Six-degree-of-freedom displacement measurement method for exposure region on silicon wafer stage

What is claimed is: 1 . A six-degree-of-freedom displacement measurement method for an exposure region on a wafer stage, wherein the exposure region ( 10 ) is a region formed by projecting an exposure light beam ( 2 ) onto a movable platform ( 3 ), wherein the method comprises following steps: fixing a planar grating ( 9 ) below a permanent magnet array ( 8 ) of the movable platform such that a measurement surface of the planar grating faces a coil array ( 4 ), and fixing a reading head ( 5 ) in a gap of the coil array such that a central line of the reading head coincides with a central line of a lens ( 1 ); forming a measurement region ( 11 ) on the planar grating by irradiating a measurement light beam ( 6 ) of the reading head onto the planar grating, wherein a center B of the measurement region and a center A of the exposure region ( 10 ) are located at a same vertical line; obtaining a six-degree-of-freedom pose (p x , p y , p z , θ x , θ y , θ z ) of the measurement region at a moment by measurement with the reading head and the planar grating, wherein (p x , p y , p z ) is a coordinate of the center B of the measurement region, and θ x , θ y , θ z are included angles formed between a normal line of a plane, in which the measurement region is located, along a positive Z direction and coordinate axes X, Y and Z, respectively; calculating and obtaining a six-degree-of-freedom pose of the exposure region by substituting the six-degree-of-freedom pose of the measurement region into (p x ′, p y ′, p z ′, θ x ′, θ y ′, θ z ′)=(p x +L cos θ x , p y +L cos θ y , p z +L cos θ z , θ y , θ z ), wherein a part of the movable platform covered by the exposure region is taken as a rigid body approximately, wherein p x ′, p y ′, p z ′ represent a position of the center A of the exposure region, θ x ′, θ y ′, θ z ′ represent included angles formed between a normal line of a plane, in which the exposure region is located, along the positive Z direction and the coordinate axes X, Y and Z, respectively, and L is a distance between the center A and the center B; and obtaining a six-degree-of-freedom displacement of the exposure region from a previous moment to a next moment by subtracting the six-degree-of-freedom pose of the exposure region at the previous moment from the six-degree-of-freedom pose of the exposure region at the next moment when the movable platform moves to the next moment.