Dielectric barrier discharge for ballast water treatment using optimized voltage shape control

The invention claimed is: 1. A controller for controlling a fluid treatment by a Dielectric Barrier Discharge system, the controller comprising: a control unit and a monitoring system, the monitoring system including one or more sensor devices, the one or more sensor devices being configured to monitor the strength of an effect caused by a discharge created by the Dielectric Barrier Discharge system, and to transmit sensor data indicative of the strength of the effect to the control unit, wherein the one or more sensor devices are configured to monitor at least one of an amount of generated plasma, a current flow, a voltage, a charge, chemical agents, a flow of a fluid, a time duration of a discharge, and a biological status of a discharge, wherein the biological status includes detecting living organisms in the fluid inflowing and outflowing in the Dielectric Barrier Discharge system, wherein the control unit is configured to be operatively coupled to a high-voltage pulse generator of the Dielectric Barrier Discharge system for controlling the generation of high-voltage pulses by the high-voltage pulse generator, wherein at least one of the one or more sensor devices is configured to monitor an occurrence of a back discharge, and wherein the control unit uses the sensor data to adapt a pulse control signal configured to adjust the Dielectric Barrier Discharge system so that a back discharge overlaps with a falling edge of at least one of the high-voltage pulses. 2. The controller according to claim 1 , wherein at least one of the one or more sensor devices for monitoring a plasma is an optical sensor, adapted to optically detect the amount of the generated plasma. 3. The controller according to claim 1 , wherein the control unit is in communication with the monitoring system and adapted to analyze signals from the monitoring system which are related to a system status of the Dielectric Barrier Discharge system. 4. The controller according to claim 1 , wherein the control unit is further configured to adapt parameters of at least one of a DC Power supply, a high voltage pulse generator, a fluid system. 5. The controller according to claim 4 , wherein the parameters comprise one or more parameters of the group: a voltage amplitude of a pulse, a length or duration of a pulse, a rise-time of a pulse, a repetition frequency of a pulse. 6. The controller according to claim 5 , wherein the high-voltage pulses are a single pulse or a pulse sequence. 7. The controller according to claim 6 , wherein the control unit is configured to adapt parameters of one or more pulses in the pulse sequence, wherein the parameters comprise one or more of the group: a voltage amplitude, a rise-time, a polarity, a pulse length, a repetition of pulses, a pulse-pause relation. 8. The controller according to claim 6 , wherein the pulse sequence comprises pulses with changing polarities. 9. A Dielectric Barrier Discharge system, comprising the controller according to claim 1 , and the high-voltage pulse generator. 10. A method of treating a fluid by a Dielectric Barrier Discharge system, the method comprising: controlling, via a control unit, a generation of high-voltage pulses by a high-voltage pulse generator of the Dielectric Barrier Discharge system; creating, by the high-voltage pulses, a discharge by the Dielectric Barrier Discharge system affecting the fluid; monitoring, via one or more sensor devices, the strength of an effect caused by the discharge and generating sensor data indicative of the strength of the effect, wherein the one or more sensor devices are configured to monitor at least one of an amount of generated plasma, a current flow, a voltage, a charge, chemical agents, a flow of a fluid, a time duration of a discharge, and a biological status of a discharge, wherein the biological status includes detecting living organisms in the fluid inflowing and outflowing in the Dielectric Barrier Discharge system, wherein at least one of the one or more sensor devices is configured to monitor an occurrence of a back discharge; and adapting the controlling of the generation of the high-voltage pulses based on the sensor data, wherein the control unit uses the sensor data to adapt a pulse control signal configured to adjust the Dielectric Barrier Discharge system so that a back discharge overlaps with a falling edge of at least one of the high-voltage pulses. 11. The method according to claim 10 , the method being used for optimizing the high voltage pulses for a plasma reactor in the Dielectric Barrier Discharge system, wherein the monitoring the strength of the effect includes monitoring one or more status values of at least one of a plasma, a current flow, a voltage, a charge, chemical agents, a flow of a fluid or a biological status or a time duration of a discharge, and wherein the adapting of the controlling includes adjusting with a control unit, based on the status values, parameters of at least one of a DC Power supply, a pulse generator, a fluid system. 12. The method according to claim 11 , wherein the parameters comprise one or more parameters of the group: a voltage amplitude of a pulse, a length/duration of a pulse, a rise-time of a pulse, a repetition frequency of a pulse. 13. The method of claim 10 , wherein: the monitoring the strength of the effect includes monitoring, with the one or more sensor devices, a fluid, treated with the Dielectric Barrier Discharge system, and the adapting of the controlling includes: inputting data from the one or more sensor devices, representing a status of the treated fluid, into a control unit; processing, in the control unit, status data of the treated fluid; and adapting parameters of a high-voltage pulse generator, which feeds high-voltage pulses in the Dielectric Barrier Discharge system, with the control unit, to generate pulses to achieve a predetermined status of the treated fluid. 14. The method for operating a Dielectric Barrier Discharge system according to claim 13 , wherein the sensors devices are configured to monitor at least one of a plasma, an input power, a current flow, a voltage, a charge, chemical agents, a flow of a fluid or a biological status or a time duration of a discharge. 15. The method for operating a Dielectric Barrier Discharge system according to claim 14 , wherein the biological status comprises detecting living organisms in the treated fluid. 16. The method for operating a Dielectric Barrier Discharge system according to claim 13 , wherein the treated fluid is ballast water. 17. The controller according to claim 1 , wherein the control unit adapts a pulse shape and a pulse sequence of the high-voltage pulses in real-time to optimize energy consumption of the Dielectric Barrier Discharge system. 18. A controller for controlling a fluid treatment by a Dielectric Barrier Discharge system, the controller comprising: a control unit and a monitoring system, the monitoring system including one or more sensor devices, the sensor devices being configured to monitor the strength of an effect caused by a discharge created by the Dielectric Barrier Discharge system, and to transmit sensor data indicative of the strength of the effect to the control unit, wherein the control unit is configured to be operatively coupled to a high-voltage pulse generator of the Dielectric Barrier Discharge system for controlling the generation of high-voltage pulses by the high-voltage pulse generator, wherein at least one of the one or more sensor devices is configured to monitor an occurrence of a back discharge, wherein the control unit uses t