Robot, robot control apparatus and robot system

What is claimed is: 1 . A robot comprising: a force detector; and a drive part that changes a position relationship between a marker and an imaging part, wherein, in the case with calibration processing of specifying a coordinate relationship as a correspondence relationship between a reference coordinate system with reference to a position of the marker and a robot coordinate system as reference of control of the drive part based on images of the marker captured by the imaging part in a plurality of the position relationships, the drive part is controlled to have anisotropy based on the coordinate relationship and a detection value of the force detector. 2 . The robot according to claim 1 , further comprising the imaging part. 3 . The robot according to claim 1 , wherein, in the case with the calibration processing, the drive part is controlled so that ease of movement of a moving point movable by the drive part may be larger in a second direction in the reference coordinate system than that in a first direction in the reference coordinate system. 4 . The robot according to claim 1 , wherein the drive part is controlled so that mechanical impedance realized by the drive part may be larger in a second direction in the reference coordinate system than that in a first direction in the reference coordinate system. 5 . The robot according to claim 3 , wherein the second directions are two directions on a single plane in the reference coordinate system, and the first direction is a direction orthogonal to the single plane in the reference coordinate system. 6 . The robot according to claim 3 , wherein the second direction is a direction along a single axis in the reference coordinate system, and the first directions are two directions on a plane orthogonal to the single axis in the reference coordinate system. 7 . The robot according to claim 3 , wherein at least one of the first direction and the second direction is a rotation direction about an axis in a predetermined direction in the reference coordinate system. 8 . The robot according to claim 1 , wherein, in a teaching work in which an operator moves a robot and teaches an action of the robot, the drive part is controlled to have anisotropy. 9 . The robot according to claim 1 , wherein, when an object is fitted in a fitting hole, the drive part is controlled to have anisotropy in a fitting direction in the reference coordinate system and another direction than the fitting direction. 10 . The robot according to claim 9 , wherein the markers are provided in a plurality of positions within a predetermined distance from the fitting hole. 11 . A robot control apparatus that controls a robot including a force detector, and a drive part that changes a position relationship between a marker and an imaging part, comprising: a calibration unit that performs calibration processing of specifying a coordinate relationship as a correspondence relationship between a reference coordinate system with reference to a position of the marker and a robot coordinate system as reference of control of the drive part based on images of the marker captured by the imaging part in a plurality of the position relationships; and a control unit that controls the drive part to have anisotropy based on the coordinate relationship and a detection value of the force detector in the case with the calibration processing. 12 . The robot control apparatus according to claim 11 , wherein the robot includes a user interface unit that, in a teaching work in which an operator moves a robot and teaches an action of the robot, controls the drive part to have anisotropy, receives designation as to whether or not to control the drive part to have anisotropy in the teaching work, and, in the case with the calibration processing, permits designation of control of the drive part to have anisotropy in the teaching work. 13 . The robot control apparatus according to claim 12 , wherein the user interface unit informs the operator of a requirement of the calibration processing for control of the drive part to have anisotropy in the teaching work. 14 . The robot control apparatus according to claim 12 , wherein the user interface unit informs the operator of a direction in which anisotropy is provided with reference to the position of the marker. 15 . A robot system comprising: a robot including a force detector and a drive part; an imaging part having a position relationship with a marker when driven by the drive part; a calibration unit that performs calibration processing of specifying a coordinate relationship as a correspondence relationship between a reference coordinate system with reference to a position of the marker and a robot coordinate system as reference of control of the drive part based on images of the marker captured by the imaging part in a plurality of the position relationships; and a control unit that controls the drive part to have anisotropy based on the coordinate relationship and a detection value of the force detector.