Digital Centric Multi-Gigabit SerDes Design and Verification

Advances in semiconductor manufacturing still lead to ever decreasing feature sizes and constantly allow higher degrees of integration in application specific integrated circuits (ASICs). Therefore the bandwidth requirements on the external interfaces of such systems on chips (SoC) are steadily growing. Yet, as the number of pins on these ASICs is not increasing in the same pace - known as pin limitation - the bandwidth per pin has to be increased. SerDes (Serializer/Deserializer) technology, which allows to transfer data serially at very high data rates of 25Gbps and more is a key technology to overcome pin limitation and exploit the computing power that can be achieved in todays SoCs. As such SerDes blocks together with the digital logic interfacing them form complex mixed signal systems, verification of performance and functional correctness is very challenging. In this thesis a novel mixed-signal design methodology is proposed, which tightly couples model and implementation in order to ensure consistency throughout the design cycles and hereby accelerate the overall implementation flow. A tool flow that has been developed is presented, which integrates well into state of the art electronic design automation (EDA) environments and enables the usage of this methodology in practice. Further, the design space of todays high-speed serial links is analyzed and an architecture is proposed, which pushes complexity into the digital domain in order to achieve robustness, portability between manufacturing processes and scaling with advanced node technologies. The all digital phase locked loop (PLL) and clock data recovery (CDR), which have been developed are described in detail. The developed design flow was used for the implementation of the SerDes architecture in a 28nm silicon process and proved to be indispensable for future projects

The truth about 2-level transition elimination in bang-bang PAM-4 CDRs

Reception of 4-level pulse amplitude modulation (PAM-4) requires a clock and data recovery (CDR) circuit, typically implemented by a PLL-like structure. An essential block in such a CDR is the phase detector which should detect whether the recovered clock leads or lags the incoming data edges. In typical implementations an incoming data edge is detected by sensing whether the incoming waveform crosses a data threshold level. However, there is some ambiguity in detecting the incoming data edge because PAM-4 modulation has 3 thresholds. If the waveform crosses multiple threshold levels, the level crossings will occur at different time instants due to the finite rise/fall time of the incoming waveform. In this work, we first analyze qualitatively and quantitatively CDR systems that use one threshold for phase adjustment. Here, eliminating the 2-level transitions decreases the amount of jitter injected by the phase detector. However, the available transitions for phase adjustment are also reduced, which lowers the CDR's robustness. Secondly, for CDR systems using three thresholds, a combination of two techniques: majority voting and elimination of 2-level transitions is investigated. We prove that in this case, the elimination of 2-level transitions is not needed and even gives a worse performance when implemented

Clocking and Skew-Optimization For Source-Synchronous Simultaneous Bidirectional Links

There is continuous expansion of computing capabilities in mobile devices which demands higher I/O bandwidth and dense parallel links supporting higher data rates. Highspeed signaling leverages technology advancements to achieve higher data rates but is limited by the bandwidth of the electrical copper channel which have not scaled accordingly. To meet the continuous data-rate demand, Simultaneous Bi-directional (SBD) signaling technique is an attractive alternative relative to uni-directional signaling as it can work at lower clock speeds, exhibits better spectral efficiency and provides higher throughput in pad limited PCBs. For low-power and more robust system, the SBD transceiver should utilize forwarded clock system and per-pin de-skew circuits to correct the phase difference developed between the data and clock. The system can be configured in two roles, master and slave. To save more power, the system should have only one clock generator. The master has its own clock source and shares its clock to the slave through the clock channel, and the slave uses this forwarded clock to deserialize the inbound data and serialize the outbound data. A clock-to-data skew exists which can be corrected with a phase tracking CDR. This thesis presents a low-power implementation of forwarded clocking and clock-to-data skew optimization for a 40 Gbps SBD transceiver. The design is implemented in 28nm CMOS technology and consumes 8.8mW of power for 20 Gbps NRZ data at 0.9 V supply. The area occupied by the clocking 0.018 mm^2 area

Timing Signals and Radio Frequency Distribution Using Ethernet Networks for High Energy Physics Applications

Timing networks are used around the world in various applications from telecommunications systems to industrial processes, and from radio astronomy to high energy physics. Most timing networks are implemented using proprietary technologies at high operation and maintenance costs. This thesis presents a novel timing network capable of distributed timing with subnanosecond accuracy. The network, developed at CERN and codenamed “White- Rabbit”, uses a non-dedicated Ethernet link to distribute timing and data packets without infringing the sub-nanosecond timing accuracy required for high energy physics applications. The first part of this thesis proposes a new digital circuit capable of measuring time differences between two digital clock signals with sub-picosecond time resolution. The proposed digital circuit measures and compensates for the phase variations between the transmitted and received network clocks required to achieve the sub-nanosecond timing accuracy. Circuit design, implementation and performance verification are reported. The second part of this thesis investigates and proposes a new method to distribute radio frequency (RF) signals over Ethernet networks. The main goal of existing distributed RF schemes, such as Radio-Over-Fibre or Digitised Radio-Over-Fibre, is to increase the bandwidth capacity taking advantage of the higher performance of digital optical links. These schemes tend to employ dedicated and costly technologies, deemed unnecessary for applications with lower bandwidth requirements. This work proposes the distribution of RF signals over the “White-Rabbit” network, to convey phase and frequency information from a reference base node to a large numbers of remote nodes, thus achieving high performance and cost reduction of the timing network. Hence, this thesis reports the design and implementation of a new distributed RF system architecture; analysed and tested using a purpose-built simulation environment, with results used to optimise a new bespoke FPGA implementation. The performance is evaluated through phase-noise spectra, the Allan-Variance, and signalto- noise ratio measurements of the distributed signals