摘要:
Methods and systems for robot cloud computing are described. Within examples, cloud-based computing generally refers to networked computer architectures in which application execution and storage may be divided, to some extent, between client and server devices. A robot may be any device that has a computing ability and interacts with its surroundings with an actuation capability (e.g., electromechanical capabilities). A client device may be configured as a robot including various sensors and devices in the forms of modules, and different modules may be added or removed from robot depending on requirements. In some example, a robot may be configured to receive a second device, such as mobile phone, that may be configured to function as an accessory or a “brain” of the robot. A robot may interact with the cloud to perform any number of actions, such as to share information with other cloud computing devices.
摘要:
Methods and systems for robot functions and user interfaces are described. A server may receive a set of robot parameters, and may predict new parameters based on a robot command. In this manner, a user may receive parameters corresponding to the predicted values and mitigate network and processing latency. In other examples, a robot may provide a forward looking image and a robot speed. When a command to move forward is issued, the server may provide a predicted image and predicted speed. The server may be able to calculate a predicted image and a predicted speed (or other parameter) more quickly than the robot could provide the same information. The predicted information may be displayed on a user interface with a corresponding indication that the values are predicted. The robot may provide the server and the user interface with the actual data when it is available.
摘要:
Systems and methods for collecting data from an object are provided. In examples, a plurality of sensing components are configured to receive information indicative of one or more characteristics of the object. The information indicative of one or more characteristics of the object can be associated with respective data points of the object. The system is further configured to generate a three-dimensional (3D) view of the object based on the information indicative of one or more characteristics of the object and the association with respective data points.
摘要:
Methods and systems for material refinement for portions of a three-dimensional (3D) object data model are provided. An example method may include rendering a portion of a 3D object data model, and determining a first appearance metric between an appearance of the portion in the rendered view and a two-dimensional (2D) image. For one or more iterations, a modification to material properties associated with the portion may be determined based on the first appearance metric, and another view of the portion of the 3D object data model may be rendered. Also for the one or more iterations, another appearance metric between and an appearance of the portion in the rendered another view and the 2D image may be determined. Additionally, modified material properties for the portion that are associated with a minimum appearance metric of the one or more iterations may be stored for the 3D object data model.
摘要:
Methods and systems for interacting with multiple three-dimensional (3D) object data models are provided. An example method may involve receiving an annotated template of a first three-dimensional (3D) object data model. The annotated template may be associated with a given category of objects and may include one or more annotations to one or more aspects of an object described by the first 3D object data model. The method may also include determining matching correspondences between the first 3D object data model and a second 3D object data model that is a given object in the given category. For the one or more matching correspondences, an annotation that is associated with a correspondence point of the first 3D object data model may be applied as a call-out to a matching correspondence point of the second 3D object data model.
摘要:
Methods and systems for providing functionality of an interface to include an artificial horizon are provided. In one example, a method includes receiving information indicating a range of motion of a camera on a device, and providing an interface on a second device remote from the device. The interface may be configured to receive an input indicating a command for an orientation of the camera on the device. The method may further include based on the information indicating the range of motion of the camera, providing an artificial horizon at a fixed position on the interface that indicates the range of motion of the camera on either side of the artificial horizon. The fixed position of the artificial horizon may be associated with an orientation of the camera having a tilt value of about zero or having a pan value of about zero.
摘要:
The present application discloses shared robot knowledge bases for use with cloud computing systems. In one embodiment, the cloud computing system collects data from a robot about an object the robot has encountered in its environment, and stores the received data in the shared robot knowledge base. In another embodiment, the cloud computing system sends instructions for interacting with an object to a robot, receives feedback from the robot based on its interaction with the object, and updates data in the shared robot knowledge base based on the feedback. In yet another embodiment, the cloud computing system sends instructions to a robot for executing an application based on information stored in the shared robot knowledge base. In the disclosed embodiments, information in the shared robot knowledge bases is updated based on robot experiences so that any particular robot may benefit from prior experiences of other robots.
摘要:
Methods and systems for displaying information on or within a three-dimensional (3D) image are described. In an example, a computing device may be configured to determine, based on a two-dimensional (2D) content displayed on a display device, an object depicted in the 2D content. The computing device may be configured to receive information indicative of a request to initiate a three-dimensional (3D) image viewer to view the object in the 3D image viewer. The computing device, accordingly, may be configured to provide rendering information associated with instructions for rendering in the 3D image viewer a 3D image representing a 3D object data model of the object on the display device. The computing device may be configured to provide, in the 3D image viewer, information relating to the object and including at least a portion of the 2D content.
摘要:
Methods and systems for providing a three-dimensional (3D) image viewer in a webpage are provided. According to an example method, a webpage may be provided, and the webpage may include embedded language that identifies a 3D image viewer to be provided within the webpage. Based on the embedded language, a computer having a processor and a memory may request information associated with rendering a 3D object data model in the 3D image viewer. The method may also include providing the 3D image viewer within the webpage, and receiving information associated with rendering the 3D object data model. Additionally, the 3D object data model may be rendered in the 3D image viewer based on the received information. Additional example systems and methods are described herein.
摘要:
Methods and systems for providing functionality of a user interface to control directional orientations of a device are provided. An example method includes receiving an input on an interface indicating a command for a directional orientation of a robotic device, and providing an indicator on the interface representing a location of the input. The indicator may include a representation of the command for the directional orientation of the robotic device. The method may further include determining that the location of the input on the interface is within a distance threshold to a pre-set location on the interface, and repositioning the indicator on the interface to be at the pre-set location. In this manner, the indicator may snap to a location if the input is close to a pre-set location, for example.