1. sakari tiuraniemi - CERN Status of the submission – End of Column

2. sakari tiuraniemi - CERN Top level layout Folded column including all 45 pixels in 5 groups of 9 pixels –Constant pitch of 300 um An additional mini-column (9 pixels) to verify effect of the corners / (in case problems with corners) –No model for the corners in transmission line End of Column circuitry –One for folded column and one for mini-column –Plus receiver bank (data and address receivers) for each EOC Power supply access from both sides due to the blocking by transmission line corners

3. sakari tiuraniemi - CERN Top level layout

4. sakari tiuraniemi - CERN End of Column Layout TDC-bank of 9 TDC’s (18 hit registers) with differential to single-ended input buffer, DLL with differential buffer Missing in layout: –Start and stop trigger generation Designed on schematic level –Shift register for serial data transmission Designed on schematic level –Coarse Counter Designed on schematic level –Address receivers and registers

5. sakari tiuraniemi - CERN

6. Start and stop trigger Receiver output A and a delayed copy B Start: A and not (B) Stop: B and not (A) Trigger pulse width fixed by delay τ –2 ns should be enough –< minimum pulse width A B Start Stop τ

7. sakari tiuraniemi - CERN

8. Coarse Counter 2 x 6-bit synchronous counter –180 degree phase difference to provide a steady output at all times –Selection of coarse counter output to be organized to avoid reading output when changing state CLK ?

9. sakari tiuraniemi - CERN Coarse Counter Example 4-bit synchronous counter: - Instead of load, reset is applied to set the state of the counter to ‘000000’ through D 0, D 1, …, D 5 - Reset is latched with CLK

10. sakari tiuraniemi - CERN Serial readout The data of each hit is stored in a shift register (parallel in, serial out - PISO) –Including rise and fall fine time (2 x 32 bits), rise and fall coarse time (2 x 6 bits) and address (5 bits) all together 81 bits Serial data transmitted off chip by LVDS driver Ferrara readout as an alternative

11. sakari tiuraniemi - CERN Impact of DM option LM option: –Thin metals: M1 – M6 (0.2 um) 64 mΩ (M1: 70 mΩ) –Thick metals: MQ and LM (0.4 um, 38 mΩ) DM option –Thin metals: M1 - M3 (0.2 um) –Thick metals MQ and MG (0.4 um) –Low resistive metals: LY (0.6 um, 89 mΩ) E1 (1.5 um, 6 mΩ) MA (4.0 um, 7 mΩ)

12. sakari tiuraniemi - CERN Impact of DM option Attach to new technology file –Affects metal levels above M3, including: Transmission lines –MQ or MG instead of M5 Interconnections and routing between blocks –Especially tricky in TDC bank where layout is quite tense »New metal layers (MQ and MG) to be used => min width 0.4 um (instead of 0.2) »The readout of 18 times 32 bits is not possible in 300 um (in the demonstrator we are not limited to 300 um) –Change metals and vias, when needed design new routing to adapt to new layout rules –New layout for TDC bank, all other blocks affected only on M4 (->MQ)

13. sakari tiuraniemi - CERN The End