Todd M. Rasmus

A 16-Gb/s Backplane Transceiver With 12-Tap Current Integrating DFE and Dynamic Adaptation of Voltage Offset and Timing Drifts in 45-nm SOI CMOS Technology

This paper presents a 16-Gb/s 45-nm SOI CMOS transceiver for multi-standard backplane applications. The receiver uses a 12-tap DFE with circuit refinements for supporting higher data rates. Both the receiver and the transmitter use dynamic adaptation to combat parameter drift due to changing supply voltage and temperature. A 3-tap FFE is included in the source-series-terminated driver. The combination of DFE and FFE permits error-free NRZ signaling at 16 Gb/s over channels exceeding 30 dB loss. The 8-port core with two PLLs is fully characterized for 16 GFC and consumes 385 m W/link.

A 16-Gb/s backplane transceiver with 12-tap current integrating DFE and dynamic adaptation of voltage offset and timing drifts in 45-nm SOI CMOS technology

This paper presents a 16-Gb/s 45-nm SOI CMOS transceiver for multi-standard backplane applications. The receiver uses a 12-tap DFE with circuit refinements for supporting higher data rates. Both the receiver and the transmitter use dynamic adaptation to combat parameter drift due to changing supply and temperature. A 3-tap FFE is included in the source-series-terminated driver. The combination of DFE and FFE permits error-free NRZ signaling at 16-Gb/s over channels exceeding 30dB loss. The 8-port core with two PLLs is fully characterized for 16GFC and consumes 385mW/link.

A uniform bandwidth PLL using a continuously tunable single-input dual-path LC VCO for 5Gb/s PCI express Gen2 application

A 4.75 to 6.1 GHz PLL with uniform bandwidth control is implemented in 90 nm CMOS. Utilizing a continuously tunable single-input dual-path LC VCO and a constant-gain phase detector, the proposed architecture is well suited to implementing PLLs that must be compliant with standards that specify minimum and maximum allowable PLL bandwidths such as PCI Express Gcn2 or FB-DIMM applications. This work also addresses noise and coupling aspects in dual-path VCO design. The measurement results show that the PLL bandwidth and random jitter (R.I) variations are well regulated and that the use of a differentially controlled dual-path VCO is important for deterministic jitter (DJ) performance.

A Continuously Tunable LC-VCO PLL with Bandwidth Linearization Techniques for PCI Express Gen2 Applications

This paper describes bandwidth linearization techniques in phase-locked loop (PLL) design for common-clock serial link applications. Utilizing a continuously tunable single-input dual-path LC VCO and a constant-gain phase detector, a proposed architecture is well suited to implementing PLLs that must be compliant with standards that specify minimum and maximum allowable bandwidths such as PCI Express Gen2 or FB-DIMM applications. A prototype 4.75 to 6.1-㎓ PLL is implemented in 90-nm CMOS. Measurement results show that the PLL bandwidth and random jitter (RJ) variations are well regulated and that the use of a differentially controlled dualpath VCO is important for deterministic jitter (DJ) performance.