1. 1 Current Status of The Control System for J-PARC Accelerator Complex Hiroshi YOSHIKAWA J-PARC Center at KEK/JAEA October 16, 2007 ICALEPCS2007 at Knoxville

2. 2 Nuclear Transmutation J-PARC Facility J-PARC = Japan Proton Accelerator Research Complex Joint Project between KEK and JAEA 3 GeV Synchrotron (25 Hz, 1MW) Hadron Beam Facility Materials and Life Science Experimental Facility Neutrino to Kamiokande 50 GeV Synchrotron (0.75 MW) 500 m Linac (330m)

3. 3 Location of J-PARC at Tokai Tsukuba Tokai 1 hour 295 km JAEA

4. 4 Goals at J-PARC Need to have high-power proton beams  MW-class proton accelerator (current frontier is about 0.1 MW) R&D toward Transmutation at 0.6 GeV Nuclear & Particle Physics at 50 GeV Materials & Life Sciences at 3 GeV

5. 5 Phase 1 and Phase 2 –Phase 1 + Phase 2 = 1,890 Oku Yen (= $1.89 billions if $1 = 100 Yen). –Phase 1 = 1,527 Oku Yen (= $1.5 billions) for 〜 8 years. –JAEA: 860 Oku Yen (56%), KEK: 667 Oku Yen (44%). JAEA Portion KEK Portion

6. 6

7. 7 J-PARC Control System Protect from Radiation –Intelligent Beam Control Keep stability of electro-magnetic field Keep minimum beam loss Predict beam behavior System identification and definition of response function By link of operation and simulation By link of operation and database Integrated Operation Environment –Effective use of software technology In the process of developing

8. 8 Function of Safety Radiation Measurement System –Legal management of the area boundary Personnel Protection System (PPS) –Make and keep the boundary condition of closed space which is allowed existence of the beam –Stop the beam when the condition breaks Machine Protection System (MPS) –Protect machine from high power beam bombardment –Stop the beam when something is wrong Computer Control System –Automatic correction, FB, FF –Suggest the optimum parameters

9. 9 PPS

10. 10 MPS MPS hardware configuration. When the threshold is exceeded, the loss monitor module with only the analog circuit is fired.

11. 11 MPS Fast beam stop procedure using Machine Protection System (MPS) 1: The beam loss is detected by the loss monitor. 1: The beam loss is detected by the loss monitor. 2: Loss signal transmission to the RFQ part using MPS. 2: Loss signal transmission to the RFQ part using MPS. 3: RFQ power off and Ion source injection timing removing. 3: RFQ power off and Ion source injection timing removing. 4: Insertion of the Beam stopper 4: Insertion of the Beam stopper 5: Because MPS don't want to cool the RFQ, power is turned on again quickly. 5: Because MPS don't want to cool the RFQ, power is turned on again quickly.

12. 12

13. 13

14. 14

15. 15 NETWORK Basic Composition Star Connection around CCR

16. 16 NETWORK Standard protocol for redundancy can not make the performance that no connection loss when the pass way is switched. We selected the protocol of the vender dependence. For ease of physical fiber topology, we use the combination of ESRP and EAPS.

17. 17 NETWORK ESRP test by single fault ESRP test by double fault No matter appears when the power of switch is down, or when fiber is disconnected. When the route revives, the connection doesn't become interrupted.

18. 18 NETWORK EAPS test by single faultEAPS test by double fault Time of route change < 1.2sec (including route reviving. Any TCP connection is not closed at this route change.)

19. 19 NETWORK

20. 20 TIMING SYSTEM Receiving module E/O-O/E Converter Fanout SEND IOC RECEIVE IOC Ether net Reflective memory net output Clock, Trigger, TypeCode

21. 21 TIMING SYSTEM Ch1Ch2ch3ch4vh5ch6ch7h8 T1 T2 T3 T4 T5 T6 T7 T8 T9 T10 ・・ ・ Ch1Ch2ch3ch4vh5ch6ch7h8 T1 T2 T3 T4 T5 T6 T7 T8 T9 T10 ・・ ・ LUT of a receiving module Ch1Ch2ch3ch4vh5ch6ch7h8 T1 T2 T3 T4 T5 T6 T7 T8 T9 T10 ・・ ・ T3 T5 T3 T5 T3 T5 T3 Type train of sending module

22. 22 TIMING SYSTEM Single Shot is generated for the initial commissioning –Effective to reduce activation Type code means operation mode and beam course Individual delay trimming can be done without stopping the beam –Two way of changing delay time. Delay time changing of selected channels can be done simultaneously

23. 23 Data Acquisition On the EPICS, fundamental data can be acquired. High power beam handling required the traceable data of each shot, selected shot, event occurred shot. Trade off of data size (resolution, repetition) with transport –Separate storing data and gathering data Concept of Selecting Data –We need the data at the event. (around the event, before and after)

24. 24 Before & after data is transmitted to PC. Pulse is Deformed Record Ring buffer Pulse shape Check Abnormal wave-form recorder LAN ・ 10MS/s or 200MS/s (2 types), 12bit(±10V), insulated each CH. ・ Ring buffer size: 192MB wave-form (50pps) Surveillance function Data Acquisition

25. 25 Data Acquisition WER Event Data Collection Server Monitoring Data Server WER ・・ ・ WER System Configuration Trigger Counter BPM 4 BPM 6 BPM 9 CT threshold *WER: Wave Endless Recorder Event (trigger number) Event Data request

26. 26 GUI

27. 27 GUI

28. 28 GUI

29. 29 SUMMARY Infrastructure of the J-PARC control system was completed. –Covered area will be extended to MR, MLF next year. Fundamental function of PPS, MPS, TS and Data Acquisition are successfully established for the 1 st stage of commissioning. High Level Application is developed on the Integrated Operation Environment –IOE is written in java, and it ’ s API can merge several simulation and other IOE tools