1. Elastic Buffer: data transfer in 2 clock domains Albert Chun (M.A.Sc. Candidate) Ottawa-Carleton Institute for Electrical & Computer Engineering (OCIECE) Ottawa, Ontario, Canada Wednesday April 17th, 2002

2. Table of Contents 1.0Background 2.0Mechanism 3.0Block Diagram (2:1 Mux with elastic buffers) 4.0Required Components 5.0Clock Divider 6.0Design Approach 7.0References

3. 1.0 Background Data transfer across 2 clock sources is a common practice in today’s high speed data transmission circuits On-chip clock speed is maintained by phase lock loop circuit Once “phase locked”, on-chip clock speed equals to incoming reference clock speed; but with constant phase difference For high speed applications, data can be buffered with double-edged flip- flops Problem occurs when the phase difference is larger than the width of a data bit; we may sample the incoming data signal at an incorrect moment, and lose information! One of the methods to eliminate this problem is to utilize an elastic FIFO buffer at the beginning of the data path, hence every data bit will be sampled without loss

4. 2.0 Mechanism The goal is to ensure the on-chip clock edge samples the data bit right at the centre of the “bit” (i.e. data eye), without missing any data bit Since we cannot control the phase difference, we “stretch” the data bit until it has adequate room around the on-chip clock edge We can accomplish this “stretching” by reducing the incoming data stream to lower bit rates In order to keep the same throughput, we have to demultiplex the incoming data from a high speed serial format to a lower speed parallel format But this is only half the story… We need to multiplex these parallel data streams back to a higher speed serial format, for subsequent stages of circuits

5. 3.0 Block Diagram (2:1 MUX with elastic buffers) div1, div2, div4 div1, div2, div4 Output data at x Mbps Input data at x/2 Mbps Input clock from PLL

6. 4.0 Required Components Elastic Buffer latches flip-flops 2:1 muxes Clock Divider flip-flops inverters (for single-ended signal implementation only)

7. 5.0 Clock Divider DQ Qb Asynchronous clock divider provides div2 & div4 output can get I & Q versions tap from latch output (of either flip-flop stage) Synchronous clock divider only div4 output available can get I & Q versions tap from latch output (of final flip-flop) DQ Qb DQ DQ clk clk/2 clk/4 clk

8. 6.0 Design Approach Estimate highest data output rate with 0.35um CMOS technology Assign highest data output rate for final 2:1 mux stage Utilize 1:4 demux and 4:1 mux stages for elastic buffer Investigate advantage/disadvantage of synchronous/asynchronous clock divider for this project Implement circuit with CMOS CML circuit Implement circuit with standard CMOS circuit (if time permits) Schematic-level design, layout, post-layout simulation

9. 7.0 References “2.5Gbit/s 16:1 Multiplexer GD16523” data sheet, GiGa (an Intel company), August 2001 “LXT6282 Octal E1 Digital Interface with CRC-4 Monitoring and Jitter/Wander Suppression” data sheet, Intel, January 2001 Shing-Chi Wang (NORTEL Networks), “Multiplexers and Demultiplexers”, 2001 GaAs IC Symposium Short Course, 2001