arket forces are continually demanding devices with increased functionality/unit area; these demands have been satisfied through aggressive technology scaling which, unfortunately, has impacted adversely on the global interconnect delay subsequently reducing system performance. Line drivers have been used to mitigate the problems with delay; however, these have a large power consumption. A solution to reducing the power dissipation of the drivers is to use lower supply voltages. However, by adopting a lower power supply voltage, the performance of the line drivers for global interconnects is impaired unless low-swing signalling techniques are implemented. Low-swing signalling techniques can provide high speed signalling with low power consumption and hence can be used to drive global on-chip interconnect. Most of the proposed low-swing signalling schemes are immune to noise as they have a good SNR. However, they tend to have a large penalty in area and complexity as they require additional circuitry such as voltage generators and low-Vth devices. Most of the schemes also incorporate multiple Vdd and reference voltages which increase the overall circuit complexity. A diode-connected driver circuit has the best attributes over other low-swing signalling techniques in terms of low power, low delay, good SNR and low area overhead. By incorporating a diode-connected configuration at the output, it can provide high speed signalling due to its high driving capability. However, this configuration also has its limitations as it has issues with its adaptability to process variations, as well as an issue with leakage currents. To address these limitations, two novel driver schemes have been designed, namely, nLVSD and mLVSD, which, additionally, have improvements in performance and power consumption. Comparisons between the proposed schemes with the existing diode-connected driver circuits (MJ and DDC) showed that the nLVSD and mLVSD drivers have approximately 46% and 50% less delay. The name MJ originates from the driver’s designer called Juan A. Montiel-Nelson, while DDC stands for dynamic diode-connected. In terms of power consumption, the nLVSD and mLVSD drivers also produce 43% and 7% improvement. Additionally, the mLVSD driver scheme is the most robust as its SNR is 14 to 44% higher compared to other diode-connected driver circuits. On the other hand, the nLVSD driver has 6% lower SNR compared to the MJ driver, even though it is 19% more robust than the DDC driver. However, since its SNR is still above 1, its improved performance and reduced power consumption, as well other advantages it has over other diode-connected driver circuits can compensate for this limitation. Regarding the robustness to external disturbances, the proposedmdriver circuits are more robust to crosstalk effects as the nLVSD and mLVSD drivers are approximately 35% and 7% more robust than other diode-connected drivers. Furthermore, the mLVSD driver is 5%, 33% and 47% more tolerant to SEUs compared to the nLVSD, MJ and DDC driver circuits respectively, whilst the MJ and DDC drivers are 26% and 40% less tolerant to SEUs iii compared to the nLVSD circuit. A comparison between the four schemes was also undertaken in the presence of ±3σ process and voltage (PV) variations. The analysis indicated that both proposed driver schemes are more robust than other diode-connected driver schemes, namely, the MJ and DDC driver circuits. The MJ driver scheme deviates approximately 18% and 35% more in delay and power consumption compared to the proposed schemes. The DDC driver has approximately 20% and 57% more variations in delay and power consumption in comparison to the proposed schemes. In order to further improve the robustness of the proposed driver circuits against process variation and environmental disturbances, they were further analysed to identify which process variables had the most impact on circuit delay and power consumption, as well as identifying several design techniques to mitigate problems with environmental disturbances. The most significant process parameters to have impact on circuit delay and power consumption were identified to be Vdd, tox, Vth, s, w and t. The impact of SEUs on the circuit can be reduced by increasing the bias currents whilst design methods such as increasing the interconnect spacing can help improve the circuit robustness against crosstalk. Overall it is considered that the proposed nLVSD and mLVSD circuits advance the state of the art in driver design for on-chip signalling applications.
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机译:药船部队对功能/单位面积不断增加的设备要求不断提高;这些要求已通过积极的技术扩展得到满足,但不幸的是,这对全局互连延迟产生了不利影响,进而降低了系统性能。线路驱动器已被用来缓解延迟问题。但是,这些具有很大的功耗。降低驱动器功耗的一种解决方案是使用较低的电源电压。但是,除非采用低摆幅信令技术,否则采用较低的电源电压会损害用于全局互连的线路驱动器的性能。低摆幅信令技术可提供具有低功耗的高速信令,因此可用于驱动全局片上互连。大多数提议的低摆信令方案均具有良好的SNR,因此不受噪声影响。但是,由于它们需要诸如电压发生器和低Vth器件之类的附加电路,因此它们往往会在面积和复杂性上造成很大的损失。大多数方案还包含多个Vdd和参考电压,这会增加整个电路的复杂性。与其他低摆幅信令技术相比,二极管连接的驱动器电路在低功耗,低延迟,良好的SNR和低面积开销方面具有最佳的属性。通过在输出端采用二极管连接配置,由于其高驱动能力,它可以提供高速信号。然而,这种配置也有其局限性,因为它具有对工艺变化的适应性的问题,以及泄漏电流的问题。为了解决这些限制,已经设计了两种新颖的驱动器方案,即nLVSD和mLVSD,此外,它们还改善了性能和功耗。所提出的方案与现有的二极管连接的驱动器电路(MJ和DDC)之间的比较表明,nLVSD和mLVSD驱动器的延迟减少了约46%和50%。 MJ的名称源自驾驶员的设计师Juan A. Montiel-Nelson,而DDC则表示动态二极管连接。在功耗方面,nLVSD和mLVSD驱动程序也产生了43%和7%的改善。此外,mLVSD驱动器方案最强大,因为其SNR比其他二极管连接的驱动器电路高14至44%。另一方面,nLVSD驱动器的信噪比比MJ驱动器低6%,尽管它比DDC驱动器强19%。但是,由于其SNR仍高于1,因此其改进的性能和降低的功耗以及与其他二极管连接的驱动器电路相比具有的其他优点可以弥补这一限制。关于外部干扰的鲁棒性,由于nLVSD和mLVSD驱动器比其他二极管连接的驱动器的鲁棒性分别高35%和7%,因此所提出的mdriver电路对串扰的影响更加鲁棒。此外,与nLVSD,MJ和DDC驱动器电路相比,mLVSD驱动器对SEU的耐受性分别高5%,33%和47%,而MJ和DDC驱动器对SEU iii的耐受性则比nLVSD,MJ和DDC驱动器电路低6%。 nLVSD电路。在±3σ工艺和电压(PV)变化的情况下,还对四种方案进行了比较。分析表明,两种提出的驱动器方案都比其他二极管连接的驱动器方案(即MJ和DDC驱动器电路)更健壮。与拟议的方案相比,MJ驱动器方案在延迟和功耗上分别高出约18%和35%。与建议的方案相比,DDC驱动器的延迟和功耗变化分别多出约20%和57%。为了进一步提高所提出的驱动器电路抵抗过程变化和环境干扰的鲁棒性,对它们进行了进一步分析,以确定哪些过程变量对电路延迟和功耗有最大的影响,并确定了几种设计技术来缓解问题。环境干扰。对电路延迟和功耗有影响的最重要的工艺参数被确定为Vdd,tox,Vth,s,w和t。可以通过增加偏置电流来减少SEU对电路的影响,而诸如增加互连间隔之类的设计方法可以帮助提高电路抗串扰的鲁棒性。总体而言,可以认为,所提出的nLVSD和mLVSD电路在片上信号应用的驱动器设计方面处于先进水平。
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