Control Method for Autonomous Mobile Robot and Autonomous Mobile Robot

What is claimed is: 1 . A method for controlling an autonomous mobile robot, the method comprising: receiving near-field obstacle information sent by at least one sensor, the at least one sensor being mounted on the autonomous mobile robot; generating an obstacle position map around the autonomous mobile robot based on the near-field obstacle information; and generating an escape path in response to receiving the near-field obstacle information multiple times within a limited time or space, the generating the escape path comprising searching for a passable direction based on a current position of the autonomous mobile robot and the obstacle position map. 2 . The method according to claim 1 , wherein the near-field obstacle information comprises at least one of: collision information indicating a contact collision of the autonomous mobile robot; lifting information indicating a lifting of the autonomous mobile robot; motor torque information indicating a stall of a driving motor of the autonomous mobile robot; or non-contact obstacle sensing information indicating presence of an obstacle around the autonomous mobile robot. 3 . The method according claim 1 , wherein the generating the obstacle position map around the autonomous mobile robot based on the near-field obstacle information comprises: marking a position on the obstacle position map corresponding to the near-field obstacle information as a near-field obstacle. 4 . The method according to claim 1 , wherein the obstacle position map is a local map around the autonomous mobile robot, and the local map is updated as the autonomous mobile robot moves. 5 . The method according to claim 1 , wherein the searching for the passable direction based on the current position of the autonomous mobile robot and the obstacle position map comprises: expanding a near-field obstacle in the obstacle position map according to an expansion coefficient, the expansion coefficient being approximately equal to a width of the autonomous mobile robot; and determining a direction in the obstacle position map where the near-field obstacle is absent as the passable direction. 6 . The method according to claim 5 , wherein the expanding the near-field obstacle in the obstacle position map according to the expansion coefficient comprises: expanding a subset of near-field obstacles in the obstacle position map according to the expansion coefficient, the subset of near-field obstacles comprising obstacles detected by obstacle remote sensing information. 7 . The method according to claim 1 , wherein the searching for a passable direction based on the current position of the autonomous mobile robot and the obstacle position map comprises: obtaining a search direction and a search range in the obstacle position map; and determining, as the passable direction, a direction within the search range where near-field obstacle is absent, wherein an initial search direction is a direction opposite to a movement direction of the autonomous mobile robot, and the search range is an area, determined by the search direction, that exceeds an area covered by the autonomous mobile robot on the obstacle position map. 8 . The method according to claim 7 , wherein when the passable direction is not found in the obstacle position map along the initial search direction, the search direction is switched to the direction opposite to the initial search direction. 9 . The method according to claim 7 , further comprising: keeping the search direction unchanged until the near-field obstacle information is received again during a process in which the autonomous mobile robot travels toward the passable direction. 10 . The method according to claim 7 , wherein the searching for the passable direction based on the current position of the autonomous mobile robot and the obstacle position map comprises: during a process of controlling the autonomous mobile robot to travel toward the passable direction; and in response to determining that the near-field obstacle information is received within a continuous time period, switching the search direction to the direction opposite to the initial search direction. 11 . The method according to claim 1 , wherein the searching for a passable direction based on the current position of the autonomous mobile robot and the obstacle position map comprises: correspondingly adjusting the passable direction as the current position of the autonomous mobile robot is updated and the obstacle position map is updated. 12 . The method according to claim 1 , wherein the searching for the passable direction based on the current position of the autonomous mobile robot and the obstacle position map comprises: in response to determining that the autonomous mobile robot cannot search for the passable direction, controlling the autonomous mobile robot to ignore the obstacle position map and conduct a pose adjustment, the pose adjustment comprising at least one of following: moving forward, moving backward, or rotating; and searching for a passable direction according to a current position of the autonomous mobile robot after pose adjustment and the obstacle position map. 13 . The method according to claim 12 , wherein the searching for the passable direction according to the current position of the autonomous mobile robot after pose adjustment and the obstacle position map further comprises: searching for the passable direction according to the current position of the autonomous mobile robot after pose adjustment and updating the obstacle position map, wherein the obstacle position map is obtained after updating obstacles in the obstacle position map according to a preset rule, the preset rule comprising that in response to determining that near-field obstacles identified in real-time by an non-contact obstacle sensing sensor mounted on the autonomous mobile robot are inconsistent with obstacles in the obstacle position map, the obstacle position map is updated according to real-time identification results of the non-contact obstacle sensing sensor. 14 . The method according to claim 1 , wherein: angular velocity and a linear velocity are determined according to an angle difference between a movement direction of the autonomous mobile robot and the passable direction, the autonomous mobile robot is controlled to move toward the passable direction according to the angular velocity and the linear velocity, the angular velocity is positively correlated with the angle difference, and the linear velocity is negatively correlated with the angle difference. 15 . The method according to claim 1 , wherein the searching for the passable direction based on the current position of the autonomous mobile robot and the obstacle position map comprises: during a process of controlling the autonomous mobile robot to move toward the passable direction, determining that the autonomous mobile robot is capable of rotating according to the obstacle position map around the autonomous mobile robot; and controlling the autonomous mobile robot to rotate, and searching for the passable direction according to a position after rotation. 16 . The method according to claim 15 , wherein an initial rotation direction is consistent with a boundary-following direction of the autonomous mobile robot. 17 . The method according to claim 15 , wherein the searching for the passable direction according to the position after rotation comprises: during a process of controlling the autonomous mobile robot to rotate, determining a direction tha