Crop container monitoring

The invention claimed is: 1 . A crop container monitor for monitoring a fill-state during a harvesting operation, the crop container monitor comprising: an open-top crop container comprising a first wall, a second wall opposite the first wall, a third wall extending between the first wall and the second wall, and a fourth wall opposite the third wall and extending between the first wall and the second wall such that the first wall, the second wall, the third wall, and the fourth wall define an opening at a top of the open-top crop container through which harvested crop discharged from a harvesting vehicle enters and interior of the open-top crop container; at least one radiation sensor positioned at an upper end of one of the first wall, the second wall, the third wall, or the fourth wall of the open-top crop container to receive radiation reflected off the harvested crop within the interior of the open-top crop container; and a controller that: receives a sensing signal from the at least one radiation sensor, wherein the sensing signal is representative of the received radiation; determines a propagation distance from the at least one radiation sensor to a point from which the received radiation was scattered, reflected, or emitted by the harvested crop within the interior of the open-top crop container based on the sensing signal; and outputs the fill-state of the harvested crop within the interior of the open-top crop container based on the propagation distance. 2 . The crop container monitor of claim 1 , wherein the controller: receives a position and/or an orientation of the open-top crop container relative to the harvesting vehicle and/or an unloading tube of the harvesting vehicle; and outputs a positioning state, representative of the relative position and/or orientation, with the fill-state. 3 . The crop container monitor of claim 2 , wherein the controller: determines if the harvested crop in a portion of the interior of the container being filled exceeds a threshold height based on the fill-state and the positioning state; and outputs a current filling status, representative of whether the harvested crop exceeds the threshold height, with the fill-state and the positioning state. 4 . The crop container monitor of claim 2 , wherein the controller: determines one or more control signals for controlling an agricultural vehicle associated with the harvesting operation based on the fill-state and the positioning state; and outputs the control signals for controlling the agricultural vehicle. 5 . The crop container monitor of claim 1 , wherein the at least one radiation sensor comprises a radiation transceiver that: emits a radiation signal; and receives the radiation signal reflected back towards the radiation transceiver by the harvested crop within the interior of the open-top crop container, wherein the controller determines the propagation distance based on a time of flight of the radiation signal. 6 . The crop container monitor of claim 5 , wherein the radiation transceiver is positioned at the upper end of the first wall of the open-top crop container and emits the radiation signal towards the second wall of the open-top crop container. 7 . The crop container monitor of claim 6 , wherein: the open-top crop container further comprises a trailer or a truck for positioning adjacent to the harvesting vehicle during the harvesting operation to receive the harvested crop from the harvesting vehicle; the first wall or the second wall is a front wall of the trailer or truck; and the other one of the first wall or the second wall is a rear wall of the trailer or truck. 8 . The crop container monitor of claim 6 , wherein: the radiation transceiver is positioned at an end of the first wall connecting to the third wall of the open-top crop container. 9 . The crop container monitor of claim 8 , wherein: the at least one radiation sensor further comprises a second radiation transceiver positioned at the upper end of the second wall that emits a second radiation signal towards the first wall and receives the second radiation signal reflected back towards the second radiation transceiver by the harvested crop material within the interior of the open-top crop container; the second radiation transceiver is positioned at the end of the second wall connecting to the third wall; and the controller determines a second propagation distance based on a time of flight of the second radiation signal and determines the fill-state of the harvested crop within the interior of the open-top crop container based on the second propagation distance. 10 . The crop container monitor of claim 8 , wherein the at least one radiation sensor further comprises a third radiation transceiver positioned at the upper end of the first wall or the second wall that emits a third radiation signal towards the other one of the first wall and the second wall and receives the radiation signal reflected back towards the third radiation transceiver by the harvested crop material within the interior of the open-top crop container, wherein the third radiation transceiver is positioned at an end of the first wall or the second wall connecting to the fourth wall, and wherein the controller determines a third propagation distance based on a time of flight of the third radiation signal and determines the fill-state of the harvested crop within the interior of the open-top crop container based on the third propagation distance. 11 . The crop container monitor of claim 5 , wherein the radiation transceiver comprises a laser transceiver. 12 . The crop container monitor of claim 1 , wherein the at least one radiation sensor comprises a first radiation sensor and a second radiation sensor, and wherein the controller: determines a range profile of the harvested crop within the interior of the open-top crop container based on a first sensing signal from the first radiation sensor, a second sensing signal from the second radiation sensor, and relative positions of the first radiation sensor and the second radiation sensor on the open-top crop container; and outputs the fill-state based on the range profile. 13 . The crop container monitor of claim 12 , wherein the controller estimates a crop distribution of the harvested crop within the interior of the open-top crop container based on the range profile and outputs the fill-state based on the crop distribution. 14 . The crop container monitor of claim 12 , wherein the controller identifies or estimates a crop spillage of the harvested crop material outside the open-top crop container based on the range profile and outputs the crop spillage as part of the fill-state. 15 . The crop container monitor of claim 12 , wherein the range profile comprises a 3D point cloud or a range image. 16 . The crop container monitor of claim 12 , wherein the first and second radiation sensors comprise any of: a LiDAR transceiver, a RADAR transceiver, an ultrasonic transceiver, a stereo camera, or a camera. 17 . The crop container monitor of claim 12 , wherein the first radiation sensor is positioned at the upper end of one of the first wall, the second wall, the third wall, or the fourth wall of the open-top crop container and the second radiation sensor is positioned at the upper end of another of the first wall, the second wall, the third wall, or the fourth wall of the open-top crop container such that the first radiation sensor is spaced apart from the second radiation sensor. 18 . The crop container monitor of claim 17