China successfully landed Chang’e-3（ CE-3） lander and rover on December 14

2013

and the rover Yutu had traversed 114. 8 m and accomplished a series of scientific investigations under teleoperation. To fulfill teleoperation requirements

the techniques of remote sensing mapping and localization based on images have been developed and used to produce high precision topographic and rover localization products. These techniques and derived products are critical to support teleoperation tasks such as obstacle avoidance and rover path planning.Based on consecutive image registration between CE-3 descent images and Chang’e-2（ CE-2） Digital Ortho Map（ DOM）（ 1.5 m/pixel）

the CE-3 lander has been localized on high-resolution lunar orbital and descent images. A sequence of descent i mages are firstly selected at intervals from 2 km altitude

and then the geometric relationships among the selected sequence images are established through SIFT matching. Lunar craters are subsequently extracted by image segmentation with mean-shift method and then applied to registration between CE-2 DOM and the descent images. The landing point of CE-3 is finally localized in CE-2 DOM and a Lunar Reconnaissance Orbiter（ LRO） image（ 1. 6 m /pixel） acquired before CE-3 landing.High-precision terrain products covering landing area of CE-3 have also been produced using the descent sequence images.First

image matching among the selected sequence images is performed with SIFT matching

during which gross errors are eliminated by an RANSAC algorithm. Second

the remaining matched points are used as tie points to construct an image network

and bundle adjustment is then performed with ground control points from the CE-2 Digital Elevation Model（ DEM） and DOM. Third

dense matching among the sequence images is performed to generate dense matched points

and the three-dimensional coordinates of the dense points is subsequently calculated with space intersection. Finally

the DEM is generated by Kriging interpolation and DOM is generated by back projection.Along the traverse

Yutu Rover acquired stereo images covering 120° field of view using its navigation cameras（ Navcam） at waypoints that are about 10 m apart. Epipolar images of the Navcam stereo images are generated and SIFT-based matching is p erformed among the Navcam images to extract tie points. Block adjustment is then performed to refine the exterior orientation p arameters of the Navcam images. Finally

the DEMs and DOMs are generated by the method similar to producing the topographic products from the descent images. These topographic products are used to support path planning at every waypoint.High precision localization of Yutu Rover has been accomplished by cross-site visual localization and DOM matching. Crosssite visual localization is based on Affine-SIFT matching algorithm

which obtains matched points in Navcam images between adjacent sites. Then bundle adjustment is applied to resolve the exterior orientation parameters of image at the present site so that to l ocalize the rover. The DOM matching localization is based on SIFT matching between the DOM derived from Navcam stereo i mages and the DOM generated previously from the descent images. As a result

the rover position is localized in CE-2 DOM b ecause the DOM from descent images has been registered to CE-2 DOM.The lander localization result based on consecutive registration of descent images is proved very precise（ within one pixel） by comparison with a LRO image acquired on December 25

2013

in which the lander can be directly identified. High precision localization and mapping results based on the descent images and Navcam stereo images have supported path planning and obstacle a voidance during CE-3 mission. These techniques have been routinely used in mission operations of CE-3 and have been proved e ffective and reliable.