Method for reducing dynamic loads of cranes

What is claimed is: 1. A device for reducing resonant vibrations and dynamic loads of cranes, the device comprising: a boom winch configured to control a luffing motion of a pivoting boom; and a hoist winch configured to control a vertical distance between a boom tip and a pay load of the crane; a boom winch speed controller coupled to the boom winch; and a hoist winch speed controller coupled to the hoist winch; wherein the device is configured to acquire resonance frequencies of a coupling of the pivoting boom and the pay load from at least inertia data of the pivoting boom and stiffness data on at least a boom rope coupled to the boom winch and a hoist rope coupled to the hoist winch, the resonance frequencies including a first resonance frequency and a second resonance frequency, the second resonance frequency being lower than the first resonance frequency; wherein the boom winch speed controller or the hoist winch speed controller is configured to automatically modify a motion of the boom winch or a motion of the hoist winch, respectively, to induce a damping inducing winch motion; wherein the boom winch speed controller comprises a proportional integral (PI)-type speed controller that is tuned to absorb vibration energy at the second resonance frequency; and wherein the hoist winch speed controller comprises a PI-type speed controller that is tuned to absorb vibration energy at the first resonance frequency. 2. The device of claim 1 , wherein the boom winch speed controller includes an integral factor and a proportional factor, and wherein the hoist winch speed controller includes an integral factor and a proportional factor; wherein the integral factor of the boom winch speed controller is substantially equal to a product of an effective inertia of the boom winch and a squared angular boom resonance frequency; wherein the integral factor of the hoist winch speed controller is substantially equal to a product of an effective inertia of the hoist winch and the squared angular boom resonance frequency; and wherein the proportional factor of the boom winch and the proportional factor of the hoist winch each comprise linear combinations of an inverse of the resonance frequencies squared. 3. The device of claim 2 , wherein the proportional factor of the boom winch speed controller is proportional to the square of an effective stiffness of a crane pedestal and the boom rope and inversely proportional to a boom inertia and a square of the angular boom resonance frequency squared; and wherein the proportional factor of the hoist winch speed controller is proportional to the square of an effective stiffness of the hoist rope and inversely proportional to an inertia of the pay load and a square of an angular load resonance frequency. 4. The device of claim 3 , wherein at least one of the boom winch speed controller and the hoist winch speed controller includes an inertia-compensating term, wherein the inertia-compensating term comprises a product of a time derivative of a measured speed of the corresponding one of the boom winch or hoist winch, and a fraction of a mechanical winch inertia of the corresponding one of the boom winch or hoist winch. 5. A method for reducing resonant vibrations and dynamic loads of cranes, wherein a vertical motion of a pay load is controlled by a boom winch controlling a luffing motion of a pivoting boom and a hoist winch controlling a vertical distance between a boom tip and the pay load, the method comprising: determining resonance frequencies of a coupling of the pivoting boom and the pay load from at least from inertia data of the pivoting boom and stiffness data on at least a boom rope coupled to the boom winch and a hoist rope coupled to the hoist winch, the resonance frequencies including a first resonance frequency and a second resonance frequency, the second resonance frequency being lower than the first resonance frequency; and automatically modifying a motion of the boom winch or a motion of the hoist winch to induce a damping inducing winch motion in the boom winch or hoist winch, respectively, by tuning a proportional integral (PI)-type boom winch speed controller coupled the boom winch or a PI-type hoist winch speed controller coupled to the hoist winch; wherein the boom winch speed controller is tuned to absorb vibration energy at the second resonance frequency; and wherein the hoist winch speed controller is tuned to absorb vibration energy at the first resonance frequency. 6. The method of claim 5 , wherein tuning the PI-type boom winch speed controller further comprises: choosing an integral factor of the boom winch speed controller that is substantially equal to a product of an effective inertia of the boom winch and a squared angular boom resonance frequency; and choosing a proportional factor of the boom winch speed controller that comprises a linear combination of an inverse of the resonance frequencies squared. 7. The method of claim 6 , wherein the proportional factor of the boom winch speed controller is proportional to a square of an effective stiffness of a crane pedestal and the boom rope and inversely proportional to a boom inertia and a square of the angular boom resonance frequency squared. 8. The method of claim 5 , wherein tuning the PI-type hoist winch speed controller further comprises: choosing an integral factor of the hoist winch speed controller that is substantially equal to a product of an effective inertia of the hoist winch and a squared angular boom resonance frequency; and choosing a proportional factor of the hoist winch speed controller to comprise a linear combination of an inverse of the resonance frequencies squared. 9. The method of claim 8 , wherein the proportional factor of the hoist winch speed controller is proportional to the square of an effective stiffness of the hoist rope and inversely proportional to an inertia of the pay load and a square of an angular load resonance frequency.