Isolde new vistar and Isolde beam interlocks

1. Isolde new vistar and Isolde beam interlocks OP DAYS 2009 Emiliano Piselli - Jose-Luis Sanchez Alvarez BE-OP-PSB

2. Outline ISOLDE Where? What? Isolde Beam Vistar Display infos VISTAR... FDF (Fixed Display Framework) Interlocks system Configuration GUI Conclusions

3. ISOLDE

4. ISOLDE On-Line Isotope Mass Separator Spallation Fission 1.4GeV p Fragmentation Cortesy E. Siesling

5. ISOLDE On-Line Isotope Mass Separator Cortesy E. Siesling

6. ISOLDE PSB layout

7. ISOLDE GPS...General Purpose Separator HRS...High Resolution Separator 7

8. ISOLDE Isolde layout GPS target HRS target BTY line from PSB Cortesy E. Siesling 8

9. ISOLDE Isolde layout HRS GPS Protons Physics! Cortesy E. Siesling

10. ISOLDE Target Cortesy E. Siesling

11. ISOLDE Secondary beam accelerated VERT HOR Cortesy E. Siesling

12. p+ p+ p+ p+ p+ p+ ISOLDE Target Target Converter Converter Target Standard Cortesy E. Siesling 12

13. ISOLDE Proton beam focusing • Standard focus • Waist of beam at target(converter targets) Fragmentation, Spallation, Fission Fragmentation, Spallation,Fission n n n n Cortesy E. Siesling

14. ISOLDE Focusing elements GPS focus HRS focus Cortesy E. Siesling

15. ISOLDE Focus settings • At each target-change:Focus settings of the proton beam depend on the type of target and will be applied and verified by the ISOLDE Machine Supervisor Cortesy E. Siesling

16. ISOLDE WrongBeam Liquid metal target: Cracked container welds Converter target: Twisted W convertor rod Cortesy E. Siesling

17. ISOLDE Steering elements GPS steering HRS steering

18. ISOLDE Steering settings • At each target-change:Proton Scan: Final steering of the proton beam is done by the ISOLDE Machine Supervisor Cortesy E. Siesling

19. ISOLDE Isolde beam • Focus settings… • Steering settings… • Max intensities (ppp & pps)

20. VISTAR Display BEAM informations CONTACT TARGET

21. VISTAR 21

22. VISTAR 22

23. VISTAR 23

24. VISTAR 24

25. VISTAR FDF (Fixed Display Framework) Library used to create a controls & monitoring java-based fixed displays. • Multiple GUI solutions are supported: • XML definition with SwiXML (also generated) for simple layouts • Pure Java JFrames (with any Java GUI Builder) for complicated cases It integrates multiple CERN components like AscBeans (lables, tables, etc) & JDataViewer It integrates integrates other basic components like TimeDate & “Diode”… Main principle used to create FDs is to define them in XML.The XML files contain a description of all the components (labels, charts, etc.) and layout of each screen. FDF architecture uses japc-monitoring and this configuration typically contains the XML file definition of the japc parameters to be monitored.

26. VISTAR

27. <Plots> <Plot id="hrs_ppp" update="HISTORY" title="HRS protons per pulse"> <StyleSheets> <StyleSheet> chart { legendVisible : false; legendPosition : SOUTH; } dataset[name='ppp'] { stroke : stroke(2); markerSize : 5; markerType : DIAMOND; strokeColor : #000082; } axis[axis=Y] { min: 0.0; max: 4400.0; } scale[axis='Y'] { title: "ppp"; } </StyleSheet> </StyleSheets> <Serie parameterId="ppp" name="Protons per pulse" maximumItemCount="1000"> <YValues field="value"/> </Serie> </Plot> <Plot id="hrs_curr" update="HISTORY" title="HRS protons current"> <StyleSheets> <StyleSheet> chart { legendVisible : false; legendPosition : SOUTH; } dataset[name='prCurr'] { stroke : stroke(2); markerSize : 5; markerType : SQUARE; strokeColor : #000082; } axis[axis=Y] { min: 0.00; max: 2.20; } scale[axis='Y'] { title: "uA"; } </StyleSheet> </StyleSheets> <Serie parameterId="prCurrA" name="proton current in uA" maximumItemCount="1000"> <YValues field="value"/> </Serie> </Plot> </Plots>

28. Interlock system TARGET Display BEAM BEAM informations CONTACT Interlock system

29. Interlock system Beam 2 Isolde PSB layout

30. Interlock system Measurement devices PSB layout

31. Interlock system PSB layout

32. Interlock system BTY.TRA325 PPS device PPS interlock: Average1’(AQN(device))≤MAX PPS

33. Interlock system BTY.QDE321 BTY.QFO322 FOCUS devices Focus interlock: Setting(device)-2≤ AQN(device)≤Setting(device)+2

34. Interlock system BTY.DHZ323 BTY.DVT324 Pos. devices Position interlock: Setting(device)-1 ≤ AQN(device) ≤ Setting(device)+1 34

35. Interlock system BTY.TRA325 Watchdog devices

36. Interlock system PSB layout

37. Interlock system BTY.TRA325 BT.TRA Watchdog devices Watchdog interlock: BT.TRA-BTY.TRA325<300E10 Need HARDWARE interlock RESET!

38. Interlock system Booster ring TRANSFO PPP device 38

39. Injection Ejection Interlock system Int.[ppp] I(300) 0 275 300 805 1200 t [ms] PPP interlock: I(300)≤ MAX PPS 39

40. Interlock system BEAM BACK SW RESET RF Condition OK 40

41. Interlock system HW Interlock HW RESET BEAM BACK 41

42. Configuration GUI 42

43. Configuration GUI 43

44. Configuration GUI 44

45. Supervisor name DB fixed_display Supervisor phone number Experimental contact Target name Genaral comment Configuration GUI 45

46. Supervisor name Supervisor phone number Experimental contact Target name Genaral comment Configuration GUI DB fixed_display 46

47. Configuration GUI 47

48. DEVICE Focus DB fixed_display Max Intensity Max proton per pulse Pos. DHZ Pos. DVT Configuration GUI Beam Label Beam type Focus Max Intensity Max proton per pulse Pos. DHZ Pos. DVT 48

49. Configuration GUI Special FOCUS disable Position and focus interlock 49

50. Conclusions ...Isolde VISTAR is CO standard and fully CO supported ...Isolde VISTAR contains many informations extremelly useful for the users and PSB team. ...Isolde Interlock system is very fast...reaction time smaller than 10ms. 50