J. Brau LCWS 2006 March, 20061 J. Brau LCWS 2006 - Bangalore March, 2006 C. Baltay, W. Emmet, H. Neal, D. Rabinowitz Yale University Jim Brau, O. Igonkina,

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Presentation transcript:

J. Brau LCWS 2006 March, J. Brau LCWS Bangalore March, 2006 C. Baltay, W. Emmet, H. Neal, D. Rabinowitz Yale University Jim Brau, O. Igonkina, N. Sinev, D. Strom University of Oregon

J. Brau LCWS 2006 March, ILC Vertex Detectors S i DS i D GLD LDC

J. Brau LCWS 2006 March, Z= 6.25cm SiD Vertex Layout 5 barrel layers 4 end disks SiD 00 Design drivers: Smallest radius possible Clear pair background Seed tracks & vertexing Improve forward region Role: Z [cm] R [cm] 5 Tesla

J. Brau LCWS 2006 March, SiD Vertex Detector BARREL –100 sensors –1750 cm 2 FORWARD –288 sensors –2100 cm 2

J. Brau LCWS 2006 March, ORIGINAL IDEA –Hierarchical array (Macro/Micro) w/SARNOFF

J. Brau LCWS 2006 March, Summary Investigation of Hierarchical Approach –Macro/Micro Hybrid (50 um  ~5 um)  Macro only, reduced to um pixel Completed Macropixel design –645 transistors –Spice simulation verified design –TSMC 0.18 um -> um pixel Next phase under consideration –Complete design of Macro pixel –Deliverable –tape out for foundry (this year) Future –Fab 50 um Macro pixel design –Then, um pixel (Macro pixel)

J. Brau LCWS 2006 March, 20067

8

9 Background Hits Dominate Vertex Detector Events of interest are relatively rare – –less than 1 Hertz. –hit rate in Vertex Detector dominated by background. Detailed calculations yield an expected background estimate of 0.03 hits/mm 2 /Bunch Crossing However, with considerable uncertainty on this level of background. –Difficult calculation. –Background will depend on final choice of collider design details.

J. Brau LCWS 2006 March, The Macropixel Array is Critical Big Pixel size (initially 50 um x 50 um) limits the tolerance to higher backgrounds. Therefore important to strive to reduce Big Pixel size. –Reducing the Big Pixel size to 10 um x 10 um (or even 15 um x 15 um) makes detector much more tolerant to backgrounds. –Macropixel Array (Big Pixel size) of um might not need complement of micropixels simplified design of single layer of "Macropixels" with time information Might not need analog information.

J. Brau LCWS 2006 March, What Limits the Macropixel Size –Compress Big Pixel size, retaining storage of hit time information for 4 hits/pixel/bunch-xing –Area needed with present technology (0.25 um?) Comparator/counter/latch, etc., circuit Storage of up to 4 hits, i.e., 14 bits x 4 deep –Process Technology - how does pixel size scale as process technology goes 0.25 um, 0.13 um, etc? What do you need to go to 10 um x 10 um pixels? Can you estimate the progress of this technology? What's available today? –Much more interesting - what will be available - 5 years from now when we need to fabricate the actual devices?; –How much does it help to reduce max number of time stamps stored to 2 or 3?

J. Brau LCWS 2006 March, Readout Procedure and Speed First, some numbers: –Consider chips 22 mm x 125 mm = 2750 mm 2 – –Total no. of 10 um x 10 um pixels = 27.5 x 1O 6 pixels/chip – –Total hits.03 x 2820 x 2750 = 2 x l0 5 hits/chip/bunch train How long does it take to interrogate a pixel to see if it has a hit (presumably look of a single bit flag?) How long does it take to read out one hit pixel –X info (up to 2200) - 12 bits + parity = 14 bits –Y info (up to 12500) - 14 bits + parity = 16 bits –Time (up to 3000) - 12 bits + parity = 14 bits 44 bits total 2 x 10 5 hits/chip x 44 bits/hit / 50 MHertz = 176 msec Might divide each chip into parallel readout streams (10-20) to accommodate higher background rates?

J. Brau LCWS 2006 March,

J. Brau LCWS 2006 March, Charge Spreading Important to minimize charge spreading –pixel size sets scale that would reduce need for analog information. How small can we keep the charge spreading? –Thickness of expitaxial layer - 10 to 15 um –Possible approach - full depletion of epitaxial layer requires high resistivity? - few kohm-cm? or less? –Depletion voltage, field in epilayer?

J. Brau LCWS 2006 March,

J. Brau LCWS 2006 March, Read Noise Minimum ionizing particle leaves  88e - /micron in expitaxial layer –10 um thick epi x 88e-/um = 880 electrons GOAL - signal to noise of 10 to 20 –Can we keep read noise below 50 e- or so? –This consideration determines thickness of the exitaxial layer.

J. Brau LCWS 2006 March, Power Consumption Keep power to ~100 millwatts/chip (goal) ~4 mW/cm 2 Trade-off noise with power Make design choices which optimize noise/power tradeoffs

J. Brau LCWS 2006 March,

J. Brau LCWS 2006 March, Power Dissipation Analysis Additional 67- to 100-fold reduction expected by power cycling analog components (0.37 – 0.55 uW)

J. Brau LCWS 2006 March, Other Considerations Dark Current –Keep it small –Sarnoff – will reset array on each bunch Should not be a problem Operating Temperature –Sarnoff expects modest cooling (<0  C adequate) Device Thickness –Thinning below 50 um looks feasible B Field – Lorentz angle 

J. Brau LCWS 2006 March, Spice Model Verification of Design

J. Brau LCWS 2006 March, SARNOFF Response to Question on Future Technology Roadmap: Macropixel size estimation vs. Mixed-signal Process Technologies

J. Brau LCWS 2006 March, CONCLUSION Completed macropixel design –645 transistors –Spice simulation verifies design –TSMC 0.18 um -> um pixel Next phase under consideration –Complete design of macro pixel –Deliverable –tape out for foundry Future –Fab 50 um pixel chip –Then, um pixel

J. Brau LCWS 2006 March, EXTRAS

J. Brau LCWS 2006 March,

J. Brau LCWS 2006 March,

J. Brau LCWS 2006 March, Power Reduction Ratio = 1/67 to 1/100 (0.552  W to 0.37  W) Activate the Detector and the Comparator during the Bunch Train and deactivate rest of the time Power Reduction Method

J. Brau LCWS 2006 March,