Title :
A 1.2–0.55V general-purpose biomedical processor with configurable machine-learning accelerators for high-order, patient-adaptive monitoring
Author :
Lee, Kyong Ho ; Verma, Naveen
Author_Institution :
Dept. of Electr. Eng., Princeton Univ., Princeton, NJ, USA
Abstract :
Machine learning offers powerful advantages in sensing systems, enabling the creation and adaptation of high-order signal models by exploiting the sensed data. We present a general-purpose processor that employs configurable machine-learning accelerators to analyze physiological signals at low energy levels for a broad range of biomedical applications. Implemented in 130nm LP CMOS, the processor operates from 1.2V-0.55V (logic). It achieves real-time EEG-based seizure detection at 273μW (at 0.85V) and patient-adaptive ECG-based cardiac-arrhythmia detection at 124μW (at 0.75V), yielding overall energy savings of 62.4× and 144.7× thanks to the accelerators.
Keywords :
CMOS logic circuits; biomedical equipment; electrocardiography; electroencephalography; learning (artificial intelligence); medical disorders; medical signal detection; medical signal processing; patient monitoring; LP CMOS; biomedical applications; configurable machine-learning accelerators; energy levels; general-purpose biomedical processor; high-order patient-adaptive monitoring; high-order signal models; patient-adaptive ECG-based cardiac arrhythmia detection; physiological signals; power 124 muW; power 273 muW; real-time EEG-based seizure detection; sensing systems; size 130 nm; voltage 1.2 V to 0.55 V; Brain models; Computational modeling; Data models; Kernel; Machine learning; Support vector machines;
Conference_Titel :
ESSCIRC (ESSCIRC), 2012 Proceedings of the
Conference_Location :
Bordeaux
Print_ISBN :
978-1-4673-2212-6
Electronic_ISBN :
1930-8833
DOI :
10.1109/ESSCIRC.2012.6341275
