1. EDET DH80k TEM camera: System overview Johannes Treis MPI Halbleiterlabor 20 th international workshop on DEPFET Detectors Seeon monastery 11.5.2015 Non-BELLE applications

2. Contents Johannes Treis / Halbleiterlabor der MPG System design philosophy Challenges System structure System components ASM Brick support Patch Panel Summary & Outlook

3. System design philosophy Johannes Treis / Halbleiterlabor der MPG Concept: Detector FPA consisting of 4 individual, independent modules ("tiles"). Each tile has its own set of peripheral components: Quadrant electronics Cable harness Vacuum feedthrough Maximum modular approach: Modules are identical, no specialized components Modules are exchangeable and interchangeable Easy replacement and refurbishment Minimal number of peripheral components "Stand alone" operation for every module Adopt same architecture for (later) DH1K camera Benefits: Easy to duplicate Easy refurbishment of broken parts, only reversible connections Reduced instrument downtime Easy subsystem operation with reduced FPA size

4. Challenges I Johannes Treis / Halbleiterlabor der MPG Thermomechanical: Thin detector substrate of all-silicon module (30  m and 50  m) Thermal challenge: Prevent formation of too-large temperature gradients over detector area Mechanical challenge: Protect detector in sensitive parts (e.g. corners) from mechanical stress due e.g. CTE mismatch Provide heatsink for thermal stabilizatio0n of both detector modules and module individual electronics inside vacuum vessel Design must be robust against temperatures and mechanical stresses introduced during foreseen annealing procedure Gradient 46°C Gradient 41°C

5. Challenges II Johannes Treis / Halbleiterlabor der MPG Data rate: DH80K takes bursts of 100 frames at 80 kHz 13  s / frame 1.3 ms per burst Burst frequency ~ 10 ms Duty cycle ~ 10:1 EDET DCD digitizes data from 512 x 512 pixels per quadrant with 8 bit resolution 262 kByte / Frame 26.2 MByte / burst 2.6 GByte / s Full scale system consists of 4 tile modules Total data rate ~ 10.5 GByte /s Data reduction / zero suppression difficult Electromechanical: Width of electrical vacuum feedthrough limited Detachable connection between various components (rules out direct soldering of flex) Compact and reliable high pincount connectors for most inter-component joints Wire bonds can not be completely avoided Electrical: Reduce pincount as much as possible Large supply currents at low voltages High number of supply and sense lines Large number of data transmission lines

6. System structure Johannes Treis / Halbleiterlabor der MPG System components: ASM: All-Silicon module Brick support: Mechanical and thermal support for ASM and interface to main heatsink Patch panel: Wire bond adapter and local power conditioning and housekeeping circuitry Vacuum interconnect: Flexlead for vacuum feedthrough of all digital and analog signals & supplies Module interface circuitry: Interface to readout system controllers, power conditioning

7. System structure Johannes Treis / Halbleiterlabor der MPG FPA stack: 4 tiles per detector FPA Mounted (clamped) on common heatsink attached to cold head of cooler Cooler cools away dissipated power and stabilized assembly to required operating temperature Modular approach: Individual support circuitry on Patch panel Individual cable harness Individual vacuum feedthrough Modules can independently be attached and detached from common heatsink Reversible mount in case of module damage or refurbishment of worn out modules Requires each module to have an individual thermomechanical support (BRICK support)

8. Johannes Treis / Halbleiterlabor der MPG System structure Top view: Feedthrough flanges integrated on baseplate flange Displacement wrt. ASM accommodated by "Double L" shaped patchpanel Insertion: Insertion fo comlete FPA stack from below No cable mounting from top required after insertion

9. System structure Johannes Treis / Halbleiterlabor der MPG "Double-L" shaped patch panel: Support multi-pin connector Support buffer capacitors in bonding section close to conection to ASM Support circuitry for Driving the LVDS signals from the DMC over the VIC to the outside Local regulation of DCD and DMC supply voltages Level out displacement between ASM edge and VIC position on baseplate flange

10. System structure Johannes Treis / Halbleiterlabor der MPG Vacuum interface connect (VIC): Potted PCB with connector on both sides with UVH compatible adhesive Tested & qualified for FSP Homogeneous impedance For optimum digital signal quality Modular and exchangeable No active components

11. System structure Johannes Treis / Halbleiterlabor der MPG CAD views

12. System structure Johannes Treis / Halbleiterlabor der MPG Module structure: Each module operates as an independent subdetector Synchronized by central sequencer Power generation & conditioning in-module: On MIC: DEPFET power and switcher voltages On Patchpanel: Drop-Critical DMC and DCD voltages "Local" sensing on patchpanel to compensate for on-module voltage drops Saves numerous feedthrough and sense lines Configuration, control and housekeeping for module via the same interface Simple, standardized external power supplies Simple vacuum feedthrough optimized for digital data transmission

13. System structure Johannes Treis / Halbleiterlabor der MPG Module Interface circuitry (MIC) : Peripheral interconnect based on simple FPGA I/O module EDET specific daughter card (EDC) Communication & setup using TCP/IP stack JTAG interface for DCD / DMC / Switcher configuration is provided by an (optional) FPGA on Microcontroller the EDC Filters for primary (raw) power, conditioning for Switcher & DEPFET voltages Buffer for LVDS data from DMCs (32 diff. pairs) Receiver for synchronization signal from main sequencer (clock)

14. System structure Johannes Treis / Halbleiterlabor der MPG DAQ Concept: Data from 32 LVDS links per Module is delivered to distribution panel on DAQ rack Redistributed to Data Capture Cards (DCCs) for assembly of frames and sending to Switch/Storage system Single power supply or modul-individual "raw" power supplies per detector module One sequencer module per detector system provides for synchronized operation of subdetectors Configuration & control of components via Control PC using TCP/IP connection(s)

15. System structure Johannes Treis / Halbleiterlabor der MPG Alternative MIC Concept: Peripheral interconnect based on Data wrapper FPGA module Project-specific daughter card (EDC, to be developed) Communication & setup using TCP/IP stack Data transfer via (multiple) GBit Ethernet interface directly to Switch

16. Johannes Treis / Halbleiterlabor der MPG System structure Alternative Concept: Foresee module-individual data wrapper FPGA module Transfer module data directly over GBit Ethernet link(s) and Switch to storage device Data rate here is 2.6 GByte /s (21 GBit /s) More complex assembly of frame data Less components in total, higher degree of modularity

17. ASM Johannes Treis / Halbleiterlabor der MPG DCD array (EDET specific DCD) DMC array Switcher Bank Test pads (removed after met. 1 testing) Bias contacts Bondpads for DCD / DMC data & supplies JTAG Pixel array 30.7 x 30. 7 mm 2 Chip size ~ 50 x 38 mm 2 Configuration and control structure similar to PXD-9 ASM Specific ASICS Application-specific DCD DMC as data Buffer Chip

18. BRICK support Johannes Treis / Halbleiterlabor der MPG Concept: Need support under entire frame Thick material to get rid of the heat, lower thermal gradients CTE match close to optimum to reduce stress Opening below (cavity) to provide beamdump Robust structure Materials under investigation: Polysilicon: Expensive, brittle, difficult to machine, Optimum CTE match and thermal performance Titanium: Reduced thermal performance, easier to machine, less expensive Higher stress and thermal gradients due to non-optimum CTE match and thermal conductivity Bevelled aproach for beam dump Thermal support over full backside area equal reference temperature of 0° ASM glued to Brick support Issues have been investigated using FEM Results for stress analysis and partially also thermal analysis depend strongly on fixture and clamping methods

19. BRICK support Johannes Treis / Halbleiterlabor der MPG Titanium Polysilicon Comparison: Equal color scale span Corrected for individual offset temperature Difference in temperature gradient ~ 2°C 25% higher leakage current gradient Higher offset (not significant) Significant temperature offset for R/O chips

20. BRICK support Johannes Treis / Halbleiterlabor der MPG Curing stress Titanium: max. von Mises Stress 434 MPa Highest stress values in support area High stress also in transition region from thin to thick silicon Max. stress here is 240 MPa

21. BRICK support Johannes Treis / Halbleiterlabor der MPG Curing stress Polysilicon: max. von Mises Stress in thin area is 17.8 MPa

22. Patch panel bonding section Johannes Treis / Halbleiterlabor der MPG Concept: Depth milling process for "stepped" access to inner layers Especially important for contacts in region of high density interconnects (LVDS fanout) Saves huge number of vias Embedding of trace pairs between fixed potential layers possible

23. Patch panel bonding section Johannes Treis / Halbleiterlabor der MPG Population of components on top layer

24. Patch panel circuit section Johannes Treis / Halbleiterlabor der MPG DCD power 2) : DV DD :2.2 V, 1.5 A AV DD :1.9 V, 5 A VRef in 5) :1 V, 800 mA VAmp Lo 5) :300 / 500 mV, 1.5 A, Current sink (!) 2) 8 Devices, 4 groups of 2 each 5) VRef in, VAmp Lo individually adjustable DMC power 3) : V Core :1.1 V, 4 A V I/O :1.8 V, 4 A 3) Estimated values Main problem: Large supply currents for DCD / DMC Substantial resistance of supply lines Strong variations of currents depending of operation state Sense lines required! Maximum granularity of system: Supplies in 4 groups of 2 DCD / DMC pairs each Actual granularity tbd. Space is not critical, so local regulation is suggested Using low noise / high current LDO regulators LDO power dissipation needs to be taken care of (thermal management) Housekeeping of current and voltage (and temperature) required Power supply prototype for use with DCD / DHP or DCD DMC modules has been designed

25. Patch panel circuit section Johannes Treis / Halbleiterlabor der MPG Positive supplies: Generate Power from single "raw" supply AVDD / DVDD / V Ref DMC voltages Adjustable Voltage for V ref Real hi and lo side (2 wire) sense Requires use of difference amplifier due to nonzero resistance of sense lines

26. Patch panel circuit section Johannes Treis / Halbleiterlabor der MPG Positive current sink: VAMP LO Generate Power from AVDD supply using bootstrapped negative LDO Adjustable Voltage Real hi and lo side (2 wire) sense Difference amplifier needs to be referenced to AVDD

27. Patch panel circuit section Johannes Treis / Halbleiterlabor der MPG Housekeeping: Monitoring of both current and voltage Optionally, voltage applied to the load can be monitored Controlled via I2C bus

28. Patch panel circuit section Johannes Treis / Halbleiterlabor der MPG Thermal management: Dropout voltage low, but raw supply needs to accomodate all voltages High currents -> relatively high power dissipation in regulators Thermal management is an issue Using solid copper inlays for thermal stabilization and optimization of thermal coupling to heatsink Use Semi-Flex PCB technology to improve connection between Circuit section and bonding section of Patch Panel Images: courtesy Häusermann

29. Summary Johannes Treis / Halbleiterlabor der MPG Status: Design of camera system consolidates Progress in conceptual, mechanical and electrical system design Prototyping of critical circuit components Thermal dummy tests to verify critical thermal and machanical aspects of design Open questions: Annealing? BRICK support material Form factor for MIC