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An energy efficient TCAM enhanced cache architectureSurprise, Jason Mathew 29 August 2005 (has links)
Microprocessors are used in a variety of systems ranging from high-performance super
computers running scientific applications to battery powered cell phones performing realtime
tasks. Due to the large disparity between processor clock speed and main memory
access time, most modern processors include several caches, which consume more than half
of the total chip area and power budget. As the performance gap between processors and
memory has increased, the trend has been to increase the size of the on-chip caches.
However, increasing the cache size also increases its access time and energy consumptions.
This growing power dissipation problem is making traditional cooling and packaging
techniques less effective thus requiring cache designers to focus more on architectural level
energy efficiency than performance alone.
The goal of this thesis is to propose a new cache architecture and to evaluate its
efficiency in terms of miss rate, system performance, energy consumption, and area
overhead. The proposed architecture employs the use of a few Ternary-CAM (TCAM)
cells in the tag array to enable dynamic compression of tag entries containing contiguous
values. By dynamically compressing tag entries, the number of entries in the tag array can
be reduced by 2N, where N is the number of tag bits that can be compressed. The architecture described in this thesis is applicable to any cache structure that uses Content
Addressable Memory (CAM) cells to store tag bits.
To evaluate the effectiveness of the TCAM Enhanced Cache Architecture for a wide
scope of applications, two case studies were performed ?? the L2 Data-TLB (DTLB) of a
high-performance processor and the L1 instruction and data caches of a low-power
embedded processor. Results indicate that a L2 DTLB implementing 3-bit tag compression
can achieve 93% of the performance of a conventional L2 DTLB of the same size while
reducing the on-chip energy consumption by 74% and the total area by 50%. Similarly, an
embedded processor cache implementing 2-bit tag compression achieves 99% of the
performance of a conventional cache while reducing the on-chip energy consumption by
33% and the total area by 10%.
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An Area Efficient 10-bit Time Mode Digital- to- Analog Converter with Current Settling Error Compensation TechniqueRavikumar, Nivethithaa 15 September 2015 (has links)
No description available.
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Exploration Of Energy And Area Efficient Techniques For Coarse-grained Reconfigurable FabricsYadav, Anil 12 1900 (has links)
Coarse-grained fabrics are comprised of multi-bit configurable logic blocks and configurable interconnect. This work is focused on area and energy optimization techniques for coarse-grained reconfigurable fabric architectures. In this work, a variety of design techniques have been explored to improve the utilization of computational resources and increase energy savings. This includes splitting, folding, multi-level vertical interconnect. In addition to this, I have also studied fully connected homogeneous and heterogeneous architectures, and 3D architecture. I have also examined some of the hybrid strategies of computation unit’s arrangements. In order to perform energy and area analysis, I selected a set of signal and image processing benchmarks from MediaBench suite. I implemented various fabric architectures on 90nm ASIC process from Synopsys. Results show area improvement with energy savings as compared to baseline architecture.
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Performance enhancement techniques for low power digital phase locked loopsElshazly, Amr 16 July 2014 (has links)
Desire for low-power, high performance computing has been at core of the symbiotic union between digital circuits and CMOS scaling. While digital circuit performance improves with device scaling, analog circuits have not gained these benefits. As a result, it has become necessary to leverage increased digital circuit performance to mitigate analog circuit deficiencies in nanometer scale CMOS in order to realize world class analog solutions.
In this thesis, both circuit and system enhancement techniques to improve performance of clock generators are discussed. The following techniques were developed: (1) A digital PLL that employs an adaptive and highly efficient way to cancel the effect of supply noise, (2) a supply regulated DPLL that uses low power regulator and improves supply noise rejection, (3) a digital multiplying DLL that obviates the need for high-resolution TDC while achieving sub-picosecond jitter and excellent supply noise immunity, and (4) a high resolution TDC based on a switched ring oscillator, are presented. Measured results obtained from the prototype chips are presented to illustrate the proposed design techniques. / Graduation date: 2013 / Access restricted to the OSU Community at author's request from July 16, 2012 - July 16, 2014
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