Controller for mobile robot

What is claimed is: 1. A controller for a mobile robot, which has a plurality of links which include a link constituting a base body and links constituting a plurality of leg link mechanisms extended from the base body and which are interconnected through a plurality of joints, and joint actuators for driving each of the joints, the controller being adapted to have the mobile robot travel by controlling driving forces to be imparted by the joint actuators to each of the joints for operating the leg link mechanisms according to a force control method, and the controller comprising at least one processor and a memory on which is installed a program which, when executed by the at least one processor, causes the controller to function as: a link position and attitude estimating unit configured to sequentially acquire input parameters, which at least include at least one of a desired attitude of a ground contact link of at least one leg link mechanism including the ground contact link that is in contact with a ground among the leg link mechanisms and an observation value of an actual attitude of a first particular link determined in advance among the plurality of links of the mobile robot, a desired position of the ground contact link, and an observation value of an actual displacement amount of each joint between the ground contact link and the first particular link, and to sequentially estimate the actual position and attitude of the first particular link by carrying out processing, which includes at least forward kinematics arithmetic processing, by using the input parameters; and a joint driving force control unit configured to adjust, through the joint actuators, a driving force to be imparted to each of the joints for operating the leg link mechanisms based on at least either one of a difference between estimated values of the actual position and attitude of the first particular link obtained by the link position and attitude estimating unit and desired position and attitude of the first particular link or a difference between estimated values of actual position and attitude of a second particular link, which is different from the first particular link and which is not in contact with a ground, among the plurality of links of the mobile robot, which are estimated values of the actual position and attitude of the second particular link calculated by forward kinematics arithmetic processing based on the estimated values of the actual position and attitude of the first particular link and an observation value of a displacement amount of each joint between the first particular link and the second particular link, and desired position and attitude of the second particular link, such that the difference is reduced. 2. The controller for the mobile robot according to claim 1 , wherein the second particular link is a link of a distal end portion of each of the leg link mechanisms, the link position and attitude estimating unit is configured to sequentially estimate the actual position and attitude of the first particular link and also to sequentially estimate actual position and attitude of the link of the distal end portion by forward kinematics arithmetic processing from the estimated values of the actual position and attitude of the first particular link and an observation value of a displacement amount of each joint between the first particular link and the link of the distal end portion while the link of the distal end portion is moving in air in a travel motion of the mobile robot, and the joint driving force control unit is configured to adjust, through the joint actuators, the driving force to be imparted to each of the joints for operating the leg link mechanisms based on at least a difference between the estimated values of the actual position and attitude of the link of the distal end portion and a desired position and attitude of the link of the distal end portion such that the difference is reduced while the link of the distal end portion is moving in the air in the travel motion of the mobile robot. 3. The controller for the mobile robot according to claim 1 , wherein the input parameters include the observation value of the actual attitude of the first particular link, and the link position and attitude estimating unit is configured to carry out, at a time of determining a new estimated value of the actual position of the first particular link, first processing in which forward kinematics arithmetic processing is carried out based on a current value of the observation value of the actual attitude of the first particular link, a latest value among the estimated values of the actual position of the first particular link determined in the past, and a current value of the observation value of the actual displacement amount of each joint between the ground contact link and the first particular link thereby to calculate a temporary value of a position of the ground contact link in a case where it is assumed that an actual current position of the first particular link agrees with the latest value, and second processing of determining a new estimated value of the actual position of the first particular link by correcting the latest value based on a difference between the temporary value of the position of the ground contact link and the desired position of the ground contact link, and to define the observation value of the actual attitude of the first particular link as the estimated value of the actual attitude. 4. The controller for the mobile robot according to claim 3 , wherein the input parameters further include an observation value of an actual load acting on the ground contact link, and the link position and attitude estimating unit is configured to further carry out third processing of estimating an amount of an elastic deformation of the ground contact link by using the observation value of the actual load and fourth processing of correcting the temporary value of the position of the ground contact link calculated by the first processing based on an estimated value of the amount of the elastic deformation, and to correct the latest value based on a difference between a corrected value of the temporary value of the position of the ground contact link obtained by the fourth processing and the desired position of the ground contact link in place of a difference between the temporary value of the position of the ground contact link and the desired position of the ground contact link in the second processing, thereby determining a new estimated value of the actual position of the first particular link. 5. The controller for the mobile robot according to claim 4 , wherein the link position and attitude estimating unit is configured to carry out the first processing, the third processing, and the fourth processing for each ground contact link in a phase during which each of the plurality of the leg link mechanisms has the ground contact link in the travel motion of the mobile robot, and to determine a new estimated value of the actual position of the first particular link by averaging the estimated values of the actual position of the first particular link obtained for each ground contact link by correcting the latest value based on the difference between the corrected value of the temporary value of the position of each ground contact link and the desired position of the ground contact link or by subjecting the value, which has been calculated by the averaging process, to a low-pass characteristic filtering process in the second processing. 6. The controller for the mobile robot according to claim 3 , wherein the link position and attitude estimating unit is configured to carry out the first processing for each ground contact link in a phase during which each of the plurality of the leg link mechanisms