Abstract
We propose a novel dynamic voltage scaling (DVS) approach for reliable and energy efficient cache memories. First, we demonstrate that, as memories age, leakage power reduction techniques become more effective due to sub-threshold current reduction with aging. Then, we provide an analytical model and a design exploration framework to evaluate trade-offs between leakage power and reliability, and propose a BTI and leakage aware selection of the 'drowsy' state retention voltage for DVS of cache memories. We propose three DVS policies, allowing us to achieve different power/reliability trade-offs. Through SPICE simulations, we show that a critical charge and a static noise margin increase up to 150% and 34.7%, respectively, is achieved compared to standard aging unaware drowsy technique, with a limited leakage power increase during the very early lifetime, and with leakage energy saving up to 37% in 10 years of operation. These improvements are attained at zero or negligible area cost.
Original language | English |
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Title of host publication | Proceedings of the 21st IEEE International On-Line Testing Symposium, IOLTS 2015 |
Publisher | Institute of Electrical and Electronics Engineers (IEEE) |
Pages | 194-199 |
Number of pages | 6 |
ISBN (Electronic) | 9781467379045 |
DOIs | |
Publication status | Published - 28 Aug 2015 |
Event | 21st IEEE International On-Line Testing Symposium, IOLTS 2015 - Elia, Halkidiki, Greece Duration: 6 Jul 2015 → 8 Jul 2015 |
Conference
Conference | 21st IEEE International On-Line Testing Symposium, IOLTS 2015 |
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Country/Territory | Greece |
City | Elia, Halkidiki |
Period | 6/07/15 → 8/07/15 |