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Xavier Bonnin and Davide Aguglia

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Presentation on theme: "Xavier Bonnin and Davide Aguglia"— Presentation transcript:

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2 Xavier Bonnin and Davide Aguglia
A Hybrid Bouncer System for Highly Repeatable and Precise Klystron Modulators Xavier Bonnin and Davide Aguglia CERN – European Organization for Nuclear Research, Technology department, Electrical Power Converter Group PPC 2017

3 Context: Compact Linear Collider (CLIC)
Parameter Value Unit Nb of klystrons 1300 Voltage 180 kV Current 160 A Pulse length 140 µs Rep. Rate 50 Hz Stability 0.85 % Repeatability 10 ppm PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

4 Context: Compact Linear Collider (CLIC)
Parameter Value Unit Nb of klystrons 1080 Voltage 180 kV Current 160 A Pulse length 148 µs Rep. Rate 50 Hz Stability 0.85 % Repeatability 10 ppm Large number of modulators => Reliability Capacitor discharge based topology High level of constraint on the precision Compensation techniques are needed (bouncer circuits) PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

5 Capacitor discharge based modulator
Bouncer circuit: Goal: compensating the cap. bank voltage droop Variety of technical solutions Active switch(es) Linear mode / switching mode / both Passive resonant bouncer topologies PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

6 Bouncer circuits examples
Corr Ripple Flex. Robust Eff Linear ++ No + - PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

7 Bouncer circuits examples
Corr Ripple Flex. Robust Eff Linear ++ No + - Switching Yes PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

8 Bouncer circuits examples
Corr Ripple Flex. Robust Eff Linear ++ No + - Switching Yes Corr Ripple Flex. Robust Eff Linear ++ No + - Switching Yes Hybrid Passive PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

9 Passive bouncer with linear switches
Requirements: Vb < 0 or >0 ic < 0 or >0 => 4-Q topology is needed PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

10 Passive bouncer with linear switches
Requirements: Vb1 > 0 ic < 0 or >0 => 2-Q topology is needed Other solution 2 switches in linear mode Additionnal grounded power supply PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

11 Passive bouncer with linear switches
Other solution PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

12 Designing procedure Linear analysis:
Real Time compensation by the linear circuit « Feedforward » compensation by the passive bouncer PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

13 Optimize this term in order to minimize the pulse error
Designing procedure Linear analysis: Real Time compensation by the linear circuit « Feedforward » compensation by the passive bouncer Optimize this term in order to minimize the pulse error PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

14 Optimize this term in order to minimize the pulse error
Designing procedure Linear analysis: Real Time compensation by the linear circuit « Feedforward » compensation by the passive bouncer Optimize this term in order to minimize the pulse error PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

15 Optimize this term in order to minimize the pulse error
Designing procedure Linear analysis: Real Time compensation by the linear circuit « Feedforward » compensation by the passive bouncer Optimize this term in order to minimize the pulse error New set of components and initial values PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

16 Designing procedure Parameters: Components: Cb, L, Ltransfo
Initial conditions: Vin0, iL0 and Vb0 Constraints (equality): Energy conservation in the bouncer (=steady state) Sensitivity analysis (normalized function): 1% of error 100% deviation 10% of error  60% deviation PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

17 Designing procedure Linear analysis:
Real Time compensation by the linear circuit « Feedforward » compensation by the passive bouncer PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

18 Designing procedure Linear analysis: LF compensator HF compensator
Real Time compensation by the linear circuit « Feedforward » compensation by the passive bouncer LF compensator HF compensator PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

19 Performances RMS error: 1500ppm Losses: 0.9% of Wpulse
Simulation results PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

20 Monte Carlo simulation results
Performances Sensitivity analysis: 500 runs Parameters are randomly chosen in a +/-10% range around the optimal solution (bouncer components only) Impact on precision and losses ? Worst accuracy: 2600ppm With only passive bouncer: 9700ppm Highest losses: 1.3% of Wpulse With only linear ballast: >5% of Wpulse Monte Carlo simulation results PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

21 Experimental set up PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

22 Conclusion Capacitor discharge based modulators need a compensation circuit (bouncer) The presented topology aims at merging the advantages of a passive bouncer and an active linear stage Acceptable level of losses Fairly simple topology and control strategy High bandwidth (linear) Compensation of spread thank to a high bandwidth feedback control PPC 2017 Evaluation of a Hybrid Bouncer System for High Precision Klystron Modulators

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