1. Field of the Invention
The present invention relates to a robot which autonomously travels.
2. Description of the Related Art
Hitherto, there has been proposed a technical method whereby motions of a robot that travels while moving an object is controlled. The motions of the robot are controlled such that the position of a representative point of the object, such as a cart, follows a desired positional trajectory and also the posture of the object follows a desired azimuth trajectory (refer to Japanese Patent Application Laid-Open No. 2007-160428).
However, for the robot to travel while smoothly moving the object, the robot is required to move the object without letting the object come in contact with the wall or the like of a hallway and also to keep itself from coming in contact with the wall or the like of the passage.
An object of the present invention is to provide a robot which is capable of traveling while moving an object such that the object and the robot itself remain in a predetermined area.
A robot according to a first aspect of the invention is equipped with a controller which controls the motions of the robot according to an action scheme when the robot travels while moving an object. The controller includes: a first processing element which recognizes a predicted position and a predicted azimuth in the future of the robot and the object, respectively, according to the action scheme and also recognizes a pathway area; a second processing element which determines, on the basis of the result of the recognition by the first processing element, whether a traveling requirement that the whole object and the whole robot remain within the pathway area in the future is met, and a third processing element which corrects the action scheme on condition that the second processing element has determined that the traveling requirement is not met.
According to the robot of the first aspect of the invention, if the traveling requirement that the robot and the object will remain within the pathway area is not met, then the action scheme of the robot is corrected to meet the traveling requirement. This enables the robot to travel while moving the object such that the object and the robot itself will remain within the pathway area according to the corrected action scheme.
In a robot according to a second aspect of the invention, the third processing element in the robot according to the first aspect of the invention corrects the action scheme of the robot so as to change the traveling direction of the robot.
According to the robot of the second aspect of the invention, the traveling direction of the robot defined by the action scheme before a correction is changed to the traveling direction defined by the corrected action scheme. This allows the robot to travel while moving the object such that the object and the robot itself will remain within the pathway area.
In the robot according to the second aspect of the invention, a robot according to a third aspect of the invention corrects the action scheme of the robot so as to reduce the traveling speed of the robot on condition that the second processing element determines whether changing the traveling direction of the robot satisfies the traveling requirement and that the third processing element determines that the traveling requirement will not be satisfied even after the traveling direction of the robot is changed.
According to the robot of the third aspect of the invention, the traveling speed of the robot is reduced if changing the traveling direction alone does not make it easy for the robot itself and the object to remain in the pathway area when the robot travels while moving the object after changing the traveling direction. Reducing the traveling speed of the robot allows the traveling direction to be changed more than in the case where the traveling speed is not changed. Thus, changing the traveling direction relatively significantly makes it possible to prevent the object and the robot from stepping out of the pathway area.
a) and
The following will describe an embodiment of a robot in accordance with the present invention with reference to the accompanying drawings.
A robot R illustrated in
The body 10 is constructed of an upper section and a lower section vertically connected such that they may relatively rotate about a yaw axis. The head 11 is capable of making a motion, such as moving about the yaw axis, with respect to the body 10. Each of the arms 12 has a first arm link 122 and a second arm link 124. The body 10 is connected with the first arm link 122 through the intermediary of a shoulder joint 121, and connected with the first arm link 122 and the second arm link 124 through the intermediary of an elbow joint 123. The second arm link 124 and the hand 13 are connected through the intermediary of a carpal joint 125. Each of the shoulder joints 121 has the freedom of rotation about a roll axis, a pitch axis, and the yaw axis, each of the elbow joints 123 has the freedom of rotation about the pitch axis, and the carpal joint 125 has the freedom of rotation about the roll axis, the pitch axis, and the yaw axis. A six-axis force sensor is provided in the vicinity of the carpal joint 125. Each of the legs 14 has a first leg link 142, a second leg link 144, and a foot 15. The body 10 and the first leg link 142 are connected through the intermediary of a hip joint 141, the first leg link 142 and the second leg link 144 are connected through the intermediary of a knee joint 143, and the second leg link 144 and the foot 15 are connected through the intermediary of a foot joint 145. The hip joint 141 has the freedom of rotation about the roll axis, the pitch axis and the yaw axis, the knee joint 143 has the freedom of rotation about the pitch axis, and the foot joint 145 has the freedom of rotation about the roll axis and the pitch axis. Each of the hands 13 is equipped with five finger mechanisms 131 to 135, which extend from the palm portion and which correspond to the thumb, the forefinger, the middle finger, the third finger, and the little finger, respectively, of a human hand. The finger mechanisms are disposed such that the first finger mechanism 131 opposes the four finger mechanisms 132 to 135, which are arranged side by side.
The first finger mechanism 131 has three link members corresponding to the first metacarpal bone and the proximal joint and the distal joint of the thumb of a human hand, and an elastic cover which covers the three link members. The three link members are connected through the intermediary of joints which correspond to the proximal joint of the first metacarpal bone, the metacarpophalangeal joint of the thumb and the interphalangeal joint of the thumb, respectively, of a human hand in this order from the palm side. The first finger mechanism 131 can be bent at each joint in response to forces transmitted from a motor accommodated in the palm portion through the intermediary of a motive power transmitting mechanism constructed of a speed reducer and the like. The motive power transmitted to the first finger mechanism 131 from the motor is controlled by the controller 20.
The finger mechanisms 132 to 135 have the same constructions as those of the finger mechanisms disclosed in, for example, Japanese Patent Application Laid-Open No. 2003-181787, and each of the finger mechanisms share substantially the same construction. For instance, the fifth finger mechanism 135 has three link members corresponding to the proximal joint, the middle joint, and the distal joint, respectively, of the little finger of a human hand, and an elastic cover which covers the three link members. The three link members are connected through the intermediary of joints corresponding to the metacarpophalangeal joint, the proximal interphalangeal joint, and the distal interphalangeal joint, respectively, of the little finger of a human hand in this order from the palm portion.
The fifth finger mechanism 135 can be bent inward at each joint in response to a motive power transmitted from a motor (not shown) serving as a motive power source through the intermediary of a motive power transmitting mechanism. As with the first finger mechanism 131, the motive power transmitted to the fifth finger mechanism 135 from the motor is controlled by the controller 20.
Of the finger mechanisms 131 to 135, a plurality of finger mechanisms may be driven by the same single motor, or each finger mechanism may be separately driven by a single motor, as with the first finger mechanism 131 in the present embodiment. Further, the motive power transmitting mechanism may be constructed of wires, pulleys or the like, as disclosed in the aforesaid Japanese Patent Application Laid-Open No. 2003-181787, or any other construction may be used as long as the construction is capable of transmitting the motive power of a motor to cause each finger mechanism to bend and stretch.
The controller 20, which is composed primarily of a CPU, a ROM, a RAM, and an I/O system, controls the action of the robot R by controlling the operation of actuators 1000 on the basis of output signals of a group of internal state sensors 101 and output signals of a group of external state sensors 102 according to an action scheme stored in a storage device. The internal state includes, for example, the position of a representative point, such as the center of gravity, of the robot R in a fixed coordinate system, the azimuth of a traveling direction of the robot R, a posture defined by the angles or the like of joints, such as the hip joint 141 and the knee joint 143, and forces acting on the robot R from outside via the hands 13.
The group of internal state sensors primarily includes a GPS receiver, which receives signals indicative of latitudes and longitudes defining the positions of the robot R, from an artificial satellite, a yaw rate sensor which outputs signals based on angular velocities about a Z-axis of the robot R, an acceleration sensor which outputs signals based on acceleration in an X-direction and the like of the robot R, a rotary encoder which outputs signals based on the angles of joints, and a six-axis force sensor which outputs signals based on forces acting on the hands 13 from outside.
The external state of the robot R includes, for example, the positions of a representative point of an object W in a fixed coordinate system or a robot coordinate system, the postures of the object W, and pathway areas defined by the walls or the like of hallways. The group of external state sensors includes primarily a pair of right and left head cameras C1, such as CCD cameras, infrared cameras or the like, which are installed in the head 11 to image the area ahead of the robot R and which are capable of sensing light in various frequency bands, and a waist camera C2 installed at a lower portion of the body 10 to measure the position, the azimuth and the like of an object by detecting the light ray of a near-infrared laser beam reflected from the object, the laser beam being emitted downward in front of the robot R (refer to
The controller 20 may be a distributed controller constructed of a main control unit and a single or a plurality of sub-control units connected through an internal network of the robot R. The controller 20 has a first processor 21, a second processor 22, and a third processor 23. The first processor 21 recognizes the predicted positions and the predicted azimuths of the robot R and the object W moved by the robot R in the future according to an action scheme, and also recognizes a pathway area. The second processor 22 determines whether a traveling requirement is met. The traveling requirement is that the whole object W and the whole robot R will remain within a pathway area in the future, and the determination is made on the basis of the recognition results provided by the first processor 21. The third processor 23 corrects the action scheme when the second processor 22 determines that the traveling requirement is not met.
The “recognition” of information by a constituent element in the present invention means to carry out any information processing required to prepare information for further information processing. Such information processing includes, for example, the retrieval of information from a database, reading information from a storage device, such as a memory, measuring, calculating, estimating or judging information on the basis of output signals of sensors and the like, and storing information obtained by measurement or the like in a memory by the constituent element.
The functions of the robot R having the aforesaid construction, more specifically, the functions for traveling while moving a cart W as an object will now be described. The position and the azimuth of the robot R in a fixed coordinate system are defined by the position of an origin (e.g., the center of gravity of the robot R) PR of a robot coordinate system (XR, YR, ZR) and the azimuth in a +XR direction (refer to
First, a flag fam indicative of the change history of the traveling direction of the robot R in an action scheme for the robot R is reset to zero (S001 in
The first processor 21 also recognizes the predicted position and the predicted azimuth in the future of the robot R on the basis of the traveling plan of the robot R (S004 in
Further, the first processor 21 recognizes the predicted position and the predicted posture of the cart W (S006 in
The first processor 21 further recognizes a pathway area (S008 in
Further, based on the recognition result supplied by the first processor 21, the second processor 22 determines whether the traveling requirement that the whole cart W and the whole robot R will remain within the pathway area in the future is met (S010 in
If it is determined that the flag fam is zero (YES in S012 of
Meanwhile, if it is determined that the flag fam is 1 rather than 0 (NO in S012 of
According to the robot R equipped with the aforesaid functions, if the traveling requirement that the robot R and the cart (object) W remain within a pathway area is not met, then the action scheme of the robot R is corrected so as to satisfy the traveling requirement (refer to S010, S014 and S018 in
Number | Date | Country | Kind |
---|---|---|---|
2007-318887 | Dec 2007 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5999865 | Bloomquist et al. | Dec 1999 | A |
6393362 | Burns | May 2002 | B1 |
6926374 | Dudeck et al. | Aug 2005 | B2 |
7076346 | Sturges et al. | Jul 2006 | B2 |
7603235 | Makela et al. | Oct 2009 | B2 |
7801644 | Bruemmer et al. | Sep 2010 | B2 |
7894939 | Zini et al. | Feb 2011 | B2 |
20040093650 | Martins et al. | May 2004 | A1 |
20060047390 | Scherl et al. | Mar 2006 | A1 |
20060111820 | Goetting et al. | May 2006 | A1 |
20100191421 | Nilsson | Jul 2010 | A1 |
Number | Date | Country |
---|---|---|
02-231609 | Sep 1990 | JP |
2007-160428 | Jun 2007 | JP |
Entry |
---|
Sakata et al., “Wheelchair User Support System Using Humanoid Robots” SICE Annual Conference in Sapporo, Aug. 4-6, 2004, pp. 1650-1655. |
Number | Date | Country | |
---|---|---|---|
20090149992 A1 | Jun 2009 | US |