Preparation for 2021 Run
Revision as of 10:46, 15 October 2020 by Dalton
Below is a list of action items which we would like accomplish before the PrimEx Phase II run in Spring/Summer of 2021
- Aligning FCAL in the Hall -- Coordinated by Tim Whitlatch
- Moving FCAL platform by about 5 mm in X-direction to make sure that the beam goes through the middle of the FCAL hole (3x3 modules). The exact position of the platform should be confirmed by the alignment group
- Preventative maintenance of FCAL PMT bases -- Coordinated by Mark D, with support from Chris S., Nick S., Fernando B., Matt S., Ben R., Paul S.
- Change out bases which draw excessive current (> 13 mA) when they are on or which show other signs of problems. High current bases are associated with increased temperature, increased deviation from setpoint and future high voltage failure. There are about 200 high current bases. They are repaired using the standard procedure for cleaning and replacing resistors on the base.
- Diagnose bases which draw excessive current (> 13 mA) when they are on and off. This curious symptom is not understood. 
- 8 bases have been remove from the FCAL for special diagnosis. These plus 2 more have arrived with Paul at IU with details of the problem symptoms.
- Report from Paul. Base 23286 drew 14 mA when powered up. The COMM board by itself draws 14 mA, so the problem is there. It was not immediately obvious what is wrong with the COMM board. The other 7 had current draws > 20 mA when powered up. In all cases the COMM board by itself had most of the excess current draw. In all 7 chip U9 on the COMM board was warm or hot to the touch. This chip drives the test pulser on the SOCK board. If there is a spark at the PMT socket the test pulser transistor is destroyed and U9 is damaged.
- Improve robustness of firmware for handling communication failures. When the beam is on we regularly have about 2-3 bases that lose communication per day. The HV drops to zero and the only known way to recover is to power cycle all the bases at the end of the run. This means that we permanently have some holes in the FCAL from perfectly working bases. We will try to modify the firmware to fix this issues. Ben R., Mark D.
- compile the existing code and load onto a test unit to make sure we can reproduce what you currently have
- have it communicate over the CAN interface like normal
- try to crash the micro-controller with a radiation source
- make a small firmware change to enable the watchdog timer and try to crash the micro-controller again with source (we should plan to track/observe if a watchdog reset occurs which should match the rate of lockups from step 3 if conditions are the same, but in this case it should self recover)
- look into remote/boot loader firmware update code & power to try and optimize.
- Ordered a RLINK-STD STM8 series Debugger, Programmer (In-Circuit/In-System) to program the base firmware.
- The RLINK has arrived.
- Evaluation of bases in inner rings for Compton events
- 25 bases have already been replaced in this area. Status of FCAL bases in 3 inner rings Colin
- A possible 47 more could be replaced, we should evaluate which of these are showing any issues. Mark D.
- Refurbish CCAL active bases
- - manufacture 150 new active bases according to recent modifications by V. Popov and install them on the CCAL -- Chris S., Nick S., and Fernando B.
- - Chris has already prepared a new PCB design for the active base
- - ( replace bases: A.Somov, J.Crafts, V. Berdnikov )
- Increase LED light pulse on the CCAL LMS system
- - replace (use multiple LEDs) on the LMS system (A.Somov, J.Crafts, V. Berdnikov)
- - Driver(s) for multiple LEDs Chris S., Nick S., and Fernando B.