SCT Links Long Term Monitoring

1. SCT Links Long Term Monitoring • Summary quality installed links • Techniques for monitoring long term performance • Data links • TTC links • Improvements for SLHC Opto WG April '08

2. Data Links Quality • Data links status before installation in pit. • Dead : 0.6% • Problematic: 0.3% • Deaths: ESD VCSELs, broken single fibres on detector, damaged tracks on Al/kapton tapes. • Problematic: “slow turn”-on VCSELs (see next slide). Opto WG April '08

3. SCT Slow-turn on VCSELs • Send fixed data pattern • Scan DAC RX threshold • Check to see if correct bit pattern returned. Opto WG April '08

4. Data Links Monitoring - 1 • RX Max and RX Min distributions from the RX threshold scans. • Insufficient dynamic range  RXmax usually >255 so can’t be determined. • Best way to monitor optical output of on-detector VCSELs is using RXmin • Long term monitoring of number of links with low values RXmax will indicate if some VCSELs are going to die . RX Max RX Min Opto WG April '08

5. Data Links Monitoring - 2 Scan RX thresholds for data links, RXmin  optical power received. Plot ratio RXmin ratio (Pit/RAL reception) See decrease of 1 dB as expected from attenuation in long cable Histogram RXmin ratio Pit/RAL Opto WG April '08

6. Data Links Monitoring - 3 • No dramatic changes but need to start long term monitoring. • Ideally we should have several data sets before beam to understand stability and performance before radiation. <RX Min> 2008 data 2007 data <RX Max> Opto WG April '08

7. TTC Links Quality • TTC links before installation in pit. • Dead : 0.2% • Problematic: 0.7% • Deaths: broken single fibres on detector, damaged tracks on Al/kapton tapes. • Problematic: low p-i-n current channels • We initially thought this was a very widespread problem but it turned out to be mainly an artifact of oscillations in the current monitoring circuitry in the power supply.  replace up to 10% VCSEL arrays in ROD. Opto WG April '08

8. TTC Links Monitoring • Measure the currents for the on-detector pin diodes (Ipin) using the LV0 power supplies in the counting room. • Recent measurements of Ipin for SCT barrel in the pit. • Mean <Ipin>=0.24 mA ok • 7.7% links with Ipin<0.1 mA (we require Ipin>0.1 mA to minimise SEU). • Measure Ipin for all suspect low channels with simple card with battery + 1 kW series resistor + DVM. 0.1 mA Ipin Opto WG April '08

9. Correlation (DVM + 1kW) vs LV0 Correlation ok at high Ipin but poor at low values of Ipin

10. Status Low Ipin Channels • Measured 1941 channels • From measurements of 150 suspect channels only 14 confirmed low (of which 7 read 0) • To be checked with optical power meter. • 0.8% low channel replace ~ 9% of TXs (12 way arrays). Opto WG April '08

11. Monitoring BER • Can monitor BER for data links using • Preamble (fixed pattern) • Header (some bits fixed) • Trailer (fixed pattern) • TTC links • BCID and L1ID counters in the ROD. • ROD receives full BCID and L1ID from L1 Trigger. • FE chips (ABCD) on module count BCs and L1s and the 4/8 LS Bits of these numbers are transmitted to the RODs. • Compare LS bits of returned BCID & L1ID with ROD data. • Any discrepancy  bit error(s). Note that we expect finite BER from SEU at high luminosity. • 95% modules show no errors, 5% have errors, mainly BCID and L1Id; under investigation … Opto WG April '08

12. Conclusions • We have tools available and we will be able to track any long term degradation in performance of data or TTC links. • Data links: perform RX threshold scans. • TTC links: measure pin currents. • BER for data/TTC links from BC and cross checks. • Monitoring could be better if more thought at the design stage: • More accurate measurements of pin currents for low values essential for determining whether TTC link performance is acceptable. • better dynamic range for RX DAC (data links) so that digital scans would always determine meaningful values of RX_Max. • by measuring individual p-i-n currents in RX. Opto WG April '08