1 / 7

ASIC at SMU

ASIC at SMU. A brief history, and lessons to be learned. Two recent designs, the technical aspect: A LC based Phase Locked Loop (PLL) A 16:1 serializer at 5 Gb/s. Phase I, with EE. 2004: decision on “ASIC for the LHC upgrade”.

wes
Download Presentation

ASIC at SMU

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. ASIC at SMU • A brief history, and lessons to be learned. • Two recent designs, the technical aspect: • A LC based Phase Locked Loop (PLL) • A 16:1 serializer at 5 Gb/s

  2. Phase I, with EE • 2004: decision on “ASIC for the LHC upgrade”. • 2004/2005: collaboration with SMU EE department, proposal to US-ATLAS about development of 10 Gb/p serializer using an SOS technology, funded at ~$160k/yr for 3 yrs. • 2005/2006: irradiation tests on a laser driver about the SOS technology and concluded that a dedicated test chip would be needed to understand at transistor level this issue. Test chip: 96 transistors w/ different size and layout. Shift registers, ring oscillators. VCO. Resistors.

  3. Phase I, with EE • The design environment was from the EE department which has one staff for Cadence and one student for the foundry design kit. • 2006/2007: design the first serializer chip (LOC1) with one EE prof. + two graduate students. • 2007: function tests of LOC1 (Datao) and found that it fails the requirement of a 2.5 Gb/p serializer. Reason: no deep understanding of the circuits, no thorough simulation of the design; no collaborative efforts.

  4. Phase I, with EE An LC based PLL was also implemented

  5. Phase II, on our own • 2007/2008: decision to terminate the collaboration with the EE department. • 2008/2009: set up the design environment in Physics. About 25% of the computer admin’s time on a server (8 CPUs, 64 GB memory) and 10% of Datao’s time on the design kit, with a lot of help from an engineer from the foundry. Foundry’s willingness to help is very important. • Datao took one semester course on IC design. Prior to this, Tiankuan took one semester course as well. • 2008 4Q: start the design of LOC2, a 5 Gb/p serializer. Will report in detail later. • Painfully slow progress due to new to the field, and no critical mass in the lab: Datao had no one to discuss on a day-to-day basis. I facilitated Datao with experts from U. of Chicago, TI, IPHC, CERN and Upenn.

  6. Phase II, on our own • 2009 1Q: Tiankuan jumped in on a 5 GHz LC based PLL. • 2009, until August: with tremendous help from Fukun, Christine (IPHC Strasbourg) and Paulo (CERN), and with a lot of creative work from a team of Datao, Tiankuan, a graduate student (Qinghua) and myself, we completed the designs for LOC2 and the LCPLL. Both will be reported later. • 2010/2011: test of LOC2 and the LCPLL, design of LOC3. Move to IBM 90 nm technology. LOC2, LCPLL and other testing structures: varactor, RAM, CML driver

  7. Lessons Learned • ASIC is do-able with efforts and moderate resource. • It is possible to take off within 18 months, if no mistakes in decision making process. • Help from experts is a big booster to take off. The fastest way is to learn from experts in a project. • It needs a dedicated team with a critical mass to achieve necessary efficiency. • Choose a technology and foundry service carefully. Foundry’s support becomes vital if special needs are to be met. This is the place help should be obtained above the university/institute level.

More Related