Title :
Power Consumption During Neuronal Computation
Author :
Sengupta, Biswa ; Stemmler, Martin B.
Author_Institution :
Wellcome Trust Centre for Neuroimaging, Univ. Coll. London, London, UK
Abstract :
Maintaining the ability of the nervous system to perceive, remember, process, and react to the outside world requires a continuous energy supply. Yet the overall power consumption is remarkably low, which has inspired engineers to mimic nervous systems in designing artificial cochlea, retinal implants, and brain-computer interfaces (BCIs) to improve the quality of life in patients. Such neuromorphic devices are both energy efficient and increasingly able to emulate many functions of the human nervous system. We examine the energy constraints of neuronal signaling within biology, review the quantitative tradeoff between energy use and information processing, and ask whether the biophysics and design of nerve cells minimizes energy consumption.
Keywords :
bioelectric phenomena; biomedical electronics; biomedical engineering; biomimetics; brain models; brain-computer interfaces; cellular biophysics; cognition; energy conservation; low-power electronics; neural nets; neurophysiology; power consumption; prosthetics; BCI design; artificial cochlea design; brain-computer interface design; energy efficient devices; energy supply; energy use; human nervous system mimicking; information processing; nerve cell biophysics; nerve cell design; neuromorphic devices; neuronal computation; neuronal signaling energy constraints; power consumption; quantitative tradeoff; retinal implant design; Biological system modeling; Biophysics; Electric potential; Energy efficiency; Neurons; Neuroscience; Noise measurement; Power consumption; Power demand; Biological information theory; biological neural networks; biological optimization; cellular biophysics; energy consumption; energy efficiency;
Journal_Title :
Proceedings of the IEEE
DOI :
10.1109/JPROC.2014.2307755
