Shoes for ball sports

That which is claimed is: 1. A shoe for ball sports, comprising: an upper having an outer layer, the outer layer comprising at least one elastic portion configured to elastically deform its shape relative to another portion of the outer layer; an actuator configured to change at least one surface property of the at least one elastic portion of an outer surface of the outer layer of the upper; a sensor configured to be sensitive to movements of the shoe; and a processing unit connected to the actuator and the sensor and configured to process sensor data retrieved from the sensor and to cause the actuator to change the at least one surface property of the at least one elastic portion of the outer surface of the upper if a predetermined event is detected in the sensor data. 2. The shoe according to claim 1 , wherein the at least one surface property is the surface structure of the at least one elastic portion of the outer surface. 3. The shoe according to claim 1 , wherein the at least one surface property is the friction of the at least one elastic portion of the outer surface. 4. The shoe according to claim 1 , wherein the at least one surface property is the surface area of the at least one elastic portion of the outer surface. 5. The shoe according to claim 1 , wherein the shoe further comprises: a plurality of fins arranged below the portion of the outer surface of the upper and connected to the actuator, such that the fins can be lowered or raised by means of the actuator to change the at least one surface property of the at least one elastic portion of the outer surface. 6. The shoe according to claim 1 , wherein the actuator is a pneumatic valve, and the shoe further comprises: an air pump configured to provide pressurized air to the pneumatic valve; and at least one inflatable element arranged under the at least one elastic portion of the outer surface of the upper; wherein the pneumatic valve is configured to provide pressurized air to the inflatable element to inflate the inflatable element and to change the at least one surface property of the at least one elastic portion of the outer surface. 7. The shoe according to claim 6 , wherein the air pump is configured to generate pressurized air through actions of a player wearing the shoe. 8. The shoe according to claim 1 , wherein the shoe further comprises: a plurality of pins arranged below the at least one elastic portion of the outer surface of the upper; and an undulating structure arranged below the plurality of pins and connected to the actuator, such that the undulating structure can be moved relative to the pins to lower or raise the pins with respect to the outer surface to change the at least one surface property of the at least one elastic portion of the outer surface. 9. The shoe according to claim 1 , wherein the at least one elastic portion of the outer surface comprises a plurality of flaps, which are configured to be lowered or raised by means of the actuator. 10. The shoe according to claim 1 , wherein the actuator comprises a shape memory alloy or an electrical motor. 11. The shoe according to claim 1 , wherein the sensor is an accelerometer, a gyroscope, or a magnetic field sensor. 12. The shoe according to claim 1 , wherein the outer surface is smooth. 13. The shoe according to claim 1 , further comprising: a sole, wherein the sensor, actuator, and processing unit are integrated in the sole. 14. The shoe according to claim 1 , wherein the predetermined event is a kick. 15. The shoe according to claim 1 , wherein the predetermined event is a short pass, long pass, shot, or control of a ball. 16. The shoe according to claim 1 , wherein the processing unit is configured to detect the predetermined event by being configured to: retrieve a time-series of sensor data from the sensor; preprocess the time-series; segment the time-series in a plurality of windows; extract a plurality of features from the sensor data in each of the plurality of windows; and estimate an event class associated with the plurality of windows based on the plurality of features extracted from the sensor data in the plurality of windows. 17. The shoe according to claim 16 , wherein the processing unit is configured to preprocess the time-series through digital filtering using a non-recursive moving average filter, a Cascade Integrator Comb filter or a filter bank. 18. The shoe according to claim 16 , wherein the event class comprises at least the event to be detected and a NULL class associated with the sensor data that does not belong to a specific event. 19. The shoe according to claim 16 , wherein the features are based at least on one of temporal, spatio-temporal, spectral, or ensemble statistics by applying, for example, wavelet analysis, principal component analysis, or Fast Fourier Transform. 20. The shoe according to claim 16 , wherein the features are based on one of simple mean, normalized signal energy, movement intensity, signal magnitude area, correlation between axes, maximum value in a window, minimum value in a window, maximum detail coefficient of a wavelet transform, correlation with a template, projection onto a principal component of a template, distance to an eigenspace of a template, spectral centroid, bandwidth, or dominant frequency. 21. The shoe according to claim 16 , wherein the processing unit is configured to segment the time-series in the plurality of windows based on a sliding window. 22. The shoe according to claim 16 , wherein the processing unit is configured to segment the time-series in the plurality of windows based on at least one condition present in the time-series. 23. The shoe according to claim 22 , wherein the at least one condition is the crossing of the sensor data of a defined threshold or the matching of a template using correlation, Matched Filtering, Dynamic Time Warping, or Longest Common Subsequence and its sliding window variant, warping Longest Common Subsequence. 24. The shoe according to claim 16 , wherein the processing unit is configured to estimate the event class based on a Bayesian classifier such as Naïve Bayes classifier, a maximum margin classifier such as Support Vector Machine, an ensemble learning algorithm such as AdaBoost classifier and Random Forest classifier, a Nearest Neighbor classifier, a Neural Network classifier, a Rule based classifier, or a Tree based classifier. 25. The shoe according to claim 16 , wherein the processing unit is configured to estimate the event class based on probabilistic modeling the sequential behavior of the events and a NULL class by Conditional Random Fields or dynamic Bayesian networks. 26. The shoe according to claim 16 , wherein the processing unit is configured to estimate the event class based on a hybrid classifier by being configured to: discriminate between different phases of the event to be detected and a NULL class, wherein the NULL class is associated with the sensor data that does not belong to a specific event; and model the sequential behavior of the event and the NULL class by dynamic Bayesian networks. 27. The shoe according to claim 16 , wherein the processing unit is configured to estimate based on a classifier that has been trained based on supervised learning. 28. The shoe according to claim 16 , wherein the processing unit is configured to estimate based on a classifier t