Agricultural harvesting machine

What is claimed is: 1. An agricultural harvesting machine comprising: a cutting apparatus formed as a header for cutting and picking up crop of a crop stand, the cutting apparatus having a reel with a horizontal reel position and a vertical reel position, and a cutting table having a cutting table length, an inclined conveyor arranged downstream of the cutting apparatus, and a driver assistance system configured for controlling at least the cutting apparatus, the driver assistance system comprising a computing device and a sensor arrangement with a crop sensor system configured for determining crop parameters of the crop stand and a layer height sensor arranged at the conveyor for determining a temporal layer height flow defined as a change in a height of product throughput as product moves along the conveyor, wherein the computing device is configured to evaluate sensor signals of the sensor arrangement as a signal evaluation and simultaneously generate cutting apparatus parameters of the cutting table length, horizontal reel position and vertical reel position to adjust the cutting apparatus parameters in order to implement a harvesting process strategy in an ongoing harvesting operation, the harvesting process strategy being directed to minimization of vibration components in the temporal layer height flow, and wherein the signal evaluation comprises a vibration analysis of the temporal layer height flow in the form of a Fourier analysis to determine the cutting table length that minimizes a vibration component of the temporal layer height flow. 2. The agricultural harvesting machine according to claim 1 , wherein the vibration analysis includes a determination of a vibration coefficient of a vibration component in the temporal layer height flow that represents that portion of the temporal layer height flow that accounts for a predetermined vibration frequency or a predetermined vibration frequency range. 3. The agricultural harvesting machine according to claim 2 , wherein the predetermined vibration frequency or predetermined vibration frequency range lies between 0.5 Hz and 10 Hz. 4. The agricultural harvesting machine according to claim 2 , wherein the computing device is configured to store at least one characteristic diagram for mapping a functional relationship between the vibration coefficient, the cutting table length and a product throughput value, wherein at least the cutting table length is generated based on the characteristic diagram, and wherein the product throughput value is a time-averaged product throughput. 5. The agricultural harvesting machine according to claim 2 , wherein, according to the characteristic diagram, the vibration coefficient has a minimum value along a cutting table length adjustment range for at least a subrange of product throughput values. 6. The agricultural harvesting machine according to claim 4 , wherein the computing device is configured to compare the characteristic diagram to the sensor signals of the sensor arrangement while the harvesting operation is ongoing. 7. The agricultural harvesting machine according to claim 1 , wherein the computing device is configured to generate the horizontal reel position so as to be adapted to the cutting table length in such a way that the horizontal reel position results in a predetermined linear relationship to the cutting table length. 8. The agricultural harvesting machine according to claim 1 , wherein the crop sensor system has a crop stand height sensor configured for measuring the crop stand height in an area in front of the harvesting machine, and in wherein the computing device is configured to generate a crop stand height map for the area in front of the harvesting machine from the sensor signals of the crop stand height sensor and generate the vertical reel position based on the crop stand height map. 9. The agricultural harvesting machine according to claim 8 , wherein the crop stand height sensor is a distance sensor. 10. The agricultural harvesting machine according to claim 8 , wherein the crop sensor system has at least one camera sensor, and wherein the computing device is configured to expand the crop stand height map based on sensor signals of the at least one camera sensor.