Beam Line Controls, Monitoring & DAQ

1. Beam Line Controls,Monitoring & DAQ paul drumm february 2005

2. Monitoring System

3. Monitoring System

4. Monitoring System

5. Monitoring System

6. Data Stream? clock DB Pointer Controls Header MHz Data (DAQ) MHz Data (DAQ) DB Pointer Controls Footer

7. Strategy & Tasks • Strategy should take account of the need to • Have stand alone systems • Avoid duplication • Avoid dependence on DAQ for last minute commissioning • Immediate Tasks: • Beam Line Controls: • SC Solenoid • Cryogenic System • Interlocks • Conventional magnet power supplies • Diagnostics

8. The Survey Controls, Instrumentation and Data Acquisition Survey • A focus of the Berkeley Collaboration meeting will be the control and physics parameters needed by MICE to fully qualify and understand the measurements to the advertised precision. These parameters can cover any aspect of MICE from the ISIS beam, through the detectors, cooling channel down to the final calorimeter, interlocks, and any ambient or dynamic parameter (fast or slow). To facilitate this discussion you are kindly requested to complete this survey. The survey asks four questions: 1. PHYSICS PARAMETERS: Which parameters might it be important to include in the data analysis of the experiment? • The absolute answer to this question is probably not yet known, and will require simulation of the experiment to determine the sensitivity of the measurement to a particular parameter. However, it is possible to make good guesses as to what these might be. These are the parameters which will be incorporated into the data stream of the DAQ. A typical parameter could be the value of the magnetic field as measured by the hall probes. It is the intention to gather a set of parameters whose importance can eventually be investigated by simulation. 2. CONTROL/MONITORING: Which additional parameters are needed for control or monitoring? • Additional parameters needed for control or monitoring which may not be part of the data stream but are necessary to ensure proper operation of the equipment. This might include for example monitoring the status of interlocks or faults which are not relevant during MICE running. 3. How do you see these parameters being recorded and controlled? • It might be that the instrumentation, its control and monitoring has already been defined or there are already standard methods/equipment used for this. This should be indicated here to so we can try to avoid duplication. If possible the nature of the hardware interface should be described. 4. What need do you have for stand-alone operation as opposed to integrated operation in MICE at RAL? • Will the equipment be operated outside of RAL during the commissioning or testing phase? If so what will be available at the time of installation at RAL? If not what will be needed when the equipment is installed, commissioned and operated at RAL?

9. v v v v v v V V Environmental parameters (marshalled elsewhere?) cooling water temperature fault conditions (power supplies) fault conditions (solenoid cryogenics) Power supplies - control & diagnostic Assume control feedback is done in the power supply “Control” – consists of setting I in each element “Diagnostic” – output = alarms/mimics etc – input parameters: Quads I,V – x4 each x9 Dipole I,V – x1 each x2 Solenoid I,V Target • Vacuum – per pump set • Gauges – three: rough – turbo – system • Integrated system control through PLC oroff-shelf controller: • pump on/off; valve open/closed • auto start-up & shutdown quads solenoid dipole Solenoid Cryogenics & control system • ISIS: • BLM • Cycle information MICE dipole Diffuser bar-code reader? quads quads Diagnostics DAQ  Control System Hybrid

10. 1 • 1. PHYSICS PARAMETERS: • Dipole Magnet Fields • Pion and Muon Momentum • Target state • target amplitude (actual) and beam loss signals = production rate • Solenoid settings & quad settings = input emittance • Diffuser setting = output emittance (of beam line)

11. 2 • 2. CONTROL/MONITORING: • Beam Line: • All magnets Qs (9), Ds(2), decay solenoid • Currents: • Set & Monitored – feedback in power supply • Volts (read back); • Alarms on temperature, cryogenics, vacuum etc  drive a “status ok” signal

12. 2 • 2. CONTROL/MONITORING: • Target: • Synchronisation inputs: • ISIS Machine Start (once per injection) • ISIS clock (200 kHz) • Control Settings: • insertion depth • insertion time • Operational monitors: • Up to 8 temperature measurements per cycle (inner coil, outer coil, cooling water inlet, water outlet, ...) • alarm status = temperatures > pre-defined limits  inhibit • The target position will be read every 0.1 ms and this information used internally to adapt drive currents and timing. • Selected history stored for long term monitoring. from CB

13. 3 Generic Control & Monitoring Model Monitoring & “Control” System Control System Equipment DAQ Human Interface Human Interface Human Interface may not need to be present (all the time) could be buttons/lamps/local mimic /plug-in terminal expert/local user/global

14. 3 • 3. How do you see these parameters being recorded and controlled? • Local Integrated system for beam line and target • power supplies, vacuum etc • Ethernet connection to outside world: • Remote monitoring within restricted i/p range • Remote control within very restricted i/p range • PC/VME/PLC EPICS/LabView • open question still – not yet designed

15. 4 • 4. What need do you have for stand-alone operation as opposed to integrated operation in MICE at RAL? • Target testing away from RAL = standalone • Beam line needs to be independent of MICE = Standalone at RAL

16. People involved: • Controls coordination (BM@DL) • Target – Controls (CB@SH) • Beam Line electrical (power supplies) (ISIS/?) • Beam Line mechanical (water) (ISIS/?) • Beam Line Diagnostics (PS@Ggo) • Cryogenics group (TB/YI) • Interlocks designer (TB/MC) • Vac group (ISIS/) • ISIS controls representative (ISIS/) • beam loss monitors • cycle information • ISIS Interlocks (ISIS/?) • - Specification • - Implementation

17. Outlook • Beam Line needs: • Operational Control System • Beam line & target • Interlocks • synergy with ISIS upgrade (“kit of parts”) • Access control • radiation + personal safety • cryogenic controls