Lund University Publications

@phdthesis{d24f73b5-fe7a-40f2-90ee-6b81206d9eb1,
  abstract     = {{The ever expanding market of ultra portable electronic products is compelling the designer to invest major efforts in the development<br/><br>
of small and low energy electronic devices. The driving force and benefactors of such devices are (but not limited to) e-health<br/><br>
system, sensor network applications, security systems, environmental applications, and home automation systems. These markets<br/><br>
have launched a massive trend towards ultra low-energy and ultra low-voltage devices. As the technology scales, the dimensions<br/><br>
of a transistors have become extremely small, leading to reliability and process variation issues. Above all, with the ability of<br/><br>
placing millions of gates in a small area, high current consumption have become one of the key factors in modern high-performance<br/><br>
technologies. In portable electronics, the battery life time is a major issue, as most of the time the device is accompanied with an<br/><br>
enclosed battery that has to last for long periods without compromise on performance. Furthermore, there are many applications<br/><br>
where the battery lifetime sets the lifetime of the device. Therefore, research is needed to identify the techniques and the impact of<br/><br>
them on the design operated for ultra low-energy. The low energy dissipation requirements on a design are achievable by employing<br/><br>
various optimization techniques. Voltage scaling is the most effective knob to reduce energy dissipation. For this reason ultra-low<br/><br>
energy design usually translates into ultra-low voltage or subthreshold (sub-VT) domain operation. This work presents an analysis<br/><br>
on design space for ultra-low energy dissipation of digital circuits. The circuits are operated in the sub-VT region with moderate<br/><br>
throughput constraints. The drawback of operating circuits in sub-VT is slow speed performances and reduced reliability. To<br/><br>
combat speed degradation due to scaling of the supply voltage, the architectural design space, needs exploration. Techniques such as<br/><br>
device sizing, body biasing, stacking transistors, dual threshold gates, multi threshold synthesis, pipelining, and loop unfolding, are<br/><br>
explored and applied to the designs. The designs are synthesized in a 65 nm CMOS technology with low-power and three threshold<br/><br>
options, both as single-VT and as multi-VT designs. A sub-VT energy model is applied to characterize the designs in the sub-<br/><br>
VT domain. Reliability in the sub-VT domain is analyzed by Monte-Carlo simulations. The minimum reliable operation voltage<br/><br>
(ROV) for gates in low power 65 nm CMOS technology is found to be around 250 mV. The applied energy model for designs to<br/><br>
be characterized for sub-VT domain operation is presented. The energy model encompasses single VT implementations and multi-<br/><br>
VT implementations. The energy modeling is based on the 65 nm CMOS standard cells provided by the technology vendor. The<br/><br>
energy model has been used to evaluate various techniques and constraints for a circuits operated in the sub-VT domain. The work<br/><br>
describes how the energy dissipation of architectures vary w.r.t. switching activity, e. The effects of pipelining together with supply<br/><br>
voltage scaling is analyzed, which shows that they have high benefits with respect to energy dissipation. Various half-band digital<br/><br>
(HBD) filter structures are evaluated for minimum energy dissipation in the sub-VT domain for a throughput constrained system. All<br/><br>
architectures, i.e., unfolded and the basic HBD filter, are implemented and simulated using 65 nm Low-Power High-Threshold (HVT)<br/><br>
standard cells. The application of a sub-VT energy model reveals that it is beneficial to use an unfolded implementation to achieve<br/><br>
low energy dissipation per sample at EMV, when compared to the energy dissipated by a basic simplified HBD filter implementation.<br/><br>
Various available threshold options are analyzed with the help of filter structures by using 65 nm Low-Leakage High-Threshold<br/><br>
(HVT), Standard-Threshold (SVT) and Low-Threshold (LVT) standard cells. Secondly, the design space is increased by utilization<br/><br>
of a combination of HVT + SVT and also HVT + LVT cells. The analysis with sub-VT energy model leads to the conclusion<br/><br>
that a suitable design is a synergy between parallelism, and utilization of various threshold options. In this analysis the multi-VT,<br/><br>
implementations did not show a major advantage over single VT implementations. A decimation filter chain consisting of 4 HBD<br/><br>
filters is fabricated and the silicon measurements demonstrate that SVT and different architectural flavors are suitable for a ultra<br/><br>
low energy (ULE) implementation. Silicon measurements prove functionality down to a supply at 350 mV, with a maximum clock<br/><br>
frequency of 500 kHz, having an energy dissipation of 102 fJ/cycle. Additionally, an alternative to SRAM macro is presented for<br/><br>
sub-VT operations. The memory is based on standard-cells and is referred to as SCMs. The energy per memory access as well as the<br/><br>
maximum achievable throughput in the sub-VT domain of various SCM architectures are evaluated by means of a gate-level sub-VT<br/><br>
energy characterization model.}},
  author       = {{Sherazi, Syed Muhammad Yasser}},
  isbn         = {{978-91-7473-725-7}},
  keywords     = {{CMOS; ultra low-voltage; ultra low-energy; subthreshold (sub-VT); body biasing; pipelining; unfolding; half-band digital filter.}},
  language     = {{eng}},
  publisher    = {{Lund University}},
  school       = {{Lund University}},
  title        = {{Design Space Exploration of Digital Circuits for Ultra-low Energy Dissipation}},
  url          = {{https://lup.lub.lu.se/search/files/3439813/4196460.pdf}},
  year         = {{2013}},
}