Mix & Latch: An Optimization Flow for High-Performance Designs with Single-Clock Mixed-Polarity Latches and Flip-Flops

Flip-flops are the most used sequential elements in synchronous circuits, but designs based on latches can operate at higher frequencies and occupy less area. Techniques to increase the maximum operating frequency of flip-flop based designs, such as time-borrowing, rely on tight hold constraints that are difficult to satisfy using traditional back-end optimization techniques. We propose Mix & Latch , a methodology to increase the operating frequency of synchronous digital circuits using a single clock tree and a mixed distribution of positive- and negative-edge-triggered flops, and positive- and negative-level-sensitive latches. An efficient mathematical model is proposed to optimize the type and location of the sequential elements of the circuit. We ensure that the initial registers are not moved from their initial location, although they may change type, thus allowing the use of equivalence checking and static timing analysis to verify formally the correctness of the transformation. The technique is validated using a 28nm CMOS FDSOI technology, obtaining 1.33X post-layout average operating frequency improvement on a broad set of benchmarks over a standard commercial design flow. Additionally, the circuit area was also reduced by more than 1.19X on average for the same benchmarks, although the overall area reduction is not a goal of the optimization algorithm. To the best of our knowledge, this is the first work that proposes combining mixed-polarity flip-flops and latches to improve the circuit performance

Power and area efficient clock stretching and critical path reshaping for error resilience

Process, voltage and temperature variations are on the rise with technology scaling. Nano-scale technology requires huge design margins to ensure reliable operation. Worst case design margining consumes significant amount of circuits and systems resources. In-situ error detection or correction is an alternative method for cost effective variation tolerance. However, existing in-situ error detection and correction circuits are power and area hungry since they use speculative error management, which gives less power savings at higher error rates. This paper proposes an error resilience technique utilizing available slack in the design. The proposed method uses a clock stretching circuit to relax timing margins on selected critical paths that has sufficient consecutive stage slack. We also propose a power optimization method which reshapes the critical path logic proportionate to the consecutive stage slack. Experimental results show that the proposed method achieves the power and area savings of 40% and 8% respectively compared to the worst case design approach. When compared to the TIMBER error resilience approach, the proposed method saves power more than 74% and area more than 13% at design time. Document type: Articl

Architecture Independent Timing Speculation Techniques in VLSI Circuits.

Conventional digital circuits must ensure correct operation throughout a wide range of operating conditions including process, voltage, and temperature variation. These conditions have an effect on circuit delays, and safety margins must be put in place which come at a power and performance cost. The Razor system proposed eliminating these timing margins by running a circuit with occasional timing errors and correcting the errors when they occur. Several existing Razor style designs have been proposed, however prior to this work, Razor could not be applied blindly or automatically to designs, as the various error correction schemes modified the architecture of the target design. Because of the architectural invasiveness and design complexities of these techniques, no published Razor style system had been applied to a complete existing commercial processor. Additionally, in all prior Razor-style systems, there is a fundamental tradeoff between speculation window and short path, or minimum delay, constraints, limiting the technique’s effectiveness. This thesis introduces the concept of Razor using two-phase latch based timing. By identifying and utilizing time borrowing as an error correction mechanism, it allows for Razor to be applied without the need to reload data or replay instructions. This allows for Razor to be blindly and automatically applied to existing designs without detailed knowledge of internal architecture. Additionally, latch based Razor allows for large speculation windows, up to 100% of nominal circuit delay, because it breaks the connection between minimum delay constraints and speculation window. By demonstrating how to transform conventional flip-flop based designs, including those which make use of clock gating, to two-phase latch based timing, Razor can be automatically added to a large set of existing digital designs. Two forms of latch based Razor are proposed. First, Bubble Razor involves rippling stall cycles throughout a circuit in response to timing errors and is applied to the ARM Cortex-M3 processor, the first ever application of a Razor technique to a complete, existing processor design. Additional work applies Bubble Razor to the ARM Cortex-R4 processor. The second latch based Razor technique, Voltage Razor, uses voltage boosting to correct for timing errors.PHDElectrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/102461/1/mfojtik_1.pd

A robust ultra-low voltage CPU utilizing timing-error prevention

To minimize energy consumption of a digital circuit, logic can be operated at sub- or near-threshold voltage. Operation at this region is challenging due to device and environment variations, and resulting performance may not be adequate to all applications. This article presents two variants of a 32-bit RISC CPU targeted for near-threshold voltage. Both CPUs are placed on the same die and manufactured in 28 nm CMOS process. They employ timing-error prevention with clock stretching to enable operation with minimal safety margins while maximizing performance and energy efficiency at a given operating point. Measurements show minimum energy of 3.15 pJ/cyc at 400 mV, which corresponds to 39% energy saving compared to operation based on static signoff timing.</p

Power efficient resilient microarchitectures for PVT variability mitigation

Nowadays, the high power density and the process, voltage, and temperature variations became the most critical issues that limit the performance of the digital integrated circuits because of the continuous scaling of the fabrication technology. Dynamic voltage and frequency scaling technique is used to reduce the power consumption while different time relaxation techniques and error recovery microarchitectures are used to tolerate the process, voltage, and temperature variations. These techniques reduce the throughput by scaling down the frequency or flushing and restarting the errant pipeline. This thesis presents a novel resilient microarchitecture which is called ERSUT-based resilient microarchitecture to tolerate the induced delays generated by the voltage scaling or the process, voltage, and temperature variations. The resilient microarchitecture detects and recovers the induced errors without flushing the pipeline and without scaling down the operating frequency. An ERSUT-based resilient 16 × 16 bit MAC unit, implemented using Global Foundries 65 nm technology and ARM standard cells library, is introduced as a case study with 18.26% area overhead and up to 1.5x speedup. At the typical conditions, the maximum frequency of the conventional MAC unit is about 375 MHz while the resilient MAC unit operates correctly at a frequency up to 565 MHz. In case of variations, the resilient MAC unit tolerates induced delays up to 50% of the clock period while keeping its throughput equal to the conventional MAC unit’s maximum throughput. At 375 MHz, the resilient MAC unit is able to scale down the supply voltage from 1.2 V to 1.0 V saving about 29% of the power consumed by the conventional MAC unit. A double-edge-triggered microarchitecture is also introduced to reduce the power consumption extremely by reducing the frequency of the clock tree to the half while preserving the same maximum throughput. This microarchitecture is applied to different ISCAS’89 benchmark circuits in addition to the 16x16 bit MAC unit and the average power reduction of all these circuits is 63.58% while the average area overhead is 31.02%. All these circuits are designed using Global Foundries 65nm technology and ARM standard cells library. Towards the full automation of the ERSUT-based resilient microarchitecture, an ERSUT-based algorithm is introduced in C++ to accelerate the design process of the ERSUT-based microarchitecture. The developed algorithm reduces the design-time efforts dramatically and allows the ERSUT-based microarchitecture to be adopted by larger industrial designs. Depending on the ERSUT-based algorithm, a validation study about applying the ERSUT-based microarchitecture on the MAC unit and different ISCAS’89 benchmark circuits with different complexity weights is introduced. This study shows that 72% of these circuits tolerates more than 14% of their clock periods and 54.5% of these circuits tolerates more than 20% while 27% of these circuits tolerates more than 30%. Consequently, the validation study proves that the ERSUT-based resilient microarchitecture is a valid applicable solution for different circuits with different complexity weights