(A) design of 20Gbps/Lane serial link for memory interface

Abstract

Various types of serial link for current and future memory interface are presented in this thesis. At first, PHY design for commercial GDDR3 memory is proposed. GDDR3 PHY is consists of read path, write path, command path. Write path and command path calibrate skew by using VDL (Variable delay line), while read path calibrates skew by using DLL (Delay locked loop) and VDL. There are four data channels and one command/address channel. Each data channel consists of one clock signal (DQS) and eight data signals (DQ). Data channel operates in 1.2Gbps (1.08Gbps~1.2Gbps), and command/address channel operates 600Mbps (540Mbps~600Mbps). In particular, DLL design for high speed and for SSN (simultaneous switching noise) is concentrated in this thesis. Secondly, serial link design for silicon photonics is proposed. Silicon photonics is the strongest candidate for next generation memory interface. Modulator driver for modulator, TIA (trans-impedance amplifier) and LA (limiting amplifier) for photo diode design are discussed. It operates above 12.5Gbps but it consumes much power 7.2mW/Gbps (transmitter core), 2mW/Gbps (receiver core) because it is connected with optical device which has large parasitic capacitance. Overall receiver which includes CDR (clock and data recovery) is also implemented. Many chips are fabricated in 65nm, 0.13um CMOS process. Finally, electrical serial link for 20Gbps memory link is proposed. Overall architecture is forwarded clocking architecture, and is very simple and intuitive. It does not need additional synchronizer. This open loop delay matched stream line receiver finds optimum sampling point with DCDL (Digitally controlled delay line) controller and expects to consume low power structurally. Only two phase half rate clock is transmitted through clock channel, but half rate time interleaved way sampling is performed by aid of initial value settable PRBS chaser. A CMOS Chip is fabricated by 65nm process and it occupies 2500um x 2500um (transceiver). It is expected that about 2.6mW(2.4mW)/Gbps (transmitter), 4.1mW(2.7mW)/Gbps (receiver). Power consumption improvement is expected in advanced process.