Laser material processing system

The invention claimed is: 1. A laser material processing system for processing a workpiece by means of a laser beam, comprising: an optical system having at least one optical component for focusing the laser beam to form a focal point on the workpiece or in a defined position relative to the workpiece; at least one inertial sensor for detecting a transitional and/or rotational acceleration of the at least one optical component of the optical system and/or the workpiece; and a processing unit connected to the at least one inertial sensor for determining a relative transitional and/or rotational acceleration between the focal point and the workpiece, wherein the processing unit comprises a real-time clock for allocating a real-time timestamp to each sensor data and is adapted to calculate an actual velocity and/or an actual relative position between the focal point and the workpiece on the basis of the detected transitional and/or rotational acceleration by integrating over time by using the allocated timestamps and having a respective initial velocity (v 0 ) and/or a respective initial relative position (x 0 ), and wherein the processing unit is adapted to control an actuator system to regulate an actual relative position between the focal point and the workpiece to a set relative position by positioning the at least one optical component and/or the workpiece on the basis of the calculated actual relative position between the focal point and the workpiece. 2. The laser material processing system according to claim 1 , further comprising an actuator system for adjusting a relative position between the focal point and the workpiece by positioning the at least one optical component and/or the workpiece. 3. The laser material processing system according to claim 1 , wherein the processing unit is adapted to control the current laser power of the laser beam in accordance with the calculated relative actual velocity and/or the calculated actual relative position between the focal point and the workpiece. 4. The laser material processing system according to claim 1 , wherein at least two inertial sensors are fixed relative to one optical component of the optical system and/or the workpiece, and wherein the processing unit is adapted to calculate a mean transitional and/or rotational acceleration on the basis of the acceleration data from the at least two inertial sensors. 5. The laser material processing system according to claim 1 , wherein the at least one inertial sensor is fixed to the workpiece. 6. The laser material processing system according to claim 1 , further comprising a moveable table for holding the workpiece on a holding part thereof, wherein the at least one inertial sensor is fixed to the holding part of the moveable table. 7. The laser material processing system according to claim 1 , further comprising a laser processing head having a casing for accommodating the optical system, wherein the at least one inertial sensor is fixed to the casing of the laser processing head. 8. The laser material processing system according to claim 1 , wherein the optical system comprises a focusing lens for focusing the laser beam on the workpiece or to a defined position relative to the workpiece, and the at least one inertial sensor is mounted in a fixed position relative to the focusing lens. 9. The laser material processing system according to claim 1 , wherein the optical system further comprises: an optical fiber; and a collimator optical unit for collimating the laser beam emitted from the optical fiber, wherein the at least one inertial sensor is mounted in a fixed position relative to the collimator optical unit. 10. The laser material processing system according to claim 1 , wherein the optical system comprises at least one plane mirror or focusing mirror, to which the at least one inertial sensor is fixedly mounted. 11. The laser material processing system according to claim 1 , further comprising: a camera with an imaging optical unit arranged upstream thereof in the beam path of the laser beam and serving for observing a processing region of the workpiece, which is processed by means of the laser beam; and an illumination device, the light from which is coaxially coupled into the beam path of the laser beam by means of a beam splitter in order to illuminate the processing region of the workpiece, wherein the processing unit is adapted to process the image data of the camera by using the calculated actual relative velocity and the calculated actual relative position between the focal point and the workpiece for compensating a mismatch of position and orientation of a laser processing area in a plurality of image frames. 12. The laser material processing system according to claim 1 , wherein the processing unit is adapted to classify the laser processing process on the basis of feature values derived from data from at least one sensor comprising a camera, an air-borne or solid-borne acoustic sensor, or a photo diode sensor for wave length ranges in the infrared, visible and ultraviolet range, wherein the calculated actual velocity is further used for the classification result as a feature value. 13. The laser material processing system according to claim 4 , wherein the processing unit is adapted to calculate a mean transitional and/or rotational acceleration on the basis of the acceleration data from the at least two inertial sensors fixed to one optical component of the optical system or the workpiece, or is adapted to calculate a mean transitional and/or rotational acceleration on the basis of the acceleration data from the at least two inertial sensors fixed to a optical component of the optical system and the workpiece, or is adapted to calibrate the at least two inertial sensors at subsequent time points, to reduce the signal-to-noise ratio of the acceleration data. 14. A method for processing a workpiece by means of a laser material processing system according to claim 1 , comprising the steps of: focusing a laser beam in order to form a focal point on the workpiece or in a defined position relative to the workpiece by means of a optical system having at least one optical component, detecting transitional and/or rotational acceleration of the at least one optical component of the optical system and/or the workpiece by means of at least one inertial sensor, allocating a real-time timestamp to each sensor data; calculating an actual velocity and/or an actual relative position between the focal point and the workpiece on the basis of the detected transitional and/or rotational acceleration by integrating over time by using the allocated timestamps and having a respective initial velocity (v 0 ) and/or a respective initial relative position (x 0 ); determining a relative transitional and/or rotational acceleration between the focal point and the workpiece by means of a processing unit connected to the at least one inertial sensor; and controlling an actuator system to regulate an actual relative position between the focal point and the workpiece to a set relative position by positioning the at least one optical component and/or the workpiece on the basis of the calculated actual relative position between the focal point and the workpiece.