Blood pump control system and method for controlling a blood pump

The invention claimed is: 1. A method for generating a signal indicative of a valve state, the method comprising: receiving a time-series signal representing a pressure difference between a first blood pressure and a second blood pressure over at least one heartbeat cycle; deriving at least one signal characteristic from the time-series signal, wherein the signal characteristic includes a relationship between, or a value derived from, at least two different data points of the time-series signal; classifying the valve state of a heart valve during the at least one heartbeat cycle based on the at least one signal characteristic, wherein the time-series signal over the at least one heartbeat cycle is separated into a plurality of separated data sets, each of the separated data sets comprising data from only one corresponding heartbeat cycle, and wherein the valve state is classified for at least two of the separated data sets; generating the signal indicative of the valve state based on the classification; and controlling a speed of a blood pump based on the signal indicative of the valve state. 2. The method of claim 1 , wherein the at least one derived signal characteristic is based on a waveform of the time-series signal. 3. The method of claim 1 , wherein the at least one signal characteristic includes one of the following: a difference between a minimal and a maximal signal value during a heartbeat cycle; an extremal value of a derivative of the signal between a minimal and a maximal signal value during a heartbeat cycle; a quotient of a difference between a minimal and a maximal signal value during a heartbeat cycle and a maximal signal value within a predetermined number of previous heartbeat cycles; a difference between an end value defined by an intersection value of a tangent line through an extremal point and a tangent line through a minimal signal value and the minimal signal value, DUR; an area bordered by the tangent lines, AREA; and an angle between the tangent line through an extremal point and a line connecting the minimal signal value and a value of the time-series signal corresponding to the end value (α). 4. The method of claim 1 , wherein the valve state is classified by a trained classifier. 5. The method of claim 1 , wherein two or more signal characteristics are derived. 6. The method of claim 1 , wherein two or more signal characteristic are derived and classifying the valve state based on the two or more signal characteristics. 7. The method of claim 1 , wherein the first blood pressure is representative of a ventricular pressure and the second blood pressure is representative of an aortic pressure. 8. The method of claim 1 , wherein the heart valve is any of: an aortic valve, a pulmonary valve, or a mitral valve. 9. A blood pump control system including: a signal characterizing circuit configured to derive at least one signal characteristic from a time-series signal indicative of a pressure difference between a first blood pressure and a second blood pressure over at least one heartbeat cycle, wherein the signal characteristic includes a relationship between, or a value derived from, at least two different data points of the time-series signal; and a classifying circuit configured to determine a classification of a valve state of a heart valve for at least parts of the time-series signal during the at least one heartbeat cycle based on the at least one signal characteristic, wherein the classifying circuit is configured to separate the time-series signal over the at least one heartbeat cycle into separated data sets, wherein each separated data set including data for only one corresponding heartbeat cycle, and wherein the classification of the valve state includes a corresponding classification for at least two of the separated data sets; and a controller operably connectable to a blood pump and configured to adjust a speed of the blood pump based on the classification of the valve state. 10. The system of claim 9 , wherein the classifying circuit is further configured to generate a signal indicative of the valve state of the heart valve based on the classification. 11. The system of claim 9 , wherein the controller is configured to receive a valve state index (VSI) signal and adjust a speed of a movable element of the blood pump based on the VSI signal, wherein the VSI signal is based on the classification. 12. A method comprising: deriving at least one signal characteristic from time-series data of a signal over at least one heartbeat cycle, the signal representing a pressure difference between a first pressure and a second pressure over the at least one heartbeat cycle, wherein the at least one signal characteristic includes a relationship between, or a value derived from, at least two different data points of the time-series data; classifying a valve state of a heart valve during the at least one heartbeat cycle based on the signal characteristic, wherein the time-series data over the at least one heartbeat cycle is separated into a plurality of separated data sets, each of the separated data sets including data for only one corresponding heartbeat cycle, and wherein the valve state is classified for at least two of the separated data sets; and controlling a heart pump based on the classification of the valve state. 13. The method of claim 12 wherein the controlling the heart pump comprises adjusting a speed of the heart pump based on the classification of the valve state.