JP4291602B2 - Robot walking using passive change of joint angle and its control method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a robot in which two or more leg links are connected to a trunk by a hip joint so as to be swingable, and the robot walks by swinging the leg links.
[0002]
[Prior art]
Robots that walk by changing the relative postures of the left leg link, the waist, and the right leg link have been developed. When the relative postures of the left leg link, the waist, and the right leg link are changed, the relative postures of the left leg link, the waist, and the right leg link must be changed so that a result of walking is obtained as a result. For this purpose, gait data that indicates the positions and postures of the left toe, waist, and right toe is used.
As shown in FIG. 11, the gait data indicates the positions and postures of the left foot, waist and right foot in a global coordinate system that defines the coordinates of the space in which the robot is active. In order to indicate the positions of the left toe, waist and right toe, a reference point L0 is defined for the left foot, a reference point R0 is defined for the right foot, and a reference point W0 is defined for the waist. ing. In order to indicate the posture of the left toe, waist and right foot, a vector L perpendicular to the left foot is assumed, a vector R perpendicular to the right foot is assumed, and a vector W extending along the waist pillar is Assumed. Gait data is the x, y, z coordinates of the reference point L0 of the left foot tip, the x, y, z coordinates of the reference point R0 of the right foot tip, and the x, y, z coordinates of the waist reference point W0 in the global coordinate system. Instruct. Also, the pitch angle Lα, roll angle Lβ, and yaw angle Lγ of the vector L perpendicular to the left foot tip are designated, and the pitch angle Rα, roll angle Rβ, and yaw angle Rγ of the vector R perpendicular to the right foot tip are designated. Then, the pitch angle Wα, roll angle Wβ, and yaw angle Wγ of the vector W extending along the waist column are indicated. The gait data stores data indicating the position and posture of the left foottip, waist, and right foottip over time.
[0003]
Given gait data that indicates the position and posture of the left toe, waist, and right foot, the robot calculates the joint angles required to take the given position and posture, and the calculated joint angles Adjust to. Since the gait data changes over time, the joint angle can also change over time. The robot walks by changing the relative postures of the left leg link, the waist and the right leg link over time according to the gait data.
Since the waist position (Wx, Wy, Wz) and posture (Wα, Wβ, Wγ) are set to maintain the ZMP (zero moment point) of the robot within the foot of the grounded leg, the robot falls Do not continue walking.
The above system can be said to be a system in which all joints of the robot are actively moved to walk, and is described in Patent Document 1 and the like.
[0004]
[Patent Document 1]
Japanese Patent Laid-Open No. 05-253867
[0005]
[Problems to be solved by the invention]
Unnaturalness is felt in the gait motion of a robot that walks by actively moving all the joints involved in walking. In order to stop a walking robot, it is necessary to stop it by a program, and it is difficult for a person to reach out and stop the robot.
[0006]
[Means and Actions for Solving the Problems]
The present inventors have conceived of utilizing the phenomenon of passive rocking by making the ankle joint free. Instead of actively swinging, the phenomenon of swinging naturally due to the removal of force is used. Compared to the intentionally actively swinging phenomenon, the naturally passively swinging phenomenon has no unnaturalness, and a natural gait motion adapted to the dynamics of the robot can be obtained. In addition, since it is a phenomenon that naturally swings passively, it can stop swinging when a person reaches out to the robot, and the robot can stop walking. Furthermore, it has been found that the energy required for walking can be saved by walking using the phenomenon of naturally passively swinging.
[0007]
In the robot of the present invention, a leg link having an ankle joint is slidably connected to the trunk by a hip joint, and there are two or more leg links. The machine configuration itself is known, but its controller is new and innovative. The controller of the present invention
(1) Freely swing the ankle joint of the grounding leg link,
(2) Measure the joint angle of the joint that is free to swing,
(3) Calculate the remaining joint angle based on the measured joint angle,
(4) Control the actuator that adjusts the remaining joint angle, adjust the remaining joint angle to the calculated joint angle,
(5) By switching the ankle joint that can swing freely according to the progress of the repetitive phenomenon that the tip of the leg link touches, floats and touches again, the swinging ankle joint is moved to the grounded leg link side. It is characterized by maintaining.
[0008]
In this robot, the grounding leg link itself tends to fall down passively in order to make the ankle joint of the grounding leg link freely swingable. At this time, other joint angles are actively adjusted, and control is performed so that the other leg link contacts the ground before the robot falls to prevent the fall. As the grounding legs are replaced, the robot advances. By repeating this, the robot continues walking while changing the grounding leg.
A natural walking motion can be obtained by walking by using movements that occur passively in nature. Since walking is performed using an action adapted to the dynamics of the robot, energy required for walking can be saved. When a person reaches out to the robot to stop passive movement, the robot stops. It is advantageous for coexistence of humans and robots, and can ensure high safety.
[0009]
In the case of a robot in which the left leg link and the right leg link are swingably connected to the torso by a hip joint, the controller uses the following relationship when calculating the remaining joint angle in the process of (3) above. It is preferable to calculate as follows. That is, the position of the center of gravity of the robot when the remaining joint angle is adjusted to the calculated joint angle,
(6) While the right leg link is a free leg link, it moves toward the grounding position of the right leg link between the grounding positions of the left and right leg links in the body side direction,
(7) While the left leg link is a free leg link, calculate the joint angle that satisfies the relationship of moving toward the grounding position of the left leg link between the grounding positions of the left and right leg links in the body side direction. .
[0010]
In this case, while the left leg link is grounded and the right leg link is a free leg link, the remaining joint angle is adjusted so that the center of gravity of the robot moves toward the grounded position of the right leg link. Therefore, the movement in which the ground leg passively swings and the movement in which the swing leg actively swings in the grounding direction are combined, and the robot walks with a natural feeling. Similarly, while the right leg link is grounded and the left leg link is a free leg link, the remaining joint angle is adjusted so that the center of gravity of the robot moves toward the grounded position of the left leg link. For this reason, the movement in which the ground leg passively swings and the movement in which the swing leg actively swings in the ground contact direction are obtained in combination.
[0011]
The controller
(8) Adjust the joint angle of the ankle joint and the hip joint in the traveling direction so that the hip joint is positioned forward in the traveling direction from the grounding position of the grounded leg link,
(9) If the ankle joint of the swing leg link and the joint angle in the travel direction of the hip joint are adjusted so that the tip of the free leg link is positioned forward in the travel direction relative to the hip joint,
The robot, while swinging alternately in the left and right directions, sends the trunk forward with respect to the grounding leg and sends the free leg forward with respect to the trunk. As a result, the robot walks forward.
[0012]
The present invention has created a novel and novel control method for a robot. This method
(1) a step of making the ankle joint of the grounding leg link freely swingable;
(2) a step of measuring the joint angle of the joint that is free to swing;
(3) calculating a residual joint angle based on the measured joint angle;
(4) adjusting the remaining joint angle to the calculated joint angle;
(5) By switching the ankle joint that can swing freely according to the progress of the repetitive phenomenon that the tip of the leg link touches, floats and touches again, the swinging ankle joint is moved to the grounded leg link side. Maintaining.
[0013]
According to this control method, the robot walks using the movement in which the ground leg link is passively tilted, a natural walking motion is obtained, and the energy required for walking can be saved. When a person reaches out to the robot and stops passive movement, the robot stops, which is advantageous for coexistence of the person and the robot.
[0014]
In the case of a robot in which the left leg link and the right leg link are swingably connected to the torso by a hip joint, the remaining joint angle is calculated using the following relationship when calculating the remaining joint angle in step (3) above. It is preferable to do. That is, when calculating the remaining joint angle based on the measured joint angle, the position of the center of gravity of the robot when adjusted to the calculated joint angle is (6) The right leg link is a free leg link Between, it moves toward the grounding position of the right leg link between the grounding positions in the body side direction of the left and right leg links,
(7) While the left leg link is a free leg link, calculate the joint angle that satisfies the relationship of moving toward the grounding position of the left leg link between the grounding positions of the left and right leg links in the body side direction. .
[0015]
According to this control method, while the left leg link is grounded and the right leg link is a free leg link, the remaining joint angle is set so that the center of gravity of the robot moves toward the grounded position of the right leg link. Since the adjustment is made, the movement in which the ground leg passively swings and the movement in which the swing leg actively swings in the ground contact direction are obtained in combination. Similarly, while the right leg link is grounded and the left leg link is a free leg link, the remaining joint angle is adjusted so that the center of gravity of the robot moves toward the grounded position of the left leg link. For this reason, the movement in which the ground leg passively swings and the movement in which the swing leg actively swings in the ground contact direction are obtained in combination. The robot walks with a natural feeling.
[0016]
When calculating the remaining joint angle in the process (3), it is preferable to calculate using the following relationship. That is, when calculating the remaining joint angle based on the measured joint angle, the position of the center of gravity of the robot when adjusted to the calculated joint angle is
(8) While the right leg link is a free leg link, the right leg link is grounded in the traveling direction at the same time as it moves toward the grounding position of the right leg link between the grounding positions of the left and right leg links in the body side direction. Move towards the position,
(9) While the left leg link is a free leg link, it moves toward the ground contact position of the left leg link between the ground contact positions of the left and right leg links in the body side direction, and at the same time the ground contact of the left leg link also in the traveling direction Calculate the joint angle that satisfies the relationship of moving toward the position.
[0017]
According to this control method, while the left leg link is grounded and the right leg link is a free leg link in both the body side direction and the traveling direction, the position of the center of gravity of the robot is directed toward the grounded position of the right leg link. The remaining joint angle is adjusted to move, and while the right leg link is grounded and the left leg link is a free leg link, the center of gravity position of the robot moves toward the grounded position of the left leg link. Since the remaining joint angle is adjusted, the robot sends the trunk forward with respect to the grounding leg while swinging alternately in the left-right direction, and sends the free leg forward with respect to the trunk. As a result, the robot walks forward. The walking posture is natural and the energy required for walking is small. Further, the robot can be stopped when a person reaches out from the outside.
[0018]
【Example】
FIG. 1 shows a skeleton diagram of the mechanical configuration of the robot 21. The hip joint has 2 axes, the knee joint has 1 axis, the ankle joint has 2 axes, the shoulder joint has 2 axes, and the elbow joint has 1 axis. Each joint is provided with a motor with an encoder, the joint angle can be adjusted, and the joint angle can be measured. θ1 to θ10 indicate joint angles. Reference numerals 17 and 18 indicate force sensors, and 19 and 20 indicate photo sensors. The photosensors 19 and 20 detect whether the foot is grounded or floating.
FIG. 2 shows the configuration of the controller 22 of the robot, and inputs the outputs of the encoders 1 to 10, the outputs of the force sensors 17 and 18, and the outputs of the photosensors 19 and 20. The controller 22 instructs the motors 1 to 10 to determine the rotation angle.
[0019]
FIG. 3 is a front view of a walking robot. (1) shows a state where the robot is strung with a right foot, and (a) shows a state immediately before the left foot is grounded by tilting left from the state of (1). (2) shows a state where the left foot is grounded, (3) shows a state where the left foot is further tilted from the state of (2), and a state where the left foot is strung, and (4) is a state where the left foot is inclined from the state of (3). The right foot is in a grounded state, and (5) is a state in which the right foot is further tilted from the state of (4) and is strung on the right foot. (1) and (5) are in the same state, and are symmetrical with the state of (3), and (2) and (4) are symmetrical.
The robot 21 realizes an operation of stepping left and right by repeating the states (1), (2), (3), (4), and (1) of FIG.
[0020]
As shown in FIG. 2, the controller 22 has phase determination means 24 and switches the control content according to the determined phase. As shown in FIG. 3, the phases are the right leg support A phase from state (1) to (2), the left leg support B phase from state (2) to (3), and from state (3) ( It is divided into a left leg support A phase up to 4) and a right leg support B phase from states (4) to (5).
[0021]
FIG. 7 shows the temporal change of the joint angle θ9 of the joint in the body side direction of the right ankle of the robot 21 stepping left and right, and in the state (1), −α (this is the maximum joint angle of this joint). When rotating to kα (k is a constant equal to or less than 1), the left foot is grounded in the state of (2), + α (this is the maximum joint angle of this joint) in the state of (3), and rotating to −kα ( In the state of 4), the right foot is grounded, and in the state of (5), it becomes -α and returns to the state of (1).
FIG. 8 shows an example of the determination processing procedure by the phase determination means 24, and the phase is determined by the joint angle θ9 of the joint in the body side direction of the right ankle. If θ9 = α in step S2, it is determined that the left leg support phase A (step S4). If θ9 = −α in step S6, it is determined that it is the right leg support A phase (step S8). If θ9 is increasing and is greater than or equal to −α and less than kα, it is determined that the phase is the right leg support A phase (step S14). If θ9 is increasing and is greater than or equal to kα, it is determined that it is the left leg support B phase (step S16). If θ9 is decreasing and less than α and greater than −kα, it is determined that the left leg support phase A (step S20). If θ9 is decreasing and −kα or less, it is determined that it is the right leg support B phase (step S22).
This phase determination processing procedure is merely an example, and various other procedures are possible. The determination can also be made by utilizing the information of the force sensors 17, 18 and the photo sensors 19, 20.
[0022]
The controller 22 shown in FIG. 2 switches the control content according to the determination result of the phase determination means 24.
(1) of FIG. 2 shows the control content in a right leg support state. In the right leg support state, control is performed as follows.
(1) The motor of the joint (θ9 in this case) of the ankle of the grounding leg is free to rotate and left to rotate freely. Let the joint θ9 be a passive joint (free joint), and leave it to passively rotate. However, -α is the maximum joint angle of this joint and does not rotate any further.
(2) Measure passively rotating joint angle θ9.
(3) The joint angle (θ7 in this case) of the joint in the body side direction of the hip joint of the ground leg is calculated from the measured joint angle θ9. This calculation will be described later.
(4) The joint angle (θ2 in this case) of the hip-joint of the free leg is set equal to −θ7. As a result, the ground leg link and the free leg link are maintained in parallel.
(5) The joint angle of the ankle joint of the free leg in the body side direction (θ4 in this case) is made equal to θ9. As a result, the foot of the ground leg and the foot of the free leg are maintained in parallel.
(6) For the knee joints (θ3 and θ8), keep the knee at an angle that extends straight (here it is zero).
(7) The joint angle (θ10 in this case) of the joint in the direction of travel of the ankle joint of the ground leg is calculated from the measured joint angle θ9. This calculation will be described later. Thereby, the position of the hip joint is sent forward in the traveling direction with respect to the ground contact position of the ground leg.
(8) The joint angle (θ6 in this case) in the advancing direction of the hip joint of the ground leg is made equal to −θ10. The body part is prevented from falling down.
(9) The joint angle (θ1 in this case) in the advancing direction of the hip joint of the free leg is made equal to θ10. Thereby, the free leg is stepped forward in the traveling direction.
(10) The joint angle (θ5 in this case) of the ankle joint of the free leg in the traveling direction is made equal to −θ10. Thereby, the foot of the free leg and the foot of the grounding leg are maintained in parallel.
[0023]
(2) of FIG. 2 shows the control content in the left leg support state. In the left leg support state, control is performed as follows.
(1) The motor of the body side joint (in this case θ4) of the ankle of the grounding leg is free to rotate and left to rotate freely. Let the joint θ4 be a passive joint (free joint), and leave it to passively rotate. However, α is the maximum joint angle of this joint and does not rotate beyond that.
(2) Measure passively rotating joint angle θ4.
(3) The joint angle (θ2 in this case) of the joint in the body side direction of the hip joint of the ground leg is calculated from the measured joint angle θ4. This calculation will be described later.
(4) The joint angle (in this case, θ7) of the hip-joint of the free leg is set equal to −θ2. As a result, the ground leg link and the free leg link are maintained in parallel.
(5) The joint angle of the ankle joint of the free leg in the body side direction (θ9 in this case) is made equal to θ4. As a result, the foot of the ground leg and the foot of the free leg are maintained in parallel.
(6) For the knee joints (θ3 and θ8), keep the knee at an angle that extends straight (here it is zero).
(7) Based on the measured joint angle θ4, the joint angle of the joint in the advancing direction of the ankle joint of the ground leg (in this case, θ5) is calculated. This calculation will be described later. Thereby, the position of the hip joint is sent forward in the traveling direction with respect to the ground contact position of the ground leg.
(8) The joint angle (θ1 in this case) of the grounded leg in the advancing direction of the hip joint is made equal to −θ5. The body part is prevented from falling down.
(9) The joint angle (θ6 in this case) of the free leg's hip joint is set equal to θ5. Thereby, the free leg is stepped forward in the traveling direction.
(10) The joint angle (θ10 in this case) in the advancing direction of the ankle joint of the free leg is made equal to −θ5. Thereby, the foot of the free leg and the foot of the grounding leg are maintained in parallel.
As shown in FIG. 2, the robot controller 22 includes phase determining means 24, and depending on the determined phase, either the motor 4 or the motor 9 is free (26), and the joint rotation angle (free) θ4 or θ9) is measured (28), the joint angle of the other motor is calculated based on the measured joint angle (30), and the joint angle of the other motor is adjusted to the calculated angle (34). When calculating the joint angles of other motors, a center-of-gravity transition model 32 described below is used.
[0024]
As shown in FIG. 4, when the right foot is stretched and maintained at θ9 = −α in the state (1), the center of gravity of the robot is at the position W1. Here, the center of gravity position W is assumed to be at the center of the left and right hip joints, but it may be located on the trunk. If θ9 is kα when tilted left from state (1) and the left foot touches the ground, the center of gravity of the robot when θ9 = kα is at the position W2.
In state (1) and thereafter, that is, in the right leg support phase A, the center of gravity position changes in accordance with the joint angle θ9 to be freed, the center of gravity position is W1 at θ9 = −α, and the center of gravity position changes as the robot tilts to the left. If the center of gravity moves from W1 to W2 and the center of gravity position is θ2 when θ9 = kα, the state (1) changes to the state 2.
The position of the center of gravity of the lateral surface of the robot is determined by θ2, θ4, θ7, and θ9. In the right leg support state, θ9 is free (measurable but not actively controlled), θ4 is equal to θ9, θ2 is equal to −θ7, and θ7 is calculated by θ9. In calculating θ9 to θ7, the center of gravity position of the robot when the posture of the robot is adjusted using the calculated θ7 is the center of gravity position when θ9 = −α is W1, and the center of gravity is as the robot tilts to the left If the position moves from W1 to W2 and the position of the center of gravity when θ9 = kα is at W2, the robot changes from state (1) to state (2).
The center-of-gravity position W1 when θ9 = −α is to the left of the ground contact position of the right leg, and does not tilt to the right beyond that. The robot never falls to the right. The center of gravity position W1 is on the left side of the ground contact position of the right leg, and tilts to the left if the joint θ9 is free.
[0025]
The equation (A) in FIG. 5 shows an equation for calculating θ9 to θ7. If θ7 is calculated using the equation and adjusted to the calculated joint angle θ7, the center of gravity position of the robot is θ9 = −α. At W1, the robot moves from W1 to W2 as the robot tilts to the left, and a relationship of moving to W2 when θ9 = kα is obtained.
[0026]
FIG. 4 also shows the transition of the center of gravity position from the state (2) to the state (3), and the center of gravity position when the left foot is stretched and maintained at θ4 = α is indicated by W3. The robot changes from state (2) to state (3) by controlling θ2, θ7, and θ9 following the change of θ4 so that the center of gravity is positioned at W3 in state (3).
In the left leg support B layer, θ2 is calculated from θ4 and controlled to θ7 = −θ2 and θ9 = θ4. The center of gravity of the robot is at W2 when θ4 = −kα, and W2 as the robot tilts to the left. If the relation of moving to W3 when θ4 = α is obtained, the robot changes from state (2) to state (3). Also in this case, θ2 can be calculated from θ4 by an expression similar to the expression (A) in FIG.
The center-of-gravity position W3 when θ4 = α is in the right direction from the ground contact position of the left leg, and does not tilt to the left beyond that. The robot never falls to the left. The center of gravity position W3 is on the right side of the ground contact position of the left leg, and tilts to the right if the joint θ4 is free.
[0027]
FIG. 4 also shows the transition of the center of gravity position from state (3) to state (4). If the center of gravity position is W4 when the robot tilts to the right, θ4 is −kα and the right foot is grounded, The robot changes from state (3) to state (4).
Similarly, the transition of the center of gravity position from state (4) to state (1) is also shown. If the center of gravity position when the robot is further tilted to the right and θ9 is straddled by −α is at the position W1, the robot The state (4) changes to the state (1).
[0028]
The center-of-gravity position is between W1 and W3, but it exists at L during the ground contact position in the body side direction of the left and right leg links. The center of gravity position while the left leg link is a free leg link moves toward the ground contact position of the left leg link, and the center of gravity position while the right leg link is a free leg link is the ground contact position of the right leg link. Move towards position.
In the right leg support A phase from the state (1) to the state (2), the phenomenon progresses naturally because the position of the center of gravity is lowered. In the left leg support phase B from state (2) to (3), the center of gravity increases, but the robot is tilting leftward from state (1) to (2), and its inertia exists, so the center of gravity position exists. The phenomenon of rising naturally proceeds. Similarly, in the left leg support A phase from the state (3) to the state (4), the phenomenon progresses naturally because the center of gravity is lowered. In the right leg support B phase from state (4) to (1), the center of gravity increases, but the robot is tilting rightward from state (3) to (4) and its inertia exists, so the center of gravity position is Ascending phenomenon proceeds naturally.
[0029]
The repetitive motions of states (1) to (4) are similar to the fact that the triangular prism repeats the pendulum motion on the floor having a coefficient of restitution coefficient of 1, and can continue the motion with a small amount of energy. If there is no friction of the swingable or rotatable joint, the repeated motions of the states (1) to (4) are repeated without being attenuated. In fact, there is friction. By applying a torque sufficient to cancel the friction to the rotatable joint motor, a state in which no friction exists can be created. In the present invention, making the joint free means not only to allow passive rotation without applying current to the motor, but also by substantially applying friction to cancel the friction. Say both not to state.
[0030]
The repetitive motions of the states (1) to (4) realize the stepping motion of the left and right legs. The robot advances when a stepping step is added in synchronization with the stepping motion of the left and right legs. At this time, since the left and right tilt is used, the free leg moves in the air without bending the knee of the free leg.
Formula B in FIG. 5 shows the joint angle (in this case, θ10) of the joint in the advancing direction of the ankle of the grounding leg during the right leg grounding. In this case, the joint angle θ6 of the hip joint of the ground leg is set to −θ10, the joint angle θ1 of the hip joint of the swing leg is set to θ10, and the joint angle of the joint of the free leg ankle is set to θ10. If θ5 is −θ10, the hip joint is positioned forward in the traveling direction with respect to the grounding position of the grounding leg by θ10, the trunk tilt is prohibited by θ6, and the free leg link is stepped forward by θ1 with respect to the hip joint, The foot of the grounding leg and the foot of the free leg are maintained in parallel by θ5. The lower part of FIG. 6 shows this, and the robot walks by alternately stepping on the left and right legs. The left and right stepping motion and the forward stepping motion are combined, and the robot walks with a natural feeling.
[0031]
In the above, the joint angle θ4 or θ9 in the body side direction of the ankle of the grounding leg is made free, and the joint angles of the remaining joints are controlled following the change. As a result, the left and right stepping motion and the forward stepping motion are combined.
Alternatively, the joint angle θ5 or θ10 in the advancing direction of the ankle of the ground leg can be made free, and the joint angles of the remaining joints can be controlled following the change. Even in this way, it is possible to obtain an operation in which the left and right stepping motions and the forward stepping motion are combined. In this case, for the advancing direction, the remaining joint angle is actively controlled based on the free joint angle θ5 or θ10 so that the center of gravity of the robot shifts forward. As for the body side direction, the center of gravity of the robot shifts to the left while the right leg is grounded, and the center of gravity of the robot shifts to the right while the left leg is grounded, based on the free joint angle θ5 or θ10. Actively control the remaining joint angles. Both the joint angle in the body side direction and the joint angle in the traveling direction of the ankle of the ground leg may be free. In synchronism with the replacement of the grounding leg, the state where the joint angles θ4 and θ5 are made free and the state where the angles θ9 and θ10 are made free are switched. In this case, in the right leg support phase, θ9 and θ10 are made free (however, the absolute value of θ9 is regulated by α, and the absolute value of θ10 is regulated by β). The remaining joints θ7, θ2, and θ4 in the body side direction are actively controlled based on the measured joint angle θ9, and the remaining joints θ6, θ1, and θ5 in the traveling direction are based on the measured joint angle θ10. Active control. In the left leg support phase, θ4 and θ5 are set free (however, the absolute value of θ4 is regulated by α and the absolute value of θ5 is regulated by β). The remaining joints θ2, θ7, and θ9 in the body side direction are actively controlled based on the measured joint angle θ4, and the remaining joints θ1, θ6, and θ10 in the traveling direction are based on the measured joint angle θ5. Active control. In any case, active control is performed so as to maintain the relationships of θ9 = θ4, θ7 = −θ2, θ6 = −θ1, and θ10 = −θ5. Regarding the advancing direction, the remaining joint angle is actively controlled based on the free joint angle θ5 or θ10 so that the center of gravity of the robot shifts forward. As for the body side direction, the center of gravity of the robot is shifted to the left while the right leg is grounded, and the center of gravity of the robot is shifted to the right while the left leg is grounded, based on the free joint angle θ4 or θ9. Actively control the remaining joint angles. When calculating the remaining joint angle based on the measured joint angle, the position of the center of gravity of the robot when adjusted to the calculated joint angle is the right and left leg while the right leg link is a free leg link. While moving toward the ground contact position of the right leg link between the ground contact positions in the body side direction of the link, it also moves toward the ground contact position of the right leg link in the traveling direction and the left leg link is a free leg link. Calculate the joint angle that satisfies the relationship of moving toward the grounding position of the left leg link in the traveling direction at the same time as moving to the grounding position of the left leg link between the grounding positions of the left and right leg links in the body side direction. The robot is confirmed to continue walking.
[0032]
The change locus of the center of gravity can be set in various ways, and as shown in FIG. 9, a smooth curved locus can be adopted. The inclination angle at the time of contact, that is, the magnitude of the constant k described above should be tuned by experiment, and if there is a robot that is preferably set small as shown in the center of gravity locus of (1) in FIG. There are also robots that are preferably set large as in 2).
[0033]
Although specific examples of the present invention have been described in detail above, these are examples and do not limit the scope of the claims. In addition, the present invention solves several objects, and is not meaningful only when all the objects are solved at the same time, and is sufficiently meaningful only by solving one or two objects. .
[0034]
【The invention's effect】
According to the robot control technology of the present invention, it is possible to walk using an event that changes passively and naturally. This closely matches the human walking pattern, and a natural gait movement can be obtained. In addition, it is adaptable to the robot dynamics, and can walk with small energy consumption. Furthermore, since it walks using the phenomenon which changes passively and naturally, if a human stops the change, the robot stops the walking motion. Since the robot stops when the person reaches out, it is easy for the person and the robot to coexist and high safety can be ensured.
[Brief description of the drawings]
FIG. 1 is a skeleton diagram showing a mechanical configuration of a robot.
FIG. 2 is a diagram showing a configuration of a robot controller.
FIG. 3 shows the left and right stepping motions, phases, and control contents of the robot in contrast.
FIG. 4 shows the movement locus of the center of gravity position.
FIG. 5 shows a method of calculating a joint angle that realizes the movement locus of the center of gravity.
FIG. 6 shows the left and right stepping motion of the robot in contrast to the stepping motion.
FIG. 7 shows a temporal change in the joint angle θ9.
FIG. 8 shows an example of a phase discrimination processing procedure.
FIG. 9 shows another example of the center of gravity movement locus.
FIG. 10 shows another example of the center of gravity movement locus.
FIG. 11 shows a conventional robot teaching technique.
[Explanation of symbols]
θ1: Joint in the direction of travel of the left hip joint
θ2: Joint in the body direction of the left hip joint
θ3: Knee joint
θ4: joints in the body side direction of the left ankle
θ5: Left ankle joint in the direction of travel
θ6: Joint in the direction of travel of the right hip joint
θ7: Body side direction of the right hip joint
θ8: Knee joint
θ9: Body side direction joint of right ankle
θ10: joint in the direction of travel of the right ankle

Claims (6)

A leg link having an ankle joint is slidably connected to the trunk by a hip joint, and there are two or more leg links, and the following controller,
The ankle joint of the grounding leg link can swing freely,
Measure the joint angle of the joint that is free to swing,
Calculate the remaining joint angle based on the measured joint angle,
Control the actuator to adjust the remaining joint angle, adjust the remaining joint angle to the calculated joint angle,
Maintaining the ankle joint to be free to swing on the side of the grounded leg link by switching the ankle joint to be free to swing in accordance with the progress of a repetitive phenomenon where the tip of the leg link is grounded, floated and grounded again.
A robot having a controller and walking using passive changes in joint angles. It is a robot in which a left leg link having an ankle joint and a right leg link are swingably connected to a trunk by a hip joint, and the following controller,
The ankle joint of the grounding leg link can swing freely,
Measure the joint angle of the joint that is free to swing,
Calculate the remaining joint angle based on the measured joint angle,
Control the actuator to adjust the remaining joint angle, adjust the remaining joint angle to the calculated joint angle,
Maintaining the ankle joint to be free to swing on the side of the grounded leg link by switching the ankle joint to be free to swing in accordance with the progress of a repetitive phenomenon where the tip of the leg link is grounded, floated and grounded again.
Have a controller,
When calculating the remaining joint angle based on the measured joint angle, the position of the center of gravity of the robot when adjusted to the calculated joint angle is the right and left leg while the right leg link is a free leg link. It moves toward the contact position of the right leg link between the contact positions in the body side direction of the link, and while the left leg link is a free leg link, between the contact positions of the left and right leg links in the body side direction. A robot that uses a passive change in joint angle to calculate a joint angle that satisfies the relationship of moving toward the ground contact position of the left leg link. The controller adjusts the joint angle of the ankle joint of the ground leg link and the forward direction of the hip joint so that the hip joint is positioned in the forward direction of the ground leg position of the ground leg link, and the tip of the free leg link is positioned more than the hip joint. 3. The robot according to claim 2, wherein the joint angle in the traveling direction of the ankle joint and the hip joint of the free leg link is adjusted so as to be positioned forward in the traveling direction. A leg link having an ankle joint is slidably connected to a trunk by a hip joint, and there are two or more leg links.
Making the ankle joint of the ground leg link free to swing;
Measuring the joint angle of the joint that is free to swing;
Calculating a residual joint angle based on the measured joint angle;
Adjusting the remaining joint angle to the calculated joint angle;
The step of maintaining the ankle joint to be free to swing on the side of the grounded leg link by switching the ankle joint to be freely swingable in accordance with the progress of a repetitive phenomenon in which the tip of the leg link is grounded, floated and grounded again. When,
A method of controlling a robot having It is a control method for a robot in which a left leg link and an right leg link having an ankle joint are swingably connected to a trunk by a hip joint,
Making the ankle joint of the ground leg link free to swing;
Measuring the joint angle of the joint that is free to swing;
Calculating a residual joint angle based on the measured joint angle;
Adjusting the remaining joint angle to the calculated joint angle;
The step of maintaining the ankle joint to be free to swing on the side of the grounded leg link by switching the ankle joint to be freely swingable in accordance with the progress of a repetitive phenomenon in which the tip of the leg link is grounded, floated and grounded again. And
When calculating the remaining joint angle based on the measured joint angle, the position of the center of gravity of the robot when adjusted to the calculated joint angle is the right and left leg while the right leg link is a free leg link. It moves toward the contact position of the right leg link between the contact positions in the body side direction of the link, and while the left leg link is a free leg link, between the contact positions of the left and right leg links in the body side direction. A robot control method characterized by calculating a joint angle satisfying a relationship of moving toward a ground contact position of a left leg link. It is a control method for a robot in which a left leg link and an right leg link having an ankle joint are swingably connected to a trunk by a hip joint,
Making the ankle joint of the grounding leg link freely swingable in the direction of travel;
Measuring the joint angle of the joint that is free to swing;
Calculating a residual joint angle based on the measured joint angle;
Adjusting the remaining joint angle to the calculated joint angle;
The step of maintaining the ankle joint to be free to swing on the side of the grounded leg link by switching the ankle joint to be freely swingable in accordance with the progress of a repetitive phenomenon in which the tip of the leg link is grounded, floated and grounded again. And
When calculating the remaining joint angle based on the measured joint angle, the position of the center of gravity of the robot when adjusted to the calculated joint angle is the right and left leg while the right leg link is a free leg link. While moving toward the ground contact position of the right leg link between the ground contact positions in the body side direction of the link, it also moves toward the ground contact position of the right leg link in the traveling direction and the left leg link is a free leg link. Calculate the joint angle that satisfies the relationship of moving toward the grounding position of the left leg link in the traveling direction at the same time between the grounding positions of the left and right leg links in the body side direction. A robot control method characterized by the above.

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