Energy-efficient and metastability-immune timing-error detection and recovery circuits for dynamic variation tolerance

Author

Bowman, Keith A. ; Tschanz, James W. ; Kim, Nam Sung ; Lee, Janice C. ; Wilkerson, Chris B. ; Lu, Shih-Lien L. ; Karnik, Tanay ; De, Vivek K.

Author_Institution

Intel Corp., Hillsboro, OR

fYear

2008

fDate

2-4 June 2008

Firstpage

155

Lastpage

158

Abstract

Timing-error detection and recovery circuits are implemented in a 65 nm resilient circuit test-chip to eliminate the clock frequency guardband from dynamic supply voltage (V_CC) and temperature variations as well as to exploit path-activation probabilities for maximizing throughput. Two error-detection sequential (EDS) circuits are introduced to preserve the timing-error detection capability of previous EDS designs while lowering clock energy and removing datapath metastability. Error-recovery circuits replay failing instructions at lower clock frequency to guarantee correct functionality. Relative to conventional circuits, silicon measurements indicate that resilient circuits enable either 25 to 32% throughput gain at equal V_CC or at least 17% VCC reduction at equal throughput, resulting in 31 to 37% total power reduction.

Keywords

error detection; sequential circuits; silicon; timing circuits; dynamic supply voltage; dynamic variation tolerance; error-detection sequential circuits; error-recovery circuits; metastability-immune timing-error detection; path-activation probabilities; silicon measurements; size 65 nm; Circuit testing; Clocks; Energy efficiency; Error correction; Frequency; Metastasis; Silicon; Temperature distribution; Throughput; Voltage;

fLanguage

English

Publisher

ieee

Conference_Titel

Integrated Circuit Design and Technology and Tutorial, 2008. ICICDT 2008. IEEE International Conference on

Conference_Location

Austin, TX

Print_ISBN

978-1-4244-1810-7

Electronic_ISBN

978-1-4244-1811-4

Type

conf

DOI

10.1109/ICICDT.2008.4567268

Filename

4567268