Linear driving mechanism with self-weight compensation, operation input device, and surgery assistance system

The invention claimed is: 1. A linear driving mechanism with self-weight compensation comprising: a holding member that holds: a first moving body to which an object is attached; a second moving body provided with a weight; and a coupling portion that couples the first moving body to the second moving body so that the weight moves along a vector which includes a directional component in a direction opposite to a movement direction of the first moving body; wherein the holding member is capable of rotating around a rotation axis; and when a mass of the first moving body in a state where the object is attached is defined as M 1 , a mass of the second moving body is defined as M 2 , a distance between a first intersection point of a perpendicular line from a rotation center of the rotation axis to the first moving body and a first gravity center of the first moving body when the distance between the first intersection point and the first gravity center in the first moving body is the shortest is defined as L 1 , and a distance between a second intersection point of a perpendicular line from the rotation center of the rotation axis to the second moving body and a second gravity center of the second moving body when the distance between the second intersection point and the second gravity center in the second moving body is the shortest is defined as L 2 , M 2 =(L 1 /L 2 )×M 1 is satisfied. 2. The linear driving mechanism with self-weight compensation according to claim 1 , wherein the first moving body and the second moving body linearly move in directions that are parallel to each other and opposite to each other. 3. The linear driving mechanism with self-weight compensation described in claim 1 , wherein the first moving body has a first rack extending in a direction of a straight line connecting the first intersection point and the first gravity center in the first moving body, wherein the second moving body has a second rack extending in a direction of a straight line connecting the second intersection point and the second gravity center in the second moving body, and wherein the coupling portion has a gear unit that engages with the first rack and the second rack. 4. The linear driving mechanism with self-weight compensation described in claim 3 , wherein the gear unit has: a first gear that engages with the first rack; and a second gear that engages with the second rack, wherein when a first radius of the first gear is defined as d 1 and a second radius of the second gear is defined as d 2 , M 2 =(L 1 /L 2 )×M 1 =(d 1 /d 2 )×M 1 is satisfied. 5. The linear driving mechanism with self-weight compensation according to claim 1 , wherein the rotation center is positioned within a predetermined range from the gravity center of the holding member. 6. An operation input device comprising: the linear driving mechanism with self-weight compensation according to claim 1 ; a base coupled to the linear driving mechanism with self-weight compensation; an abutment portion that is provided at the base and is capable of abutting against a portion of the first moving body; and a detector using a relative value form that detects a movement distance of at least one of the first moving body, the second moving body, and the coupling portion, wherein the detector is initialized in a positional relationship in which the first moving body has abutted against the abutment portion. 7. A surgery assistance system comprising: the operation input device according to claim 6 ; and an actuation unit having a surgical instrument for performing surgery to a patient, the actuation unit being connected to the operation input device, and the actuation unit being actuated on the basis of at least a movement distance or a position detected in the detector. 8. An operation input device comprising: the linear driving mechanism with self-weight compensation according to claim 1 ; a base coupled to the linear driving mechanism with self-weight compensation; an abutment portion that is provided at the base and is capable of abutting against a portion of the first moving body; and a detector using a relative value form and that detects a position of at least one of the first moving body, the second moving body, and the coupling portion, wherein the detector is initialized in a positional relationship in which the first moving body has abutted against the abutment portion. 9. A surgery assistance system comprising: the operation input device according to claim 8 ; and an actuation unit having a surgical instrument for performing surgery to a patient, the actuation unit being connected to the operation input device, and the actuation unit being actuated on the basis of at least a movement distance or a position detected in the detector.