Kernel-level grain monitoring systems for combine harvesters

What is claimed is: 1. A kernel-level grain monitoring system utilized onboard a combine harvester, the kernel-level grain monitoring system comprising: a grain camera positioned to capture bulk grain sample images of a currently-harvested grain taken into and processed by the combine harvester; a moisture sensor configured to generate moisture sensor data indicative of a moisture level of the currently-harvested grain; a display device having a display screen on which one or more parameters pertaining to the currently-harvested grain are selectively presented; and a controller architecture coupled to the grain camera, to the moisture sensor, and to the display device, the controller architecture configured to: analyze the bulk grain sample images, as received from the grain camera, to determine an average per kernel (APK) volume representing an estimated volume of a single average kernel of the currently-harvested grain; calculate one or more topline harvesting parameters based, at least in part, on the determined APK volume and the moisture sensor data; and selectively present the topline harvesting parameters on the display device for viewing by an operator of the combine harvester; wherein the topline harvesting parameters include a kernel weight parameter having a test weight specifying a weight of the currently-harvested grain when packed into a predetermined volume of space; and wherein the controller architecture is further configured to calculate the test weight utilizing kernel packing data indicating a cumulative void space within the predetermined volume of space. 2. The kernel-level grain monitoring system of claim 1 wherein the controller architecture is configured to determine the kernel packing data based, at least in part, on an image analysis assessment of cumulative void space within the bulk grain sample images. 3. The kernel-level grain monitoring system of claim 1 , further comprising an operator interface coupled to the controller architecture; and wherein the controller architecture is configured to determine the kernel packing data based, at least in part, on operator input data received via the operator interface. 4. The kernel-level grain monitoring system of claim 1 , further comprising a database storing a plurality of kernel packing data associated with different grain attributes; and wherein the controller architecture is configured to determine the kernel packing data by recalling a selected one of the plurality of kernel packing data corresponding to the currently-harvested grain. 5. The kernel-level grain monitoring system of claim 1 , further comprising at least one strike plate sensor coupled to the controller architecture and impacted by kernels of the currently-harvested grain when transported into a grain tank of the combine harvester; wherein the controller architecture is coupled to the strike plate sensor and is configured to: estimate an APK mass of the currently-harvested grain utilizing the APK volume and a bulk density parameter of the currently-harvested grain; and monitor a mass flow rate of the currently-harvested grain based, at least in part, on the estimated APK mass and impact data provided by the strike plate sensor. 6. The kernel-level grain monitoring system of claim 5 , wherein the topline harvesting parameters comprise a grain yield parameter calculated utilizing the mass flow rate as an input. 7. The kernel-level grain monitoring system of claim 1 , wherein the controller architecture is configured to further analyze the bulk grain sample images, as received from the grain camera, to determine an APK morphology classification indicating a kernel size and shape category of the currently-harvested grain. 8. The kernel-level grain monitoring system of claim 7 , further comprising load cells located in a grain tank of the combine harvester; and wherein the controller architecture is further configured to: estimate an angle of repose of the currently-harvested grain based, at least in part, on the APK morphology classification; and selectively calibrate the moisture sensor utilizing data generated by the load cells and the estimated angle of repose. 9. The kernel-level grain monitoring system of claim 1 , further comprising strike plate sensors coupled to the controller architecture and impacted by kernels of the currently-harvested grain when ejected from the combine harvester; wherein the controller architecture is coupled to the strike plate sensors and is configured to: estimate an APK mass of the currently-harvested grain utilizing the APK volume and a bulk density parameter of the currently-harvested grain; and monitor a grain loss parameter of the currently-harvested grain based, at least in part, on the estimated APK mass and impact data provided by the strike plate sensors. 10. The kernel-level grain monitoring system of claim 1 , further comprising an actuated harvesting component onboard the combine harvester and coupled to the controller architecture; wherein the controller architecture is further configured to: determine a target setting adjustment to the actuated harvesting component based, at least in part, on a parameter calculated utilizing the APK volume; and perform at least one of: (i) generating graphics on the display device visually prompting an operator to implement the target setting adjustment to the actuated harvesting component, or (ii) automatically implementing the target setting adjustment to the actuated harvesting component. 11. The kernel-level grain monitoring system of claim 10 , wherein the parameter calculated utilizing the APK volume comprises one or more of an APK weight, an APK mass, or an APK density; and wherein the target setting adjustment comprises a fan speed adjustment. 12. A kernel-level grain monitoring system utilized onboard a combine harvester having an actuated harvesting component, the kernel-level grain monitoring system comprising: a grain camera positioned to capture bulk grain sample images of a currently-harvested grain taken into and processed by the combine harvester; a moisture sensor configured to generate moisture sensor data indicative of a moisture level of the currently-harvested grain; a display device having a display screen on which one or more parameters pertaining to the currently-harvested grain are selectively presented; and a controller architecture coupled to the grain camera, to the moisture sensor, and to the display device, the controller architecture configured to: analyze the bulk grain sample images, as received from the grain camera, to determine an average per kernel (APK) parameter which includes a kernel weight parameter having a test weight specifying a weight of the currently-harvested grain when packed into a predetermined volume of space; calculate the test weight utilizing kernel packing data indicating a cumulative void space within the predetermined volume of space; determine a target setting adjustment to the actuated harvesting component based, at least in part, on the APK parameter; and perform at least one of: (i) generating a notification prompting an operator to implement the target setting adjustment, and (ii) controlling the actuated harvesting component to automatically implement the target setting adjustment. 13. The kernel-level grain monitoring system of claim 12 , the controller architecture is configured to, when generating the notification, generate graphics on a display screen of the display device visually prompting an operator to implement the target setting adjustment. 14. The kernel-level grain monitoring system of claim 12 , wher