A controller determines a plurality of candidate paths. The plurality of candidate paths cross a first digging wall from a first slot toward a second slot and extend in respective directions. The controller calculates an evaluation function of a path search algorithm for each of the plurality of candidate paths. The controller determines a candidate path having an optimal evaluation function of the plurality of the candidate paths as a first digging path. The controller controls a work machine according to the first digging path.

A shovel includes a lower travelling body, an upper swiveling body that is mounted on the lower travelling body so as to freely swivel relative to the lower travelling body, an operator cab that is mounted on the upper swiveling body, and a monitor attaching base that is installed inside the operator cab so as to extend in right and left directions and includes a plurality of attaching units, to which a display device is attachable.

A shovel according to an embodiment of the present invention includes a lower traveling body, an upper turning body rotatably mounted on the lower traveling body, an operator's compartment provided to the upper turning body, a display device provided in the operator's compartment, and an input device provided in the operator's compartment. The display device is capable of displaying a setting screen for a construction support system using information and communication technology, and a function to switch a screen displayed on the display device to the setting screen is assigned to the input device.

A material type identifier identifies a type of material loaded into a dump truck. When the dump truck is unloaded, a flow rate identification system identifies a flow rate of material exiting the dump truck. A flow rate controller automatically controls the tailgate actuator based on a desired flow rate of material exiting the dump body of the dump truck.

A data collection system includes an input device configured to receive an input from a user, a first hardware processor configured to obtain data related to a work machine with a work attachment and satisfying a predetermined condition, according to the input received by the input device, and a second hardware processor configured to execute a process related to providing the user with an incentive when the first hardware processor obtains the data.

A controller may receive, from one or more sensor devices of the work machine, sensor data of an environment that includes a ground surface on which the work machine is located. The controller may determine whether a wireless connection is viable. The controller may selectively transmit the sensor data to one or more remote computing devices for processing or processing the sensor data locally by the work machine based on whether the wireless connection is viable. When the wireless connection is viable, the sensor data is transmitted to the one or more remote computing devices to cause the one or more remote computing devices to process the sensor data to provide first processed data. When the wireless connection is not viable, the sensor data is processed locally by the work machine to generate second processed data.

An example wear detection system receives first imaging data from one or more sensors associated with a work machine. The first imaging data comprises data related to at least one ground engaging tool (GET) of the work machine. The example system identifies a region of interest including data of the at least one GET within the first imaging data. Based on the identified region of interest, the example system controls a LiDAR sensor to capture second imaging data capturing the at least one GET that is of higher resolution than the first imaging data. The example system generates a three-dimensional point cloud of the at least one GET based on the second imaging data and determines a wear level or loss for the at least one GET based on the three-dimensional point cloud.

The present disclosure is directed to systems and methods for managing on-site machines. The method includes, for example, (i) receiving geospatial information associated with a work site; (ii) generating a user interface on at least one display; (iii) displaying a first machine of the multiple machines within the first section in a first compressed view; (iv) selecting a second machine of the multiple machines; (v) in response to the selection of the second machine of the multiple machines within the second section, visually presenting at least one portion of the work site in an elevated view; and (vi) visually presenting the second machine of the multiple machines in a second compressed view.

A method of indicating to an operator of a work vehicle a relative location of an object, an object indication system, and a work vehicle are provided. The method includes sensing the object with one or more sensors positioned at one or more sensor positions on the work vehicle and activating one or more indicators positioned at one or more indicator positions relative to the operator based on the sensing of the object with the one or more sensors. Each sensor position directionally corresponds to one or more of the indicator positions.

A periphery monitoring device calculates an expected passage range indicating a range of a locus of a machine body when a lower travelling body travels in an imaging direction of a camera, based on a slewing angle of an upper slewing body and an attitude of an attachment, and superimposes a range image indicating the calculated expected passage range on an image captured by the camera to display the superimposed image on the display.