Patent Description:
A self-moving robot may be used for its convenient control and flexible action. For some self-moving robot, such as an integrated combined robot, the height may be limited to a certain degree. In the walking process of the self-moving robot, if the height of an obstacle is less than the height of the body of the self-moving robot, then the self-movement walk of the robot is hindered and the self-moving robot cannot pass through the obstacle smoothly.

Rather, this background is only provided to illustrate one example technology area where some embodiments described herein may be practiced.

Prior document D1 (<CIT>) discloses a mobile robot with single camera and a method for recognizing 3d surroundings of the same, where images of the surroundings are captured, and a preset number of particles with respect to feature points of a first image are projected to a second image based on matching information of feature points extracted from the two images sequentially captured, thereby extracting 3D information of the surroundings (see ABSTRACT of D1). Prior document D2 (<CIT>) discloses a mobile robot, specifically discloses that a system has a path-setting unit for setting the path of a mobile apparatus according to the inputted path, a measuring unit for measuring an environment in which the mobile apparatus exists, an extracting unit for extracting an object existence region in the environment according to the values measured by the measuring unit, a judging unit that judges the validity of the path according to the path set by the path setting unit and to the object existence region extracted by the extracting unit, a position determining unit that determines a target position to which the mobile apparatus is to move by selecting it from the portions of the path judged as valid, and a movement controller for controlling the mobile apparatus to move to the target position (see ABSTRACT of D2). Prior document D3 (<CIT>) discloses a robot cleaner, a robot cleaning system and a method for controlling same, the robot cleaner cleaning by wirelessly communicating with an external apparatus having a driving unit for driving a plurality of wheels; an upper camera disposed on a main body for photographing an upper image perpendicular to a direction of driving the robot cleaner; and a controller for controlling the driving unit to allow the robot cleaner to drive with a cleaning area according to a predetermined driving pattern, and compensating the driving path by analyzing the image photographed by the upper camera (see ABSTRACT of D3). Prior document D8 (<NPL>") discloses generating a 3D local map from visual information and planning the appropriate locomotion based on the map from biped walking with the variable height and the width and from crawling (see ABSTRACT of D8). Prior art document D9 (<CIT>) generally discloses a robot capable of being automatically separated, and specifically discloses that the robot comprises a module part and a robot body, wherein the robot body comprises a driving unit, a walking mechanism, a control unit and an energy supply unit; the module part is provided with a first working module, a control mechanism and an automatic combination actuating mechanism; the control mechanism control the automatic combination actuating mechanism to combine the module part on the robot body according to the instructions of the control unit; and the first working module is supplied with power to work by the energy supply unit. According to the actual working requirements, the module part is separated or combined with the robot body, therefore, the energy waste is avoided, and the purpose of saving energy and electricity is achieved (see ABSTRACT of D9). Prior art document D10 (<CIT>) generally discloses a method for cleaning or processing a room by means of an autonomously mobile device, and specifically discloses that in order the relieve the user of the task of finding the exact subarea to which the device must travel, or avoid, on a map of the room, the user in order to select a subarea takes a photograph of the subarea and transmits it to a processing unit (see ABSTRACT of D10).

In the present disclosure, a self-moving robot, a map building method, and a map invoking method for a combined robot is provided in view of the defects of other applications. For example, through distance sensors disposed on the self-moving robot, based on a generated two-dimensional map, spatial height information may be overlaid and three-dimensional map information may be generated. Additionally or alternatively, in a combined state, the robot invokes and plans a walking path in a working region based on a three-dimensional map, thereby ensuring smooth, safe and efficient operation of the combined robot in a complex environment.

In these or other embodiments of the present disclosure, a self-moving robot includes, for example, a robot body and a control center disposed on the body, wherein the robot body includes a first distance sensor disposed in a horizontal direction and a second distance sensor disposed in a vertical direction. In these or other embodiments, the first distance sensor collects two-dimensional map information of a working surface in which the self-moving robot is located. Additionally or alternatively, the second distance sensor collects spatial height information above the working surface in which the self-moving robot is located; and while obtaining the two-dimensional map information of the working surface, the control center combines the spatial height information with the two-dimensional map information to obtain three-dimensional map information of a working region.

In these or other embodiments, the first distance sensor and the second distance sensor may include an ultrasonic sensor, an infrared sensor and/or a visual sensor. Additionally or alternatively, the spatial height information above the working surface is a distance between the working surface and a lower surface of an encountered obstacle.

The present disclosure also provides a map building method for the above self-moving robot, including the following example steps:.

In these or other embodiments, the two-dimensional map information in the step <NUM> is obtained by the self-moving robot scanning the working surface during a traversing walk. Additionally or alternatively, the spatial height information above the working surface in the step <NUM> is a distance from the working surface to a lower surface of an encountered obstacle. A specific process of overlaying the spatial height information to the pre-generated two-dimensional map information may include:.

A three-dimensional map of the working region is built according to the three-dimensional map information saved in the step <NUM>.

The present invention also provides a map invoking method conducted by a combined robot. The combined robot includes a self-moving robot combined to a functional module, where, in an uncombined mode, the self-moving robot works without the functional module, and in the uncombined mode, the self-moving robot generates two-dimensional map information of a working surface by scanning the working surface during a traversing walk and three-dimensional map information by collecting spatial height information above the working surface and by overlaying said spatial height information to the two-dimensional map information. The method comprises: invoking three-dimensional map information; calculating a plane map with a height L from the ground according to a body height of the combined robot and three-dimensional map information; planning a walking path according to the plane map; and conducting a walking operation along the walking path. The combined robot further includes the functional module combined and connected with the self-moving robot. The self-moving robot is provided with a storage unit and the two-dimensional map information and the three-dimensional map information of the working region configured to be stored in the storage unit.

The combined robot includes an uncombined mode and a combined mode. When the self-moving robot works individually or alone, the combined robot is in the uncombined mode; and when the self-moving robot is combined and connected with the functional module, the combined robot is in the combined mode.

In the uncombined mode, the self-moving robot invokes the two-dimensional map information and conducts a walking operation on a two-dimensional working surface. In the combined mode, the combined robot invokes the three-dimensional map information, calculates a plane map with a height L from the ground according to a body height of the combined robot and three-dimensional map information, planes a walking path according to the plane map, and conducts a walking operation along the walking path; wherein the combined robot including the self-moving robot and the functional module combined and connected on top of the self-moving robot; and a storage unit configured to store two-dimensional map information and the three-dimensional map information of a working region. For example, in the combined mode, the combined robot plans a walking path according to the three-dimensional map information and calculates a walkable working region.

Additionally or alternatively, the combined robot calculates: map information of a first plane P1 according to body height L and the three-dimensional map information. In these or other embodiments, a height difference between the first plane P1 and the working surface is the body height L of the combined robot. Additionally or alternatively, the combined robot plans the walking path according to the two-dimensional map information of the first plane P1.

Thus, in some embodiments, the present disclosure provides a self-moving robot, a map building method, and a map invoking method for a combined robot. In the present disclosure, through the distance sensors disposed on the self-moving robot, based on the generated two-dimensional map, the spatial height information is overlaid and the three-dimensional map information is generated; and in the combined state, the robot invokes and plans the walking path in the working region based on the three-dimensional map, thereby helping to ensure smooth, safe and efficient operation of the combined robot in a complex environment.

The technical solution of the present disclosure is described below in detail in combination with drawings and specific embodiments.

<FIG> is an example structural schematic diagram of a self-moving robot. As shown in <FIG>, the self-moving robot <NUM> includes a robot body <NUM> and a control center (not shown in the figure) disposed on the body <NUM>, wherein the robot body <NUM> includes a first distance sensor <NUM> disposed in a horizontal direction and a second distance sensor <NUM> disposed in a vertical direction. In these or other embodiments, the first distance sensor <NUM> collects two-dimensional map information of a working surface W in which the self-moving robot is located; and the second distance sensor <NUM> collects spatial height information above the working surface W in which the self-moving robot is located. Additionally or alternatively, while obtaining the two-dimensional map information of the working surface W, the control center combines the spatial height information with the two-dimensional map information to obtain three-dimensional map information of a working region. Additionally or alternatively, for a point A, two-dimensional map information is (x1, y1) and the spatial height information is h1, the combining, by the control center, the spatial height information with the two-dimensional map information to obtain three-dimensional map information of a working region may be a process of combining the (x1, y1) and h1 to obtain (x1, y1, h1) as three-dimensional map information. Additionally or alternatively, the first distance sensor <NUM> and the second distance sensor <NUM> include an ultrasonic sensor, an infrared sensor and/or a visual sensor. For example, the spatial height information above the working surface W is a distance between the working surface and a lower surface of an encountered obstacle in an up-down direction.

<FIG> is a simplified flow chart of a three-dimensional map building method for a self-moving robot. As shown in <FIG>, a map building method for the self-moving robot provided in the embodiment as mentioned above includes the following example steps:.

Additionally or alternatively, the two-dimensional map information in the step <NUM> is obtained by the self-moving robot scanning the working surface during a traversing walk. Additionally or alternatively, the traversing walk is a operation or a process that the self-moving robot walks in the in a working region and walks all through the in the working region (in other words, traverses the in the working region). In these or other embodiments, the spatial height information above the working surface in the step <NUM> is a distance between the working surface and a lower surface of an encountered obstacle in an up-down direction.

An example process of combining the spatial height information with the pre-generated two-dimensional map information may include:.

<FIG> is an example structural schematic diagram of a combined robot. As shown in <FIG>, the combined robot A includes the above self-moving robot <NUM> and a functional module <NUM> integrated on the self-moving robot, wherein the self-moving robot includes, for example, a cleaning robot, a transporting robot or a walking robot capable of working individually. In one embodiment of the present disclosure, the self-moving robot <NUM> is a sweeping robot. Additionally or alternatively, the functional module <NUM> may be one submodule or a combination of more submodules of a security module, a humidifying module and a purifying module.

In these or other embodiments, the present disclosure includes a map invoking method for a combined robot. The combined robot A includes a self-moving robot <NUM> and a functional module <NUM> combined and connected with the self-moving robot. The self-moving robot <NUM> is provided with a storage unit (not shown in the figure), and the two-dimensional map information and the three-dimensional map information of the working region are stored in the storage unit. The combined robot A includes two working modes, such as an uncombined mode and a combined mode. When the self-moving robot <NUM> individually works, the combined robot is in the uncombined mode; and when the self-moving robot <NUM> is combined and connected with the functional module <NUM>, the combined robot is in the combined mode. In the uncombined mode, the self-moving robot <NUM> invokes the two-dimensional map information and conducts a walking operation on a two-dimensional working surface W. Additionally or alternatively, for a wiping robot, conducting the walking operation may conduct wiping operation well walks in a working region. In the combined mode, the combined robot <NUM> invokes the three-dimensional map information and conducts a walking operation in a three-dimensional working region.

For example, in the combined mode, the combined robot A plans a walking path according to the three-dimensional map information and calculates a walkable working region. A method for planning the walking path may include: the combined robot calculating a plane map with a height L from the ground according to body height L and the three-dimensional map; and the combined robot planning the walking path according to the plane map.

<FIG> is a schematic diagram of a walking state of a combined robot of the present disclosure on a working surface. As shown in <FIG>, for example, the combined robot calculates map information of a first plane P1 according to the body height L and the three-dimensional map information. In these or other embodiments, a height difference between the first plane P1 and the working surface W is the body height L of the combined robot. Additionally or alternatively, the combined robot plans the walking path according to the two-dimensional map information of the first plane P1.

As shown in <FIG>, the actual working process of the embodiments of the present disclosure may be as follows:
As shown in <FIG>, after the self-moving robot <NUM> walks and scans in the working environment to build a map or records the coordinate information of the working plane to build a map during a traversing walk, a two-dimensional map is formed in the control center of the self-moving robot <NUM>. The formation process of the above two-dimensional map is well-known in the arts, and is not repeated herein. Additionally or alternatively, the self-moving robot <NUM> continues to conduct a traversing walk in the working environment. During walking, the distance sensors collect the height information in the working environment in real time (or approximately real time) and transmit the height information to the control center. The control center combines the height information with the pre-generated two-dimensional map to obtain a three-dimensional map and save the three-dimensional map into the control center.

In these or other embodiments, when the self-moving robot adopts the above mode of recording the coordinate information of the working plane to build the map during a traversing walk, the self-moving robot can simultaneously (or approximately simultaneously) record the spatial height information, e.g., when obtaining the two-dimensional information of the working plane, the self-moving robot can simultaneously (or approximately simultaneously) collect the three-dimensional information of the working region to complete the building of the three-dimensional map of the working region. When the combined robot, as shown in <FIG>, is combined and connected, the height of the combined robot is higher than the height of the self-moving robot <NUM>. Therefore, an original two-dimensional map may not be enough to be used as the basis for planning the walking path of the combined robot. For example, a position which could be smoothly passed previously by the self-moving robot <NUM> may become impassable due to the problem of the increased height of the combined robot. At this moment, the three-dimensional map may be invoked to plan the walking path of the combined robot.

As shown in <FIG>, the body height of the self-moving robot <NUM> in the combined state is L. In the present embodiment, the combined robot calculates map information of the first plane P1 with a height L away from the working plane W of the self-moving robot through the above three-dimensional map. The first plane P1 can be regarded as the walkable working plane of the combined robot, and the walking path of the combined robot is planned in the map of the first plane P1.

Claim 1:
A map invoking method, conducted by a combined robot (A), including a self-moving robot (<NUM>) combined to a functional module, wherein, in an uncombined mode, the self-moving robot (<NUM>) works without the functional module, and in the uncombined mode, the self-moving robot generates two-dimensional map information of a working surface by scanning the working surface during a traversing walk and three-dimensional map information by collecting spatial height information above the working surface and by overlaying said spatial height information to the two-dimensional map information;
the method comprising:
invoking three-dimensional map information;
calculating a plane map with a height L from the ground according to a body height (L) of the combined robot (A) and three-dimensional map information;
planning a walking path according to the plane map; and
conducting a walking operation along the walking path;
wherein the combined robot (A) further includes the functional module combined and connected on top of the self-moving robot (<NUM>); and
a storage unit configured to store two-dimensional map information and the three-dimensional map information of a working region.