plays an important role in the history and might impact the future of
humanity. Today, AI is more available now than ever. Products and
services driven by AI technologies have widely emerged around us and
have led to a profound impact on daily life. Predictably, AI will act as the
one of the backbones of new technological revolutions. Nevertheless,
several troughs may once again take place if the
technologies/applications cannot be grounded swiftly according to the
expectations from the dominant stakeholders (inventors rather than the
general public). The article is intended to help the readers to better
understand AI, accept AI, and think more deeply about AI. With the long-
lasting curiosity and wisdom, we are likely to witness the beauty of a
world with the novel AI ecology. As Ophelia stated in Shakespeare’s play
Hamlet, “we know what we are, but we know not what we may become.”
References
1. Kaynak O. The golden age of Artificial Intelligence. Discov Artif Intell.
2021;1:1. https://doi.org/10.1007/s44163-021-00009-x.
Article Google Scholar
2. McCarthy J, Minsky ML, Rochester N, Shannon CE. A proposal for the
Dartmouth summer research project on artificial intelligence.
Stanford: AI Magazine; 1995.
Google Scholar
3. Market research report, markets and markets, report code: TC 7894,
May
2021. https://www.marketsandmarkets.com/Market-Reports/artificial
-intelligence-market-74851580.html.
4. Hinton G, Deng L, Yu D, Dahl GE, et al. Deep neural networks for
acoustic modeling in speech recognition: the shared views of four
research groups. IEEE Signal Process Mag. 2012;29(6):82–97.
Article Google Scholar
5. Graves A, Mohamed AR, Hinton G. Speech recognition with deep
recurrent neural networks. In: IEEE international conference on
acoustics, speech and signal processing. IEEE: Piscataway; 2013. p.
6645–9.
Chapter Google Scholar
6. Chollet F. Xception: deep learning with depthwise separable
convolutions. In: Proceedings of the IEEE conference on computer
vision and pattern recognition. IEEE: Piscataway; 2017. p. 1251–8.
Google Scholar
�7. He K, Zhang X, Ren S, Sun J. Deep residual learning for image
recognition. In: Proceedings of the IEEE conference on computer
vision and pattern recognition. IEEE: Piscataway; 2016. p. 770–8.
Google Scholar
8. Devlin J, Chang MW, Lee K, Toutanova K. Bert: pre-training of deep
bidirectional transformers for language understanding. Comput
Lang. 2018. https://doi.org/10.48550/arXiv.1810.04805.
Article Google Scholar
9. Sutskever I, Vinyals O, Le QV. Sequence to sequence learning with
neural networks. In: Advances in neural information processing
systems. Canada: NeurIPS; 2014. p. 3104–12.
Google Scholar
10. Gualtieri L, Rauch E, Vidoni R. Emerging research fields in
safety and ergonomics in industrial collaborative robotics: a
systematic literature review. Robot Comput Integr Manuf.
2021;67:101998.
Article Google Scholar
11. Palagi S, Fischer P. Bioinspired microrobots. Nat Rev Mater.
2018. https://doi.org/10.1038/s41578-018-0016-9.
Article Google Scholar
12. Menouar H, Guvenc I, Akkaya K, et al. UAV-enabled intelligent
transportation systems for the smart city: applications and
challenges. IEEE Commun Mag. 2017;55(3):22–8.
