Digital Phase Follower -- Deserializer in Low-Cost FPGA

1. Digital Phase Follower --Deserializer in Low-Cost FPGA Jinyuan Wu, Z. Shi

2. Motivation • In HEP systems, sometime many channels of serial data must be concentrated. • It will be nice if the data clock is not transmitted separately. (Just transmit a single data channel). • It will be nice if it can be received in low-cost FPGA in which dedicated serial data receivers are not available. • It will be nice if user protocol can be supported. (Can be 8B/10B, or can be anything users want). • Examples: • TSO modules to PP modules. (500 Mbps, user protocol). • FPIX2 to PDCB. (140 Mbps, user protocol).

3. Receiving Serial Data • Data channels are de-serialized using shift registers. • The clock for the receiving shift registers comes from: • Separate channel. (Channel-channel skew  ). • Same data channel. • Clock recovery using PLL. (Phase detection+VCO). • Dynamic phase aligner. (In Altera devices, choosing a correct clock phase from 8 phase samples). • Digital phase follower. (For low-cost FPGA).

4. Multiple Sampling b0 b1 b2 Quad Sampling Fs = 4/UI b0 b1 b2 b3 Triple Sampling Fs = 3/UI Double Sampling Fs < or > 2/UI b0 b1 b2 b3 b4 b5 • Multiple sampling is used to determine the phase of the data. • A correct sampling point is automatically chosen after first 0 to 1 transaction. • The sampling point shifts following the shift of the data phase. • Everything is in standard digital circuit.

5. More Notes on Multiple Sampling b0 b1 b2 Quad Sampling Fs = 4/UI b0 b1 b2 b3 Triple Sampling Fs = 3/UI Double Sampling Fs < or > 2/UI b0 b1 b2 b3 b4 b5 • In digital phase follower, since no clock recovery is needed, 4, 3 or 2 samples per bit (unit interval) are sufficient. (Not 8). • In double sampling case, sampling rate must be known either less or larger than 2/UI.

6. Digital Phase Follower, Block Diagram QF Q3 Data Out Data In c0 c0 b1 QE Q2 b0 c90 QD Q1 Shift2 c180 Shift0 Q0 Frame Detection c270 SEL Multiple Sampling Clock Domain Changing Tri-speed Shift Register was3 is0 was0 Trans. Detection is3

7. Digital Phase Follower: Operation Older Samples Selected Sample Q3 Selected Sample Q2 b0 Selected Sample Q1 Selected Sample Q0 SEL QF QE QD Newer Samples SEL=0 SEL=1 SEL=2 SEL=3

8. Was 0, Is 3, Data Is Slower. Shift 0. This bit has been sent to the shift register. No duplicate recording. Older Samples New Selection Q3 Q3 Q2 b1 Q2 Q1 b0 Q1 Shift2 Old Selection Q0 Shift0 Q0 QF SEL QE Tri-speed Shift Register was3 QD is0 was0 is3 Newer Samples SEL was 0 SEL is 3

9. Was 3, Is 0, Data Is Faster. Shift 2. This bit has not been sent to the shift register. Sent it through b1, along with new selection b0=Q0. Older Samples Old Selection Q3 Q3 Q2 b1 Q2 Q1 b0 Q1 Shift2 New Selection Q0 Shift0 Q0 QF SEL QE Tri-speed Shift Register was3 QD is0 was0 is3 Newer Samples SEL was 3 SEL is 0

10. Simulation (1) • This is a 4B/5B receiver working at 400Mbps, compiled in an Altera Cyclone device. • The receiving clock is 0.4% slower – no errors is seen.

11. Simulation (2) • The same receiver running with receiving clock 0.4% faster – no errors is seen.

12. Deserializer Based on Digital Phase Follower • Data is self-timed, no separate clock transmission is needed. • The transmitter and receiver clocks can be independent – frequency difference is compensated. • User protocols are supported. • It can be implemented in low-cost FPGA.

13. Digital Phase Follower Start-up • Preamble: 1 idle word with 0 to 1 transitions. • In other scheme, long preambles or training patterns are needed. • Frame detection: defined by user. It can be 10000000000000xxxxxxxxxx (in FPIX2). • Data: