Autonomously mobile backscatter detection apparatus and method, and positioning method for the apparatus

What is claimed is: 1. A method of backscatter detection for an autonomously mobile backscatter detection apparatus, wherein the autonomously mobile backscatter detection apparatus comprises: a mobile platform configured to move freely in a horizontal plane; and a backscatter detection imaging apparatus, arranged on the mobile platform and configured to acquire an image of an item of two items to be inspected, and wherein the method comprises: determining a contour curve of a plurality of items to be inspected by a trajectory tracking control algorithm in a Cartesian coordinate system; forming a trajectory curve of the mobile platform according to the contour curve; moving the mobile platform to be close to a first item to be inspected along the trajectory curve; controlling the backscatter detection imaging apparatus to scan the first item to be inspected, under a control of a main control unit of the mobile platform; and moving the mobile platform along the trajectory curve, such that the backscatter detection imaging apparatus sequentially scans the plurality of items to be inspected, wherein the method further comprises: detecting a gap between the items to be inspected so as to distinguish different items to be inspected and recording a position of the gap, and moving the backscatter detection imaging apparatus and/or the mobile platform to be in an orientation close to a center of one of the items to be inspected, which is determined according to boundaries of the one of the items to be inspected. 2. The method according to claim 1 , wherein the step of determining the contour curve of the plurality of items to be inspected comprises: positioning the mobile platform in place and rotating a laser ranging module of the mobile platform to obtain position and distance information of the items to be inspected within a range of angles less than or equal to 270° in front of the mobile platform, obtaining effective data points of the items to be inspected through filtering by a processor, and then calculating a contour curve function of the plurality of items to be inspected in the Cartesian coordinate system by the processor based on the data points. 3. The method according to claim 2 , further comprising a step of: calculating an optimal scanning distance according to scattering angles and an area of a receiving end of the backscatter detection imaging apparatus after detecting the gap between the items to be inspected. 4. The method according to claim 1 , further comprising a step of: moving the backscatter detection imaging apparatus on the mobile platform vertically or horizontally, so as to scan the items to be inspected in an optimal imaging quality. 5. A method of positioning an autonomously mobile backscatter detection apparatus, wherein the autonomously mobile backscatter detection apparatus comprises: a mobile platform configured to move freely in a horizontal plane; and a backscatter detection imaging apparatus, arranged on the mobile platform and configured to acquire an image of an item of two items to be inspected, and wherein the method comprises: moving the mobile platform to a location where a plurality of feature points are capable of being detected, and finding the plurality of feature points; stopping the mobile platform, and observing the found feature points to determine whether the feature points are stationary or not, so as to select the stationary feature points; establishing a Cartesian coordinate system with a current position of a reference point on the mobile platform as an origin point and a front face of the mobile platform facing towards a X-axis positive direction, and calculating and recording coordinates of the plurality of feature points in the Cartesian coordinate system; delimiting a first positioning area where three or more feature points are capable of being simultaneously observed by the mobile platform and a second positioning area other than the first positioning area; determining a position of the mobile platform by a three-point positioning algorithm when the mobile platform is located in the first positioning area, and determining the position of the mobile platform by a servo mechanism encoder of the mobile platform when the mobile platform is located in the second positioning area. 6. The method according to claim 5 , wherein the selected stationary feature points comprise 5-10 feature points, and if the number of the selected stationary feature points is less than 5, then the positioning method controls the mobile platform to move to a new location, and finds and selects feature points again. 7. The method according to claim 5 , wherein the step of determining the position of the mobile platform by the three-point positioning algorithm comprises: rotating a laser ranging module of the mobile platform to respectively measure distances between the mobile platform and three feature points, and determining the position of the mobile platform based on the distances and the recorded coordinates of the three feature points. 8. The method according to claim 5 , wherein the step of determining the position of the mobile platform by the servo mechanism encoder of the mobile platform comprises: feeding back a distance by which a wheel or a track travels through two servo motor encoders operated independently of each other, so as to calculate a position and an attitude angle of the mobile platform by a main control unit of the mobile platform. 9. The method according to claim 5 , wherein the position determined by the three-point positioning algorithm is used to replace the position determined by the servo mechanism encoder to eliminate accumulative error, when the mobile platform is located in the first positioning area.