Development of a Machine Learning Model with a Function of Amygdala for Rapid Image Processing

<p>Caiye Fan<sup>1</sup>, Sunwoo Ko<sup>2</sup>, Linyang Yan<sup>1</sup></p>

doi:10.25236/AJCIS.2021.040406

Academic Journal of Computing & Information Science, 2021, 4(4); doi: 10.25236/AJCIS.2021.040406.

Development of a Machine Learning Model with a Function of Amygdala for Rapid Image Processing

Author(s)

Caiye Fan¹, Sunwoo Ko², Linyang Yan¹

Corresponding Author:

Caiye Fan

Affiliation(s)

¹Department of Cultural Technology (Artificial Intelligence), Jeonju University, Korea

²Department of Artificial Intelligence, Jeonju University, Korea

Download PDF
|
Download: 101
|
View: 1205

Abstract

In this paper, a method of implementing convolutional neural network that can quickly deal with dangerous situations is designed based on the processing rules of the amygdala of human brain. By studying the processing rules of the amygdala in the human brain, we can understand neuron activity when humans are at risk, build similar models, and test relevant data. A neural network model can be constructed by changing structure, loss function and number of filters the general convolutional neural network model. The designed neural network model can quickly and accurately predict dangers. It was used to test data set and good results were obtained.

Keywords

Amygdala, biological learning method, convolutional neural network, image processing

Cite This Paper

Caiye Fan, Sunwoo Ko, Linyang Yan. Development of a Machine Learning Model with a Function of Amygdala for Rapid Image Processing. Academic Journal of Computing & Information Science (2021), Vol. 4, Issue 4: 35-40. https://doi.org/10.25236/AJCIS.2021.040406.

References

[1] J. L. Hellier, The Brain, the Nervous System, and Their Diseases [3 volumes]; ABC-CLIO, 2014, pp. 300–303.

[2] M. S. Gazzaniga, G. R. Mangun, R. B. Ivry, Cognitive Neuroscience: The Biology of the Mind; New York: W.W. Norton, 2014, pp. 45

[3] L. R. Squire, "Memory and the hippocampus: a synthesis from findings with rats, monkeys, and humans," Psychol Rev, vol. 99, pp. 195-231, April 1992.

[4] J. S. Feinstein, R. Adolphs, A. Damasio, D. Tranel, "The human amygdala and the induction and experience of fear," Current Biology, vol. 21, pp. 34-38, January 2011.

[5] E. R. Kandel, J. H. Schwartz, T. M. Jessel, H. James, M. Thomas, Principles of Neural Science; New York: McGraw-Hill, 2000, ch. 2-4.

[6] J. E. LeDoux, Synaptic Self: How Our Brains Become Who We Are also viewed; Penguin, 2003, ch. 3, pp.80-117.

[7] J. J. Kim, M. W. Jung, "Neural circuits and mechanisms involved in Pavlovian fear conditioning: a critical review," Neurosci Biobehav Rev, vol. 30, pp. 188-202, February 2006.

[8] X. F. Li, G. E. Stutzmann, J. E. LeDoux, "Convergent but temporally separated inputs to lateral amygdala neurons from the auditory thalamus and auditory cortex use different postsynaptic receptors: in vivo intracellular and extracellular recordings in fear conditioning pathways," Learn Mem, vol. 3, pp. 229-242, September 1996.

[9] G. J. Quirk, J. L. Armony, J. E. LeDoux, "Fear Conditioning Enhances Different Temporal Components of Tone-Evoked Spike Trains in Auditory Cortex and Lateral Amygdala," Neuron, vol. 19, pp. 613-624, September 1997.

[10] G. J. Quirk, C. Repa, J. E. LeDoux, "Fear conditioning enhances short-latency auditory responses of lateral amygdala neurons: parallel recordings in the freely behaving rat," Neuron, vol. 15, pp. 1029-39, November 1995.

[11] J. E. LeDoux, Synaptic Self: How Our Brains Become Who We Are also viewed; Penguin, 2003, ch. 5, pp.210-218.