walking state and supporting walking motion.
- This type of device includes a motor that applies torque to the knee joint and the like, and also includes a detection unit that detects the walking state of the pedestrian in order to suitably control the application of torque. Since the walking state of a pedestrian is determined based on the free leg phase and the stance phase in walking and stair climbing operations, the sole installation type detects the ground contact timing of the foot as the detection unit Such pressure sensors and waist-mounted gravity sensors are generally used (for example, Patent Documents 1 to 7).
- Non-Patent Document 1 discloses that a ball screw mechanism includes two frames, a ball screw mechanism, a linear spring, and a motor that are connected via a rotating member, and the elasticity of the linear spring that can be expanded and contracted between the two frames. There has been proposed a small and light variable stiffness mechanism that can be changed by using a linear spring so that the elastic energy of the linear spring is maximized when the stiffness is maximum.
- JP 2011-239887 A WO2010 / 074160 JP 2003-116893 A JP 2010-148759 A JP 2010-273748 A JP 2011-206289 A JP 2010-148637 A JP 2008-175559 A
- Patent Literature 1 and Patent Literature 2 describe a discrimination algorithm for discriminating the switching timing of the free leg / stand by using the foot horizontal direction speed.
- the speed in the horizontal direction of the foot is the foot speed on the free leg side as seen from the leg on the stance side, and it is necessary to determine which foot is on the stance side by using a pressure sensor on the sole.
- the discrimination algorithm of Patent Document 1 and Patent Document 2 requires a pressure sensor on the sole and a posture sensor on both legs.
- Patent Document 8 performs walking analysis using an absolute value of acceleration detected by an acceleration sensor attached to a foot.
- a method using an absolute value of acceleration a method other than normal flat ground walking is used. Walking analysis is difficult for various walking states, and it is not a configuration that can be applied to walking support devices in real time.
- Non-Patent Document 1 relates to a variable stiffness mechanism and does not perform stiffness change control of the variable stiffness mechanism in relation to a walking state.
- the present invention has been made in view of the above, and without using a pressure sensor on the sole, each transition between the free leg period and the stance period by utilizing a relative foot speed with respect to the reference position of the human body. It is an object of the present invention to provide a leg shift timing determination apparatus and method that can determine timing more accurately.
- the present invention provides a walking support device that suitably assists the knee joint in accordance with the walking state and a control method thereof.
- a phase transition timing determination device includes a walking information acquisition unit that receives an output of a sensor that detects leg movement and continuously calculates a relative speed of a foot to a reference part of a human body; Leg state judging means for judging the transition timing between the swing phase and the stance phase based on the relative speed is provided.
- the walking information acquisition means receives the output from the sensor, and continuously calculates the relative speed of the toes with respect to the reference part of the human body, for example, the waist. Then, each transition timing between the swing phase and the stance phase based on the relative speed calculated by the walking information acquisition unit by the leg state determination unit, that is, a transition timing from the swing phase to the stance phase. Or whether it is the transition timing from the stance phase to the swing phase. Therefore, the transition timing between the swing leg period and the stance period becomes more accurate by utilizing the relative foot tip speed with respect to the reference position of the human body.
- the phase transition timing determination method includes a walking information acquisition step of receiving an output of a sensor that detects leg motion and continuously calculating a relative speed of a foot tip with respect to a reference part of a human body; And a leg state determination step of determining a transition timing between the swing phase and the stance phase based on the relative speed of the toes calculated in the information acquisition step.
- a walking support device is a walking support device provided with a variable stiffness mechanism that is mounted on a leg of a human body and capable of changing rigidity in a direction in which the knee bends and extends, the phase transition timing determination device, Stiffness control means for increasing the rigidity of the variable stiffness mechanism at the transition timing from the swing phase to the stance phase and lowering the stiffness of the variable stiffness mechanism at the transition timing from the stance phase to the swing phase.
- the walking support control method is the walking support control method for a walking support brace equipped with a variable rigidity mechanism that is mounted on a leg of a human body and capable of changing rigidity in a direction in which the knee bends and stretches.
- a walking information acquisition step for receiving the output of the sensor for detecting the foot and continuously calculating the relative speed of the toes relative to the reference part of the human body, and the play based on the relative speed of the toes calculated in the walking information acquisition step.
- the leg state determination step for determining the transition timing between the stance phase and the stance phase, and at the transition timing from the swing phase to the stance phase, the rigidity of the variable stiffness mechanism is increased, and the stance phase to the swing phase is increased.
- a stiffness control step for reducing the stiffness of the variable stiffness mechanism at the transition timing.
- the walking support device is attached to the leg of the human body, and the rigidity is changed in order to adjust the magnitude of the torque applied in the direction of bending and stretching the knee by the variable rigidity mechanism.
- each transition timing between the swing leg phase and the stance phase is determined by a phase transition timing determination device having a sensor for detecting leg movement.
- the rigidity of the variable stiffness mechanism is increased by the stiffness control means, and at the transition timing from the stance phase to the swing phase, the stiffness of the variable stiffness mechanism is increased by the stiffness control means. Be lowered.
- the walking state that is the transition timing between the swing phase and the stance phase is determined, and the stiffness is adjusted by changing the height accordingly, so that assist to the knee is suitably performed.
- the present invention it is possible to suitably perform the level change adjustment of the stiffness for assisting the knee in accordance with the transition timing between the swing phase and the stance phase.
- FIG. 1 It is a schematic structure figure showing one embodiment of the walk support equipment in the walk support device concerning the present invention, and is a figure in which the variable rigidity mechanism was omitted. It is explanatory drawing explaining the structure and movement of a variable rigidity mechanism, (a) is a figure in a free leg state, (b) is explanatory drawing in a standing leg state. It is a block diagram which shows one Embodiment of the control system of the walk assistance apparatus which concerns on this invention. It is a time chart figure of each state and signal corresponding to walking operation. It is a wave form diagram which shows the result of the experiment explaining evaluation of the discrimination
- FIG. 1 is a schematic structural diagram showing an embodiment of a walking assistance device in a walking assistance device according to the present invention.
- the variable stiffness mechanism 4 is not shown in FIG. 1, but details of the variable stiffness mechanism 4 are shown in FIG.
- the walking support device includes the walking support device 1 shown in FIG. 1 and the variable stiffness mechanism 4 shown in FIG. 2, and the operation of the variable stiffness mechanism 4 is controlled by the control unit 5 shown in FIG. 3.
- the walking support device 1 includes a plate-like upper link 10 and a lower link 20 that are pivotably connected to each other on one end side via a rotating member 30.
- the upper link 10 and the lower link 20 are made of a material having robustness and have length dimensions corresponding to the lengths of the human thigh P1 and the thigh P2.
- the length dimension of the upper link 10 and the lower link 20 may be produced to the same dimension (L) as in this embodiment, or the physique of the user to wear (for example, P1 is L1 and P2 is L2). It may be manufactured according to.
- P0 indicates an appropriate position of the user's trunk, in the present embodiment, a waist region
- P3 indicates a toe region.
- binding belts 101 and 201 as an example of a binding tool are attached.
- the binding belts 101 and 201 fasten and fix the upper link 10 and the lower link 20 to the outer side surface of the leg by being wound around the thigh P1 and the thigh P2.
- the binding work is performed in a state in which the rotating member 30 is positioned so as to be positioned on the side of the knee. Therefore, when the walking support device 1 is worn, the upper link 10 and the lower link 20 swing around the rotating member 30 in accordance with the bending and stretching of the user's thigh P1 and thigh P2.
- a band, a hook-and-loop fastener, or a mechanical fastening member can be used as the binding tool.
- the attitude sensors 11 and 21 are attached to appropriate positions of the upper link 10 and the lower link 20, for example, at substantially the center position in the longitudinal direction thereof.
- an acceleration sensor or a gyro sensor can be used as the attitude sensors 11 and 21, an acceleration sensor or a gyro sensor can be used.
- the posture sensor 11 detects an inclination angle q1 of the upper link 10, that is, the thigh P1 with respect to the vertical direction.
- the posture sensor 21 detects an inclination angle q2 of the lower link 20, that is, the thigh P2 with respect to the vertical direction.
- FIG. 2A and 2B are explanatory views for explaining the configuration and movement of the variable rigidity mechanism 4.
- FIG. 2A is a view in a swinging leg state where the leg is floating from the ground
- FIG. 2B is a standing leg state where the leg is grounded. It is explanatory drawing of.
- the variable rigidity mechanism 4 is mounted on the walking assistance device 1.
- the variable rigidity mechanism 4 is attached to the upper link 10 and the lower link 20.
- a plate-like attachment member 41 is erected on the side surface of the upper link 10, and a motor 42 as a drive source is fixed to the attachment member 41.
- a ball screw 43 having a predetermined length is connected to the output shaft of the motor 42, and the ball screw 43 is rotated forward and backward by driving the motor 42.
- the motor 42 is attached to the attachment member 41 so that the axial direction of the ball screw 43 extends toward the rotating member 30 and is preferably parallel to the longitudinal direction of the upper link 10.
- the nut 44 functions as a movable fulcrum member as will be described later, has a hole in which a female screw is formed, and is screwed into the ball screw 43.
- a rod-shaped body 47 for restricting rotation is erected on the mounting member 41 in parallel with the ball screw 43.
- the nut 44 is formed with an engagement hole or notch for restricting only the rotation operation with the rod-shaped body 47. Therefore, when the motor 42 rotates with the nut 44 screwed to the ball screw 43, the nut 44 is engaged with the rod-like body 47 and the rotation is restricted. As a result, the ball screw 43 is rotated according to the normal rotation and reverse rotation of the motor 42.
- FIG. 2A shows a state in which the nut 44 is on the proximal end side
- FIG. 2B shows a state in which the nut 44 is on the distal end side.
- one end of the wire 45 is bound to a proper position of the mounting member 41.
- the wire 45 has a predetermined length, and the other end is engaged with one end of an elastic member such as a spring, preferably a linear spring 46 having a predetermined elastic coefficient.
- a locking tool 22 is provided at an appropriate position on the side opposite to the mounting side of the rotating member 30.
- the base end of the linear spring 46 is locked to the locking tool 22.
- the wire 45 is engaged with the nut 44 to form a bypass. Specifically, the wire 45 is stretched over a through-hole 441 formed in the thickness direction of the nut 44 on the way.
- the through hole 441 faces the rotating member 30 in the middle of the movement locus.
- the position of the through hole 441 is referred to as the fulcrum 441 in the swing of the linear spring 46.
- the fulcrum 441 is positioned in the vicinity of the rotating member 30 (that is, the knee), preferably on the proximal end side that is closer to the upper link 10 than the rotating member 30, and FIG. ), The fulcrum 441 is located away from the rotating member 30 (that is, the knee) toward the tip side.
- the fulcrum 441 is on the knee side, and the linear spring 46 is slightly extended, that is, a weak force. It is in the state which has produced.
- the fulcrum 441 is on the tip side compared to the knee, and the linear spring 46 is compared to the length of the line segment connecting the rotating member 30 and the locking tool 22.
- the fulcrum 441 is extended according to the detour (the detour length is increased), that is, a strong force is generated, and the elastic energy of the linear spring 46 is increased.
- the strong force of the linear spring 46 acts and it becomes difficult to bend, that is, the rigidity of the orthosis is increased, so that the leg in the standing state does not bend the knee.
- the high elastic energy of the linear spring 46 acts as a strong restoring force that returns the lower link 20 to a direction parallel to the upper link 10 (see arrow (4)). . Therefore, by using this force as an assist force, it becomes easy to make a transition from the swing phase to the stance phase and prevent knee breakage during the stance phase. Particularly when climbing stairs, it is suitable for transferring weight (trunk) to a leg on the standing leg side or lifting weight.
- the linear spring 46 does not appear to be stretched as compared with FIG. 2A in terms of drawing, but as described above, it is actually stretched and has high rigidity. Is shown.
- FIG. 3 is a block diagram showing an embodiment of a control system of the walking support apparatus according to the present invention.
- the control unit 5 is configured by a microcomputer or the like, and can be mounted on, for example, a user's waist, shoulder, or back.
- the control unit 5 includes a processor, and includes posture sensors 11 and 21, a motor 42, a memory area that stores processing programs, data necessary for processing, and a work memory area that temporarily stores data being processed. Connected to the storage unit 5a.
- the control part 5 is a walking information acquisition part 50 which acquires the information regarding a user's walking state from the detection result of the attitude
- the walking information acquisition unit 50 includes a thigh movement calculation unit 51, a thigh movement calculation unit 52, and a toe movement calculation unit 53.
- the thigh movement calculation unit 51 continuously captures the movement of the thigh P1 from the posture sensor 11 at a predetermined cycle.
- the thigh movement calculation unit 51 calculates the inclination angle q1 of the upper link 10 with respect to the vertical direction from the detection signals continuously acquired from the posture sensor 11, and calculates the angular velocity Vq1 from the continuous inclination angle q1.
- the thigh movement calculation unit 52 continuously captures from the posture sensor 21 at a predetermined cycle.
- the thigh movement calculating unit 52 calculates the inclination angle q2 of the lower link 20 with respect to the vertical direction from the detection signals continuously taken from the posture sensor 21, and calculates the angular velocity Vq2 from the continuous inclination angle q2.
- the toe movement calculating unit 53 sequentially calculates a relative position based on the user's waist P0 from the speed Vx.
- the leg state determination unit 54 determines the contact timing of the toe P3 from the sequentially calculated polarity of Vx, that is, a positive / negative change state. Since the polarity of Vx does not change with the dimension L, the length of the leg is irrelevant to the determination of the ground contact timing. That is, the contact timing can be determined without knowing the leg length.
- the motor drive control unit 55 outputs a drive command to the motor 42 according to the determination result of the leg state determination unit 54.
- the relationship between the swing phase and the stance phase and the relative foot position and speed are as follows. That is, for the leg of interest, when the speed Vx is positive, the leg is in the swing phase, and when the speed Vx is negative, the leg is in the stance phase. Furthermore, since the speed Vx is continuous and has periodicity, the walking state can be predicted. It should be noted that the leg of interest is a time when the toe position changes from a free leg to a standing leg when the toe position is forward (positive) with respect to the waist P0, and when the toe position is behind (negative) with respect to the waist P0. This is the time to change to the leg, and this condition can be used as information to reinforce the judgment of the walking state. In addition, as long as it is a range having the same characteristics as walking, it is possible to include rapid walking or running state as the same manner as walking.
- “rigid rigidity” in FIG. 4C indicates a setting state of the position of the fulcrum 441 by the motor 42. That is, the rigidity of the orthosis is changed from low rigidity to high rigidity in accordance with the transition from the swing phase to the stance phase, and is changed from high rigidity to low rigidity in accordance with the transition from the stance phase to the swing phase. .
- the transition signals between the swing phase and the stance phase are obtained by continuously acquiring the detection signals of the posture sensors 11 and 21 and continuously calculating the toe speed Vx. Can be predicted.
- a suitable characteristic value can be obtained by setting each of the high and low stiffness values and the transition time experimentally or empirically.
- the change of rigidity may be switching in a short time, but if it is changed transiently, compared to the switching in a short time, the grounding of the legs and the walking movement at getting out of bed are smoother and more It will be close to nature. Further, torque applied to the motor 42 can be suppressed, and power saving can be achieved.
- FIG. 5 is a waveform diagram showing the results of an experiment for explaining the evaluation of the discrimination of the transition of the leg using the posture sensors 11 and 21 according to the present embodiment.
- the presence or absence of grounding is determined by the grounding sensor installed on the sole.
- a detection signal (rectangular waveform (i) of the standing leg and the free leg in the figure) is shown.
- the upper part is a comparative example corresponding to Patent Document 8 (Japanese Patent Laid-Open No. 2008-175559), which is determined using the absolute value of acceleration
- the lower part is a diagram in which posture sensors 11 and 21 are provided.
- This embodiment uses the mechanism shown in FIG.
- the walking state “normal walking on the flat ground” is shown at the right end, and other walking states include “flat walking (fast walking)”, “complex walking”, and “stairs climbing (low speed)” from the right side. Show.
- FIG. 5 in the case of “ordinary walking on a flat ground”, in the upper comparative example, a predetermined level of acceleration can be detected corresponding to the transition to the phase, so it is possible to determine the phase transition timing.
- the present embodiment in the lower stage it can be seen that it is possible to determine the phase transition because the relative speed of the toes is consistent with the sign of the relative speed.
- leg phase transition timing can be determined by using the positive / negative polarity of the relative speed of the toes, or the change state from positive to negative and from negative to positive.
- FIG. 6 is a time chart showing the results of an experiment comparing the relative speed of the toes performed by using the mechanism of FIG. 1 with the state of the standing leg and the free leg.
- the walking speed for one step on each of the left and right is a normal walking speed (cycle), for example, one step on each of the left and right.
- the upper part of FIG. 6 shows the relative speed of the toes, and the lower part shows a square waveform (i) of the standing leg and the free leg by the ground sensor.
- the relative speed of the toes does not change from negative to positive
- the stance phase is in the stage of transition from the stance phase to the swing phase, and conversely, the early withdrawal speed of the toes is positive.
- the phase is in the transition from the swing phase to the stance phase. Therefore, it can be seen that the positive and negative polarities of the relative speed of the toes are consistent with the respective transition timings between the standing leg and the free leg.
- FIG. 7 is a flowchart showing the process I, which is an example of the walking support process.
- inclination angles q1 and q2 and angular velocities Vq1 and Vq2 are acquired from detection signals from attitude sensors 11 and 21 (step S1).
- a foot speed Vx relative to the waist P0 is calculated from the inclination angles q1, q2 and the angular velocities Vq1, Vq2 (step S3).
- a determination is made as to whether or not there is a phase shift (step S5).
- This determination can be processed by determining the timing at which the speed Vx crosses 0 in the aspect of changing the rigidity in a short time.
- step S5 when the determination in step S5 is processed based on prediction as in this embodiment, each time the speed Vx is calculated, the polarity and the threshold values Vs1 and Vs2 are compared according to the polarity. If it is determined that there is no shift in the phase, the process returns to step S1 via step S15 and the same processing is repeated at a predetermined cycle. On the other hand, if there is a shift in the phase in step S5, a determination is made as to “Transition 1” or “Transition 2”. The determination of “transition 1” or “transition 2” may be made based on the polarity of the speed Vx, and as described above, the relative position of the toe position calculated with the calculation of the speed Vx with respect to the waist P0.
- the polarity information may be used for the determination of “Migration 1” and “Migration 2” in a reinforcing manner.
- “Transition 1” refers to the time when the polarity of the relative speed Vx of the toes is negative and changes from the stance phase to the next swing phase
- “Transition 2” refers to the relative velocity Vx of the toes. This is the time when the polarity of is positive and changes from the swing phase to the next stance phase.
- step S7 If it is determined that the phase shift is “transition 1”, it is determined that the phase shifts to the swing phase (step S7), and a normal rotation drive command is issued to the motor 42 at a predetermined amount and at a predetermined speed (step S7). Step S9).
- step S11 when the transition of the phase is determined to be “transition 2”, it is determined that the transition to the stance phase is performed (step S11), and a reverse drive command at a predetermined amount and a predetermined speed is issued to the motor 42 ( Step S13).
- step S13 Next, it is determined whether or not it is finished. If it is not finished, the above process is repeated. If it is finished, the process is exited.
- FIG. 8 is a diagram showing the results of an experiment for evaluating the consistency between “Migration 1” and “Migration 2” and the positive / negative information of the relative position of the toes.
- Waveform (ii) shows the relative position where 0 is also stopped from the relative speed of the toes.
- the figure shows “normal flat walking”, “flat walking (fast walking)”, “complex walking”, and “stairs climbing (low speed)” in order from the right side.
- transition 1 i.e., when changing from the stance phase to the swing phase
- transition 2 i.e., from the swing phase to the stance phase.
- the relative position of the toes is in a positive position. Therefore, it can be seen that the relative speed of the toes is used for the transition timing of the phase, and the positive / negative information of the relative position of the toes is effective as a determination factor of “transition 1” or “transition 2”.
- FIG. 9 is a flowchart showing a process II which is another embodiment of the walking support process.
- Process II is a case where, based on the experimental example of FIG. 8, the positive / negative information of the relative position is used instead of the positive / negative information of the relative speed when determining “transition 1” and “transition 2”.
- steps S21 and S23 are the same as steps S1 and S3, and the description thereof is omitted.
- the toe movement calculation unit 53 calculates the relative position based on the user's waist P0 from the speed Vx by, for example, successive integration processing.
- Step S27 performs the same processing as step S5, that is, whenever the velocity Vx is calculated, the polarity and the threshold values Vs1 and Vs2 are compared according to the polarity. If it is determined that there is no shift in the phase, the process returns to step S21 via step S39 and the same process is repeated at a predetermined cycle. On the other hand, if it is determined in step S27 that there is a shift in the phase of the foot, using the polarity information of the relative position of the toe position with respect to the waist P0 obtained in step S25, it is determined whether “transition 1” or “transition 2”. A determination is made (step S29).
- step S31 If the relative position is negative, it is determined that the phase shift is “transition 1”, that is, the transition to the swing phase (step S31), and a normal rotation drive command at a predetermined amount and a predetermined speed is issued to the motor 42. Performed (step S33). On the other hand, when the relative position is negative, it is determined that the transition of the phase is “transition 2”, that is, the transition to the stance phase (step S35), and a reverse drive command with a predetermined amount and a predetermined speed is issued to the motor 42. Performed (step S37). Next, it is determined whether or not it is finished. If it is not finished, the above process is repeated. If it is finished, the process is exited.
- the present invention can employ the following embodiments.
- the prediction time of stiffness change is performed using the threshold values Vs1 and Vs2.
- the driving speed and driving amount of the motor 42 in the rigidity change may be adjustable according to the user.
- determines, or selects manually at the time of a flat ground walk and the time of stair-climbing.
- variable stiffness mechanism 4 can be changed to the following mode.
- the linear spring 46 may not necessarily be linear as long as it has elasticity.
- an elastic wire may be used instead of the linear spring 46.
- a wire may be connected to both sides of the linear spring 46.
- another drive source such as an electromagnetic solenoid may be employed instead of the motor 42.
- the motor 42 is preferably attached to the upper link 10 in consideration of weight, but it may be provided on the lower link 20 side so that the turning direction of the ball screw 43 is opposite to that in the above embodiment. .
- a sliding screw mechanism or other mechanisms that convert rotational motion into translational motion can be employed.
- variable rigidity mechanism 4 shown in FIG. 2 is adopted.
- the structure is not limited to the structure shown in FIG. 2 as long as the rigidity can be changed according to the walking phase.
- an aspect in which the rigidity is made variable by variably applying a rotation load to the rotating member 30 may be used.
- the rotation load may be changed by applying, for example, a technique adopted in an electromagnetic brake or a brake technique that mechanically increases or decreases a frictional force.
- the posture sensors 11 and 21 may measure the angle on the vertical plane using a magnetic sensor or the like in addition to the acceleration sensor and the gyro sensor. Moreover, the aspect which utilizes the detection signal of one attitude
- the posture sensors 11 and 21 may be attached to one leg of the human body, so that there is no need to provide a pressure sensor on the sole, there are few restrictions on movement, and a long life can be achieved. Moves alternately so that the movement of the opposite leg can be known from the movement information of one leg, and the number of sensors is reduced accordingly. Moreover, it is good also as a structure with which it mounts
- the toe speed is defined in the orthogonal coordinate system, but is not limited to the orthogonal coordinate system as long as it can evaluate whether the toe is moving forward or backward of the human body.
- the toe speed may be defined by polar coordinates with the waist as the origin.
- the present invention is configured as described above, the life can be extended compared to the case of using a ground sensor attached to the sole of the foot, and movement information can be continuously acquired unlike a pressure sensor such as a ground sensor. Therefore, future prediction is possible. And by enabling the future prediction, it becomes possible to develop a robot orthosis or prosthetic leg that has a higher support effect than before and can provide natural support. Furthermore, the present invention can be applied to a type of orthosis that cannot be attached to the sole. In addition, it is easy to attach and remove, and is excellent in operability and convenience.
- phase transition timing determination process between the swing phase and the stance phase in the control unit 5 is not limited to the application to the variable stiffness mechanism 4, and other types of types utilizing the phase transition timing.
- the present invention can also be applied to other walking support devices.
- the phase transition timing determination device receives the output of the sensor that detects the movement of the leg and continuously calculates the relative speed of the toes relative to the reference part of the human body. And leg state determining means for determining a transition timing between the swing leg phase and the stance phase based on the relative speed of the toes.
- the walking information acquisition means receives the output from the sensor, and continuously calculates the relative speed of the toes with respect to the reference part of the human body, for example, the waist. Then, each transition timing between the swing phase and the stance phase based on the relative speed calculated by the walking information acquisition unit by the leg state determination unit, that is, a transition timing from the swing phase to the stance phase. Or whether it is the transition timing from the stance phase to the swing phase. Therefore, the transition timing between the swing leg period and the stance period becomes more accurate by utilizing the relative foot tip speed with respect to the reference position of the human body.
- the leg state determination means determines the transition timing between the swing phase and the stance phase based on the relative speed of the toes and the positive / negative polarity. It is preferable. According to this configuration, by using the positive / negative polarity information of the relative speed of the toes, each transition timing between the swing phase and the stance phase can be accurately determined.
- the walking information acquisition means further receives the output of the sensor and continuously calculates the relative position of the toes with respect to the reference part of the human body.
- the leg state determining means may further determine the transition timing from the swing phase to the stance phase based on whether the relative position of the toes is positive or negative, or the transition from the stance phase to the swing phase. It is preferable to determine whether it is timing. According to this configuration, the information on whether the relative position of the toes is positive or negative is reinforced as the determination information, so that it is possible to determine the phase transition timing with higher accuracy.
- the sensor detects the thigh and the thigh of the human body as the movement of the leg. According to this configuration, there is no need to provide a pressure sensor on the sole, there are few restrictions on movement, and a long life can be achieved.
- the sensor is preferably at least one of an acceleration sensor, a magnetic sensor, and a gyro sensor. According to this configuration, since the detection signal can be continuously taken out, future prediction processing can be performed. Further, since the sensor attached to the sole is not used, the life of the sensor can be extended. Further, since the sensor only needs to be attached to one leg, the sensors for both legs are unnecessary.
- the present invention also includes a walking information acquisition step that receives the output of a sensor that detects leg movement and continuously calculates the relative speed of the toes relative to a reference part of the human body, and the walking information acquisition step calculates the walking information acquisition step.
- a leg phase transition timing determination method including a leg state determination step of determining a transition timing between a swing phase and a stance phase based on a relative speed of a toe.
- leg state determining step it is preferable to determine the transition timing between the swing phase and the stance phase based on the relative speed of the toes and the positive / negative polarity.
- the walking information acquisition step further receives the output of the sensor, continuously calculates the relative position of the toes with respect to a reference part of the human body, and determines the leg state determination The step further determines whether it is a transition timing from the swing phase to the stance phase or a transition timing from the stance phase to the swing phase based on whether the relative position of the toes is positive or negative It is preferable.
- the present invention also provides a walking support device including a variable stiffness mechanism that is mounted on a leg of a human body and capable of changing stiffness in a direction in which the knee bends and extends, a phase transition timing determination device according to the present invention, and the free leg. And a stiffness control means for increasing the rigidity of the variable stiffness mechanism at the transition timing from the stance phase to the stance phase and lowering the stiffness of the variable stiffness mechanism at the timing of transition from the stance phase to the swing phase. .
- the present invention provides a walking support control method for a walking support device that includes a variable rigidity mechanism that is mounted on a leg of a human body and that can change rigidity in a direction in which the knee bends and extends, and an output of a sensor that detects the movement of the leg.
- a walking information acquisition step for continuously calculating the relative speed of the toes with respect to a reference part of the human body, and a swing phase and a stance phase based on the relative speed of the toes calculated in the walking information acquisition step
- a leg state determining step for determining a transition timing between the stance phase and the transition timing from the swing phase to the stance phase, the variable stiffness mechanism is increased in rigidity, and at the transition timing from the stance phase to the swing phase, the variable stiffness is increased.
- a walking support control method including a stiffness control step for reducing the stiffness of the mechanism.
- the walking support device is attached to the leg of the human body, and the rigidity is changed in order to adjust the magnitude of the torque applied in the direction of bending and stretching the knee by the variable rigidity mechanism.
- each transition timing between the swing leg phase and the stance phase is determined by a phase transition timing determination device having a sensor for detecting leg movement.
- the rigidity of the variable stiffness mechanism is increased by the stiffness control means, and at the transition timing from the stance phase to the swing phase, the stiffness of the variable stiffness mechanism is increased by the stiffness control means. Be lowered.
- the walking state that is the transition timing between the swing phase and the stance phase is determined, and the stiffness is adjusted by changing the height accordingly, so that assist to the knee is suitably performed.
- the rigidity control means maintains the set rigidity until the next start of the change of the rigidity. According to this configuration, the assist effect is stabilized by maintaining the rigidity required in each of the swing phase and the stance phase.
- the rigidity control means is a means for transiently changing the rigidity of the variable rigidity mechanism. According to this configuration, it is possible to support natural walking by changing the rigidity transiently.
- the rigidity control means increases the rigidity of the variable rigidity mechanism, it is determined that the relative position of the toe is on the front side compared to the reference portion, and the rigidity of the variable rigidity mechanism is determined.
- the relative position of the toes is determined to be on the rear side compared to the reference portion. According to this configuration, it is possible to determine the transition timing with high accuracy by reinforcing the relative position of the toes as the determination information.
- the walking support orthosis includes a thigh-side link and a thigh-side link connected via a rotation member corresponding to a knee position, and the variable rigidity mechanism includes one of the thigh-side link and the thigh-side link.
- an elastic member that bypasses the fulcrum member between them, and the rigidity control means drives the drive source to control the transition from the swing phase to the stance phase.
- the fulcrum member is moved to a position away from the rotating member, and the fulcrum member is moved to a position close to the rotating member at the transition timing from the stance phase to the free leg phase.
- the extension amount of the elastic member can be changed by moving the fulcrum member in the perspective direction as compared with the rotating member by driving the drive source, that is, by shortening the detour length.
- the rigidity can be changed.
- the sensor is attached to the thigh side link, and is attached to the first thigh sensor and the thigh side link for detecting movement in the vertical plane of the thigh side link. It is preferable to include a second posture sensor for detecting in-plane movement. According to this configuration, the relative speed of the toe is calculated by attaching the posture sensor to the thigh side link and the thigh side link, so that the future can be predicted easily and with a long life without providing a sensor on the sole. Configuration can be provided.
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Abstract
Description
Vx=L・cos(q1)・Vq1-L・cos(q2)・Vq2 ・・・(式1)
として周期的に求める。但し、式1では、腰P0を基準に歩行方向(前方)位置を正、また、腰P0の速度を基準に歩行方向の速度を正としている。
Vx=L1・cos(q1)・Vq1-L2・cos(q2)・Vq2 ・・・(式2)
に基づいて算出することが好ましい。但し、式2において、Vxは、人体の腰を基準にした足先の相対速度、q1,Vq1は、前記大腿部の傾斜角及び角速度、q2,Vq2は、前記小腿部の傾斜角及び角速度、及びL1,L2は、人体の大腿部及び小腿部の寸法である。
10 上側リンク(大腿側リンク)
11,21 姿勢センサ(センサ)
20 下側リンク(小腿側リンク)
30 回動部材
4 可変剛性機構
42 モータ(駆動源)
43 ボールネジ
44 ナット(支点部材)
441 支点
46 線形バネ(弾性部材)
5 制御部
53 足先動き算出部(歩行情報取得手段)
54 脚状態判断部(脚状態判断手段)
55 モータ駆動制御部(剛性制御手段)
Claims (16)
- 脚の動きを検出するセンサの出力を受け付けて人体の基準部位に対する足先の相対速度を連続的に算出する歩行情報取得手段と、
前記足先の相対速度に基づいて遊脚期と立脚期との間の移行タイミングを判断する脚状態判断手段とを備えた脚相移行タイミング判定装置。 - 前記脚状態判断手段は、前記足先の相対速度及びその正負の極性に基づいて遊脚期と立脚期との間の移行タイミングを判断する請求項1に記載の脚相移行タイミング判定装置。
- 前記歩行情報取得手段は、さらに、前記センサの出力を受け付けて、前記人体の基準部位に対する足先の相対位置を連続的に算出するもので、
前記脚状態判断手段は、さらに、前記足先の相対位置が正か負かに基づいて前記遊脚期から前記立脚期への移行タイミングか、前記立脚期から前記遊脚期への移行タイミングかを判断する請求項1又は2に記載の脚相移行タイミング判定装置。 - 前記センサは、前記人体の大腿部及び小腿部の動きを前記脚の動きとして検出するものである請求項1~3のいずれかに記載の脚相移行タイミング判定装置。
- 前記足先の相対速度Vxは、
Vx=L1・cos(q1)・Vq1-L2・cos(q2)・Vq2
であることを特徴とする請求項4に記載の脚相移行タイミング判定装置。
但し、Vxは、人体の腰を基準にした足先の相対速度、q1,Vq1は、前記大腿部の傾斜角及び角速度、q2,Vq2は、前記小腿部の傾斜角及び角速度、及びL1,L2は、人体の大腿部及び小腿部の寸法である。 - 前記センサは、加速度センサ、磁気センサ及びジャイロセンサのうちの少なくとも1種類であることを特徴とする請求項1~5のいずれかに記載の脚相移行タイミング判定装置。
- 人体の脚に装着され、膝を屈伸する方向に対する剛性が変更可能な可変剛性機構を備えた歩行支援装具と、
請求項1~6のいずれかに記載の脚相移行タイミング判定装置と、
前記遊脚期から立脚期への移行タイミングでは前記可変剛性機構の剛性を高め、前記立脚期から遊脚期への移行タイミングでは前記可変剛性機構の剛性を下げる剛性制御手段とを備えた歩行支援装置。 - 前記剛性制御手段は、次の前記剛性の変更開始時まで、設定された剛性を維持するものである請求項7記載の歩行支援装置。
- 前記剛性制御手段は、前記可変剛性機構の剛性を過渡的に変更することを特徴とする請求項7又は8に記載の歩行支援装置。
- 前記剛性制御手段は、前記可変剛性機構の剛性を高めるときは、前記足先の相対位置が前記基準部位に比して前側にあると判定したことを条件とし、前記可変剛性機構の剛性を下げるときは、前記足先の相対位置が前記基準部位に比して後ろ側にあると判定したことを条件とする請求項7~9いずれかに記載の歩行支援装置。
- 前記歩行支援装具は、膝位置に対応する回動部材を介して連結された大腿側リンクと小腿側リンクとを備え、
前記可変剛性機構は、前記大腿側リンクと小腿側リンクの一方のリンクに取付けられた駆動源と、前記駆動源の駆動によって前記回動部材に近い位置と離れた位置との間で移動する支点部材と、前記大腿側リンクと小腿側リンクとの間に張設され、かつ、その間で前記支点部材を迂回して掛け渡された弾性部材とを備え、
前記剛性制御手段は、前記駆動源を駆動制御することによって、前記遊脚期から立脚期への移行タイミングでは前記支点部材を前記回動部材から離れた位置に移動させ、前記立脚期から遊脚期への移行タイミングでは前記支点部材を前記回動部材に近い位置に移動させる請求項7~10のいずれかに記載の歩行支援装置。 - 前記センサは、前記大腿側リンクに取付けられ、前記大腿側リンクの鉛直面内の動きを検出するための第1の姿勢センサと、前記小腿側リンクに取付けられ、前記小腿側リンクの鉛直面内の動きを検出するための第2の姿勢センサとを含む請求項11に記載の歩行支援装置。
- 脚の動きを検出するセンサの出力を受け付けて人体の基準部位に対する足先の相対速度を連続的に算出する歩行情報取得ステップと、
前記歩行情報取得ステップで算出された前記足先の相対速度に基づいて遊脚期と立脚期との間の移行タイミングを判断する脚状態判断ステップとを備えた脚相移行タイミング判定方法。 - 前記脚状態判断ステップは、前記足先の相対速度及びその正負の極性に基づいて遊脚期と立脚期との間の移行タイミングを判断する請求項1に記載の脚相移行タイミング判定方法。
- 前記歩行情報取得ステップは、さらに、前記センサの出力を受け付けて、前記人体の基準部位に対する足先の相対位置を連続的に算出し、
前記脚状態判断ステップは、さらに、前記足先の相対位置が正か負かに基づいて前記遊脚期から前記期立脚期への移行タイミングか、前記立脚期から前記遊脚期への移行タイミングかを判断する請求項13又は14に記載の脚相移行タイミング判定方法。 - 人体の脚に装着され、膝を屈伸する方向に対する剛性が変更可能な可変剛性機構を備えた歩行支援装具に対する歩行支援制御方法において、
前記脚の動きを検出するセンサの出力を受け付けて人体の基準部位に対する足先の相対速度を連続的に算出する歩行情報取得ステップと、
前記歩行情報取得ステップで算出された前記足先の相対速度に基づいて遊脚期と立脚期との間の移行タイミングを判断する脚状態判断ステップと、
前記遊脚期から立脚期への移行タイミングでは前記可変剛性機構の剛性を高め、前記立脚期から遊脚期への移行タイミングでは前記可変剛性機構の剛性を下げる剛性制御ステップとを備えた歩行支援制御方法。
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