Category Archives: The field of AI

The Field of AI (Part 02-3): A “Pre-History” & a Foundational Context

URLs for A “Pre-History” & a Foundational Context:

  • This post is the main post on a Pre-History & a Foundational context of the Field of AI. In this post a narrative is constructed surrounding the “Pre-History”. It links with the following posts:
  • The post here is a first and very short linking with on Literature, Mythology & Arts as one of the foundational contexts of the Field of AI
  • The second part in the contextualization is the post touching on a few attributes from Philosophy, Psychology and Linguistics
  • Following, one can read about very few attributes picked up on from Control Theory as contextualizing to the Field of AI
  • Cognitive Science is the fourth field that is mapped with the Field of AI.
  • Mathematics & Statistics is in this writing the sixth area associated as a context to the Field of AI
  • Other fields contextualizing the Field of AI are being considered (e.g. Data Science & Statistics, Economy, Engineering fields)


02 — The Field of AI: A Foundational Context:
Philosophy, Psychology & Linguistics

Philosophy:

 In the early days of philosophy (while often associated with the Ancient Greeks, surely found in other comparable forms in many intellectual, knowledge-seeking communities throughout history) and up till present days, people create forms of logic, they study and think about the (existence, developments, meaning, processes, applications, … of) mind, consciousness, cognition, language, reasoning, rationality, learning, knowledge, and so on.   

Logic too, often has been claimed as being an Old Greek invention; specifically by Aristotle (384 B.C to 322 B.C.). It has, however, more or less independent traditions across the globe and across time. Logic lies at the basis of, for instance, Computational Thinking, of coding, of mathematics, of language, and of Artificial Intelligence. In its most basic (and etymologically), logic comes from Ancient Greek “Logos” (λόγος), which simply means “speech”, “reasoning”, “word” or “study”. Logic can, traditionally, be understood as “a method of human thought that involves thinking in a linear, step-by-step manner about how a problem can be solved. Logic is the basis of many principles including the scientific method.”[1] Note, following the result of research and development (R&D) in fields that could be associated with the field of AI and within the field of AI itself, can show that today logic, in its various forms, is not only a linear process. Moreover, at present, the study of logic has been an activity no longer limited to the field of philosophy alone and is studied in various fields including computer science, linguistics or cognitive science as well.

 One author covering a topic of AI, tried to make the link between Philosophy and Artificial Intelligence starkly clear. As a discipline, AI is offered the consideration as possibly being “philosophical engineering.”[2] In this linkage, the field of AI is positioned as one researching more philosophical concepts from any field of science and from Philosophy itself that are then transcoded, from mathematical algorithms to artificial neural networks. This linkage proposes that philosophy covers ideas that are experienced as, for instance, ambiguous or complex or open for deep debate. Historically, philosophy tried to define, or at least explore, many concepts including ‘knowledge,’ ‘meaning,’ and ‘reasoning,’ which are broadly considered to be processes or states of a larger set known as “intelligence”. The latter itself too has been a fertile topic for philosophy. The field of AI as well has been trying to explore or even solve some of these attributes. The moment it solved some expressions of these, it was often perceived as taking away not only the mystery but also the intelligence of the expressed form. The first checker or chess “AI” application is hardly considered “intelligent” these days. The first AI solution beating a champion in such culturally established board games has later been shown to lack sufficient “intelligence” to beat a newer version of an AI application. Maybe that improved version might (or will) be beaten again, perhaps letting the AI applications race on and on? Just perhaps contrary to “philosophical engineering,” would the field of AI be practically engineering the philosophy out of some concepts?

Mini
Project #___:  algorithms in daily life
Find out what “algorithm” in general (in a more non-mathematical or more non-coding sense) means. Can you find it has similarities with the meaning of “logic”? If so, which attributes seem similar?
What do you think ‘algorithm’ could mean and could be in daily life (outside of the realm of Computer Science)? Are there algorithms we use that are not found in a computer?

Mini Project #___: The Non-technological Core of AI
Collect references of what consciousness, intelligence, rationality, reasoning and mind have meant in the history of the communities and cultures around you. 
Share your findings in a collection of references from the entire class. 
Maybe add your findings to the collage (see the Literature project above).
Alternative: the teacher shares a few resources or references of philosophers that covered these topics and that are examples of the pre-history of AI.



Psychology

Psychology has influenced and is influenced by research in AI. To some degree and further developing this is still the case today.[3]

Not only as a field related to cognitive science and the study of the processes involving perception and motor control (i.e. control of muscles and movement) but also the experiments and findings from within the longer history of psychology, have been of influence in the areas of AI.

It is important to note that while there are links between the field of AI and psychology, some attributes in this area of study have been contested, opposed and surpassed by cognitive science and computer science, with its subfield of AI.

An example of a method that can be said to have found its roots in psychology is called “Transfer Learning”. This refers to a process or method learned within one area that is used to solve an issue in an entirely different set of conditions. For a machine the area and conditions are the data sets and how its artificial neural network model is being balanced (i.e. “weighted”). The machine uses a method acquired in working within one data set to work in another data set. In this way the data set does not have to be sufficiently large for the machine to return workable outputs.

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The AI method known as Reinforcement Learning is one that could be said to have some similarities with experiments such as those historically conducted by Pavlov and B.F. Skinner. With Pavlov the process of “Classical Conditioning” was introduced. This milestone in the field of psychology is most famously remembered with Pavlov’s dog that started to produce saliva the moment it heard a sound of a bell (i.e. the action which Pavlov desired to observe). This sound was initially associated with the offering of food; first the bell was introduced, then the food and then the dog would produce saliva. Pavlov showed that the dog indeed did link both the bell and the food. Eventually, the dog would produce saliva at the hearing of the bell without getting any food. What is important here is that the dog has no control over the production of saliva. That means the response was involuntary; it was automatic. This is, in an over-simplified explanation, Classical Conditioning.

That stated, Reinforcement Learning (RL) is a Machine Learning method, where the machine is confronted with degrees of “reward” or the lack thereof. See the section on RL for further details. Studies surrounding reward have been found in historical research conducted by a researcher named Skinner and others. It’s interesting to add that this research has been contested by Chomsky, questioning the scientific validity and transferability to human subjects.[4] Chomsky’s critique has been considered as important in the growth of the fields of cognitive science and AI, back then in the 1950s. In these experiments a process called “Operant Conditioning” was being tested. The researchers were exploring voluntary responses (as opposed to the involuntary ones seen with Pavlov). That is to say, these were responses that were believed to be under the control of the test subject and that would lead to some form of learning, following some form of reward.

Again, these descriptions are too simplistic. They are here to nudge you towards further and deeper exploration, if this angle were to excite you positively towards your learning about areas in the academic field of AI.



Linguistics

With Linguistics come the studies of semiotics. Semiotics could be superficially defined as the study of symbols and various systems for meaning-giving including and beyond the natural languages. One can think of visual languages, such as icons, architecture, or another form is music, etc. Arguably, each sense can have its own meaning-giving system. Some argue that Linguistics is a subfield of semiotics while again others turn that around. Linguistics also comes with semantics, grammatical structures (see: Professor Noam Chomsky and the Chomsky Hierarchy)[5], meaning-giving, knowledge representation and so on.

Linguistics and Computer Science both study the formal properties of language (formal, programming or natural languages). Therefor any field within Computer Science, such as Artificial Intelligence, share many concepts, terminologies and methods from the fields within Linguistics (e.g. grammar, syntax, semantics, and so on). The link between the two is studied via a theory known as the “automata theory”[6], the study of the mathematical properties of such automata. A Turing Machine is a famous example of such an abstract machine model or automaton. It is a machine that can take a given input by executing some rule, as expressed in a given language and that in a step by step manner; called an algorithm, to end up offering an output. Other “languages” that connects these are, for instance, Mathematics and Logic.

Did you know that the word “automaton” is from Ancient Greek and means something like “self-making”, “self-moving”, or “self-willed”? That sounds like some attributes of an idealized Artificial Intelligence application, no?

Mini
Project #___: What are automatons? 
What do you know you feel could be seen as an “automaton”? 
Can you find any automaton in your society’s history?

[1] Retrieved on January 12, 2020 from https://en.wiktionary.org/wiki/logic

[2] Skanski, S. (2018). Introduction to Deep Learning. From Logical Calculus to Artificial Intelligence. In Mackie, I. et al. Undergraduate Topics in Computer Science Series (UTiCS). Switzerland: Springer. p. v . Retrieved on March 26, 2020 from http://www.springer.com/series/7592  AND https://github.com/skansi/dl_book

[3] Crowder, J. A. et al. (2020). Artificial Psychology: Psychological Modeling and Testing of AI Systems. Springer

[4] Among other texts, Chomsky, N. (1959). Reviews: Verbal behavior by B. F. Skinner. Language. 35 (1): 26–58. A 1967 version retrieved on March 26, 2020 from https://chomsky.info/1967____/

[5] Chomsky, N. (1956). Three models for the description of language. IEEE Transactions on Information Theory, 2(3), 113–124. doi:10.1109/tit.1956.1056813 AND Fitch, W. T., & Friederici, A. D. (2012). Artificial grammar learning meets formal language theory: an overview. Philosophical Transactions of the Royal Society B: Biological Sciences, 367(1598), 1933–1955. doi:10.1098/rstb.2012.0103

[6] The automata theory is the study of abstract machines (e.g. “automata”, “automatons”; notice the link with the word “automation”). This study also considers how automata can be used in solving computational problems.

The Field of AI (Part 02-2): A “Pre-History” & a Foundational Context

URLs for A “Pre-History” & a Foundational Context:

  • This post is the main post on a Pre-History & a Foundational context of the Field of AI. In this post a narrative is constructed surrounding the “Pre-History”. It links with the following posts:
  • The post here is a first and very short linking with on Literature, Mythology & Arts as one of the foundational contexts of the Field of AI
  • The second part in the contextualization is the post touching on a few attributes from Philosophy, Psychology and Linguistics
  • Following, one can read about very few attributes picked up on from Control Theory as contextualizing to the Field of AI
  • Cognitive Science is the fourth field that is mapped with the Field of AI.
  • Mathematics & Statistics is in this writing the sixth area associated as a context to the Field of AI
  • Other fields contextualizing the Field of AI are being considered (e.g. Data Science & Statistics, Economy, Engineering fields)


My very rough and severely flawed mapping of some of the fields and applications associated with the Field of AI. (use, for instance, CRTL+ to zoom in)
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01 — The Field of AI: A Foundational Context: Literature, Mythology, Visual Arts

Figure 1 Talos or Talus, the artificial lifeform described in the Greek mythology. Here depicted with the mythological character of Medea or Medeia by Sybil Tawse image: public domain

 The early Greek Myths (about 2500 years ago) showcase stories of artificially intelligent bronze automatons or statues that were brought to life which then in turn exhibited degrees of “intelligence”. If you want to dig deeper search for Pygmalion’s Galateia, or look up the imaginary stories of Talos (Talus)[1].

China’s literary classics; for instance, Volume 5 “The Questions of Tang” of the Lièzǐ, perhaps unwittingly also explored the imagination of Artificial Intelligence. See, the example mentioned in the post on the Field f AI and a Pre-History.

The many thousands years old Jewish myth of the “golem” (גולם‎), fantasized about a creature made of clay that magically came to life. It could be interpreted as an imagination of the raw material for a controllable automaton and an artificial form of some degree of intelligence. While its cultural symbolism is far richer than given justice here, it could be imagined as symbolizing a collective human capability to envision giving some form and function of intelligence to materials that we, in general, do not tend to equate with comparable capability (i.e. raw materials for engineered design).

Golem (Prague Golem reproduction) photo: public domain

It is suggested in some sources[2] that artificial intelligence (in the literary packaging of imagined automatons or other) was also explored in European literary works such as in the 1816 German Der Sandmann (The Sandman) by Ernst Theodor Amadeus Hoffman,[3]  with the story’s character Olympia. The artificial is also explored by the fictional character Dr. Wagner, who creates Homunculus (a little man-like automaton), in Faust by Goethe,[4] and in Mary Shelley’s Frankenstein.[5] Much earlier yet, far less literary and rather philosophically, the artificial was suggested in the 1747 publication entitled L’Homme Machine (Man—Machine) by the French Julien Offray de la Mettrie, who posited the hypothesis that a human being as any other animal, are automatons or machines.

The next post will cover some hints of Philosophy in association with the Field of AI

Mini
Project #___ : Exploring the Pre-History of AI in your own and your larger
context.
Collect any other old stories from within China, Asia or elsewhere (from a location or culture that is not necessarily your own) that reference similar imaginations of “artificial intelligence” as constructed in the creative minds of our ancestors. 
Share your findings in a collection of references from the entire class. 
Maybe make a large collage that can be hung up on the wall, showing “artificial intelligence” from the past, through-out the ages.
Alternative: the teacher shares a few resources or references from the Arts (painting, sculpture, literature, mythology, etc.) that covered these topics and that are examples of the pre-history of AI.

[1] Parada, C. (Dec 10, 1993). Genealogical Guide to Greek Mythology. Studies in Mediterranean Archaeology, Vol 107. Coronet Books

[2] McCorduck, P. (2004). Machines Who Think: A Personal Inquiry into the History and Prospects of Artificial Intelligence. Natick: A K Peters, Ltd. p. xxv

[3]Hoffmann,  E.T.A. (1816). Der Sandmann. In Hoffmann (1817). Die Nachtstücke.  Retrieved on April 8, 2020 from https://germanstories.vcu.edu/hoffmann/sand_pics.html  translated here https://germanstories.vcu.edu/hoffmann/sand_e_pics.html additional information: http://self.gutenberg.org/articles/The_Sandman_(short_story) 

[4] Nielsen, W. C. (2016). Goethe, Faust, and Motherless Creations. Goethe Yearbook, 23(1), 59–75. North American Goethe Society.  Information retrieved on April 8, 2020 from https://muse.jhu.edu/article/619344/pdf

[5] An artistic interpretation of the link between the artificial life of the Frankenstein character and AI is explored here: http://frankenstein.ai/  Retrieved on April 8, 2020

The Field of AI (part 02): A “Pre-History” & a Foundational Context.

last update: Friday, April 24, 2020

URLs for A “Pre-History” & a Foundational Context:

  • This post is the main post on a Pre-History & a Foundational context of the Field of AI. In this post a narrative is constructed surrounding the “Pre-History”. It links with the following posts:
  • This post is a first and very short linking with on Literature, Mythology & Arts as one of the foundational contexts of the Field of AI
  • The second part in the contextualization is the post touching on a few attributes from Philosophy, Psychology and Linguistics
  • Following one can read about very few attributes picked up on from Control Theory as contextualizing to the Field of AI
  • Cognitive Science is the fourth field that is mapped with the Field of AI.
  • Mathematics & Statistics is in this writing the sixth area associated as a context to the Field of AI
  • Other fields contextualizing the Field of AI are being considered (e.g. Data Science & Statistics, Economy, Engineering fields)
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The Field of AI: A “Pre-History”.

A “pre-history” and a foundational context of Artificial Intelligence can arguably by traced back to a number of events in the past as well as to a number of academic fields of study. In this post only a few have been handpicked.

This post will offer a very short “pre-history” while following posts will dig into individual academic fields that are believed to offer the historical and present-day context for the field of AI.

It is not too far-fetched to link the roots of AI, as the present-day field of study, with the human imagination of artificial creatures referred to as “automatons” (or what could be understood as predecessors to more complex robots).

While it will become clear here that the imaginary idea of automatons in China is remarkably older, it has been often claimed that the historic development towards the field of AI, as it is intellectually nurtured today, commenced more than 2000 years ago in Greece, with Aristotle and his formulation of the human thought activity known as “Logic”.

Presently, with logic, math and data one could make a machine appear to have some degree of “intelligence”. Note, it is rational to realize that the perception of an appearance does not mean the machine is intelligent. What’s more, it could be refreshing to consider that not all intelligent activity is (intended to be seen as) logical.

It’s fun, yet important, to add that to some extent, initial studies into logic could asynchronously be found in China’s history with the work by Mòzǐ (墨子), who conducted his philosophical reflections a bit more than 2400 years ago. 

Coming back to the Ancient Greeks: besides their study of this mode of thinking, they also experimented with the creation of basic automatons.

Automatons (i.e. self-operating yet artificial mechanical creatures) were likewise envisioned in China and some basic forms were created in its long history of science and technology.[1] An early mentioning can be found in, Volume 5 “The Questions of Tang” (汤问; 卷第五 湯問篇) of the Lièzǐ (列子)[2], an important historical Daoist text.

In this work there is mentioning of this kind of (imagined) technologies or “scientific illusions”.[3] The king in this story became upset by the appearance of intelligence and needed to be reassured that the automaton was only that, a machine …

Figure 1 King of Zhōu, who reigned a little more than 2950 years ago ( 周穆王; Zhōu Mù Wáng ) , introduced by Yen Shi, is meeting an automaton (i.e. the figure depicted with straighter lines, on the top-left), as mentioned in the fictional book Lièzǐ. Image retrieved on March 5, 2020 from here
Figure 2 Liè Yǔkòu (列圄寇/列禦寇), aka the Daoist philosopher Lièzĭ (列子) who imagined an (artificial) humanoid automaton. This visual was painted with “ink and light colors on gold-flecked paper,” by Zhāng Lù (张路); during the Míng Dynasty (Míng cháo, 明朝; 1368–1644). Retrieved on January 12, 2020 from here ; image license: public domain.

Jumping forward to the year 1206, the Arabian inventor, Al-Jazari, supposedly designed the first programmable humanoid robot in the form of a boat, powered by water flow, and carrying four mechanical musicians. He wrote about it in his work entitled “The Book of Knowledge of Ingenious Mechanical Devices.

It is believed that Leonardo Da Vinci was strongly influenced by his work.[4] Al-Jazari additionally designed clocks with water or candles. Some of these clocks could be considered programmable in a most basic sense.

figure 3 Al-jazari’s mechanical musicians machine (1206). Photo Retrieved on March 4, 2020 from here; image: public domain

One could argue that the further advances of the clock (around the 15th and 16th century) with its gear mechanisms, that were used in the creation of automatons as well, were detrimental to the earliest foundations, moving us in the direction of where we are exploring AI and (robotic) automation or autonomous vehicles today.

Between the 16th and the 18th centuries, automatons became more and more common.  René Descartes, in 1637, considered thinking machines in his book entitled “Discourse on the Method of Reasoning“. In 1642, Pascal created the first mechanical digital calculating machine.

Figure 4 Rene Descartes; oil on canvas; painted by Frans Hals the Elder (1582 – 1666; A painter from Flanders, now northern Belgium, working in Haarlem, the Netherlands. This work: circa 1649-1700; photographed by André Hatala . File retrieved on January 14, 2020 from here. Image license: public Domain

Between 1801 and 1805 the first programmable machine was invented by Joseph-Marie Jacquard. He was strongly influenced by Jacques de Vaucanson with his work on automated looms and automata. Joseph-Marie’s loom was not even close to a computer as we know it today. It was a programmable loom with punched paper cards that automated the action of the textile making by the loom. What is important here was the system with cards (the punched card mechanism) that influenced the technique used to develop the first programmable computers.

Figure 5 Close-up view of the punch cards used by Jacquard loom on display at the Museum of Science and Industry in Manchester, England. This public domain photo was retrieved n March 12, 2020 from here; image: public domain

In the first half of the 1800s, the Belgian mathematician, Pierre François Verhulst discovered the logistic function (e.g. the sigmoid function),[1] which will turn out to be quintessential in the early-day developments of Artificial Neural Networks and specifically those called “perceptrons” with a threshold function, that is hence used to activate the output of a signal, and which operate in a more analog rather than digital manner, mimicking the biological brain’s neurons. It should be noted that present-day developments in this area do not only prefer the sigmoid function and might even prefer other activation functions instead.


[1] Bacaër, N. (2011). Verhulst and the logistic equation (1838). A Short History of Mathematical Population Dynamics. London: Springer. pp. 35–39.  Information retrieved from https://link.springer.com/chapter/10.1007%2F978-0-85729-115-8_6#citeas and from mathshistory.st-andrews.ac.uk/Biographies/Verhulst.html  

In 1936 Alan Turing proposed his Turing Machine. The Universal Turing Machine is accepted as the origin of the idea of a stored-program computer. This would later, in 1946, be used by John von Neumann for his “Electronic Computing Instrument“.[6] Around that same time the first general purpose computers started to be invented and designed. With these last events we could somewhat artificially and arbitrarily claim the departure from “pre-history” into the start of the (recent) history of AI.

figure 6 Alan Turing at the age of 16. Image Credit: PhotoColor [CC BY-SA (https://creativecommons.org/licenses/by-sa/4.0)] ; Image source Retrieved April 10, 2020 from here


As for fields of study that have laid some “pre-historical” foundations for AI research and development, which continue to be enriched by AI or that enrich the field of AI, there are arguably a number of them. A few will be explored in following posts. The first posts will touch on a few hints of Literature, Mythology and the Arts.


[1] Needham, J. (1991). Science and Civilisation in China: Volume 2, History of Scientific Thought. Cambridge, UK: Cambridge University.

[2] Liè Yǔkòu (列圄寇 / 列禦寇). (5th Century BCE). 列子 (Lièzǐ). Retrieved on March 5, 2020 from https://www.gutenberg.org/cache/epub/7341/pg7341-images.html  and 卷第五 湯問篇 from https://chinesenotes.com/liezi/liezi005.html   and an English translation (not the latest) from  https://archive.org/details/taoistteachings00liehuoft/page/n6/mode/2up  

[3] Zhāng, Z. (张 朝 阳).  ( November 2005). “Allegories in ‘The Book of Master Liè’ and the Ancient Robots”. Online: Journal of Heilongjiang College of Education. Vol.24 #6. Retrieved March 5, 2020 from https://wenku.baidu.com/view/b178f219f18583d049645952.html

[4] McKenna, A. (September 26, 2013). Al-Jazarī Arab inventor. In The Editors of Encyclopaedia Britannica. Online: Encyclopaedia Britannica Retrieved on March 25, 2020 from https://www.britannica.com/biography/al-Jazari AND:

Al-Jazarī, Ismail al-Razzāz; Translated & annotated by Donald R. Hill. (1206). The Book of Knowledge of Ingenious Mechanical Devices. Dordrecht, The Netherlands: D. Reidel Publishing Company. Online Retrieved on March 25, 2020 from https://archive.org/details/TheBookOfKnowledgeOfIngeniousMechanicalDevices/mode/2up

[5] Bacaër, N. (2011). Verhulst and the logistic equation (1838). A Short History of Mathematical Population Dynamics. London: Springer. pp. 35–39.  Information retrieved from https://link.springer.com/chapter/10.1007%2F978-0-85729-115-8_6#citeas and from mathshistory.st-andrews.ac.uk/Biographies/Verhulst.html

[6] Davis, M. (2018). The Universal Computer: the road from Leibniz to Turing. Boca Raton, FL: CRC Press, Taylor & Francis Group

The Field of AI (part 01): Context, Learning & Evolution

One could state that Artificial Intelligence (AI) methods enable the finding of and interaction with patterns in the information available from contexts to an event, object or fact. These can be shaped into data points and sets. Many of these sets are tremendously large data sets. So large are these pools of data, so interconnected and so changing that it is not possible for any human to see the patterns that are actually there or that are meaningful, or that can actually be projected to anticipate the actuality of an imagined upcoming event.

While not promising that technologies coming out from the field of AI are the only answer, nor the answer to everything, one could know their existence and perhaps apply some of the methods used in creating them. One could, furthermore, use aspects from within the field of AI to learn about a number of topics, even about the processes of learning itself, about how to find unbiased or biased patterns in the information presented to us. Studying some basics about this field could offer yet another angle of meaning-giving in the world around and within us.  What is a pattern, if not an artificial promise to offer some form of meaning?

It’s not too far-fetched to state that the study of Artificial Intelligence is partly the study of cognitive systems[1] as well as the context within which these (could) operate. While considering AI[2], one might want to shortly consider “context.”

Here “context” is the set of conditions and circumstances preceding, surrounding or following a cognitive system and that related to its processed, experienced, imagined or anticipated events. One might want to weigh how crucial conditions and circumstances are or could be to both machine and human.[3]  The field of AI is one of the fields of study that could perhaps offer one such opportunity.

A context is a source for a cognitive system to collect its (hopefully relevant) information, or at least, its data from. Cognitive Computing (CC) systems are said to be those systems that try to simulate the human thought processes, to solve problems, via computerized models.[4] It is understandable that some classify this as a subset of Computer Science while some will obviously classify CC as a (sometimes business-oriented) subset of the field of AI.[5] Others might link this closer to the academic work done in Cognitive Science. Whether biological or artificial, to a number of researchers the brain-like potentials are their core concern.[6]

As can be seen in a few of the definitions and as argued by some experts, the broad field of AI technologies do not necessarily have to mimic *human* thought processes or human intelligence alone. As such, AI methods might solve a problem in a different way from how a human might do it.

However similar or different, the meaning-giving information, gotten from a context, is important to both an AI solution as well as to a biological brain. One might wonder that it is their main reason for being: finding and offering meaning.

The contextual information an AI system collects could be (defined by or categorized as) time, locations, user profiles, rules, regulations, tasks, aims, sensory input, various other big to extremely huge data sets and the relationships between each of these data sets in terms of influencing or conflicting with one another. All of these sources for data are simultaneously creating increasing complexities, due to real-time changes (i.e. due to ambiguity, uncertainty, and shifts). AI technologies offer insights through their outputs of the *best* solution, rather than the one and only certain solution for a situation, in a context at a moment in spacetime.

The wish to understand and control “intelligence” has attracted humans for a long time. It is then reasonable to think that it will attract our species’ creative and innovative minds for a long time to come. It is in our nature to wonder, in general, and to wonder about intelligence and wisdom in specific; whatever their possible interlocked or independent definitions might be(come) and whichever their technological answers might be.

In considering this, one might want to be reminded that the scientific name of our species itself is a bit of a give-away of this (idealized) intention or aspiration: “Homo Sapiens.” This is the scientific name of our animal species. Somewhat loosely translated, it could be understood to mean: “Person of Wisdom”. 

In the midst of some experts who think that presently our intelligence is larger than our wisdom, others feel that, if handled with care, consideration and contextualization, AI research and developments just might positively answer such claim or promise and might at least augment our human desires towards becoming wiser.[7] Just perhaps, some claim,[8] it might take us above and beyond[9] being Homo Sapiens.[10]

For now, we are humans exploring learning with and by machines in support of our daily yet global needs.

For you and I, the steps to such aim need to be practical. The resources to take the steps need to be graspable here and now.

At the foundation, to evaluate the validity or use of such claims, we need to understand a bit what we are dealing with. Besides the need for the nurturing of a number of dimensions in our human development, we might want to nurture our Technological Literacy (or “Technology Literacy”).[11]

A number of educators[12] seem to agree that,[13] while considering human experiences and their environments, this area of literacy is not too bad a place to start off with.[14] In doing so, we could specifically unveil a few points of insight associated with Artificial Intelligence; that human-made technological exploration of ambiguous intelligence.

Few people know that heart comes http://appalachianmagazine.com/2016/12/25/why-stink-bugs-are-taking-over-the-eastern-united-states/ online prescription for viagra under pressure, when stress control of the mind. The uses of alcohol, smoking, tobacco, and http://appalachianmagazine.com/2019/03/10/mountain-tradition-eating-ramps-in-springtime/ super generic viagra illegal drugs have great influence of carrying this sexual complication. You on line viagra can also get discount on bulk order for this product. While viagra lowest prices some states don’t need that this online drug is not good as their branded counterparts are.




[1] Sun F., Liu, H., Hu, D.  (eds). (2019). Cognitive Systems and Signal Processing: 4th International Conference, ICCSIP 2018, Beijing, China, November 29 – December 1, 2018, Revised Selected Papers, Part 1 & Part 2. Singapore: Springer

[2] DeAngelis, S. F. (April 2014). Will 2014 be the Year you Fall in Love with Cognitive Computing? Online: WIRED. Retrieved November 22, 2019 from https://www.wired.com/insights/2014/04/will-2014-year-fall-love-cognitive-computing/

[3] Desouza, K. (October 13, 2016). How can cognitive computing improve public services? Online Brookings Institute’s Techtank Retrieved November 22, 2019 from https://www.brookings.edu/blog/techtank/2016/10/13/how-can-cognitive-computing-improve-public-services/

[4] Gokani, J. (2017). Cognitive Computing: Augmenting Human Intelligence. Online: Stanford University; Stanford Management Science and Engineering; MS&E 238 Blog. Retrieved November 22, 2019 from https://www.datarobot.com/wiki/cognitive-computing/

[5] https://www.datarobot.com/wiki/cognitive-computing/

[6] One example is: Poo, Mu-ming. (November 2, 2016). China Brain Project: Basic Neuroscience, Brain Diseases, and Brain-Inspired Computing. Neuron 92, NeuroView, pp. 591-596.  Online: Elsevier Inc. Retrieved on February 25, 2020 from https://www.cell.com/neuron/pdf/S0896-6273(16)30800-5.pdf  . Another example is: The work engaged at China’s Research Center for Brain-Inspired Intelligence (RCBII), by the teams led by Dr XU, Bo and Dr. ZENG, Yi. Founded in April 2015, at the CAS’ Institute of Automation, the center contains 4 research teams: 1. The Cognitive Brain Modeling Group (aka Brain-Inspired Cognitive Computation); 2. The Brain-Inspired Information Processing Group; 3. The Neuro-robotics Group (aka Brain-Inspired Robotics and Interaction) and 4. Micro-Scale Brain Structure Reconstruction. Find some references here: bii.ia.ac.cn

[7] Harari, Y. N. (2015). Sapiens. A Brief History of Humankind. New York: HarperCollings Publisher

[8] Gillings, M. R., et al. (2016). Information in the Biosphere: Biological and Digital Worlds. Online: University California, Davis (UCD). Retrieved on March 25, 2020 from https://escholarship.org/uc/item/38f4b791

[9] (01 June 2008). Tech Luminaries Address Singularity. Online: Institute of Electrical and Electronics Engineers (IEEE Spectrum). Retrieved on March 25, 2020 from  https://spectrum.ieee.org/static/singularity

[10] Maynard Smith, J. et al. (1995). The Major Transitions in Evolution. Oxford, England: Oxford University Press  AND Calcott, B., et al. (2011). The Major Transitions in Evolution Revisited. The Vienna Series in Theoretical Biology. Boston, MA: The MIT Press.

[11]  National Academy of Engineering and National Research Council. (2002). Technically Speaking: Why All Americans Need to Know More About Technology. Washington, DC: The National Academies Press   Online: NAP Retrieved on March 25, 2020 from https://www.nap.edu/read/10250/chapter/3

[12] Search, for instance, the search string “Technological Literacy” through this online platform: The Education Resources Information Center (ERIC), USA https://eric.ed.gov/?q=Technological+Literacy

[13] Dugger, W. E. Jr. et al (2003). Advancing Excellence in Technology Literacy. In Phi Delta Kappan, v85 n4 p316-20 Dec 2003 Retrieved on March 25, 2020 from https://eric.ed.gov/?q=Technology+LIteracy&ff1=subTechnological+Literacy&ff2=autDugger%2c+William+E.%2c+Jr.&pg=2

[14] Cydis, S. (2015). Authentic Instruction and Technology Literacy. In Journal of Learning Design 2015 Vol. 8 No.1 pp. 68 – 78. Online: Institute of Education Science (IES) & The Education Resources Information Center (ERIC), USA. Retrieved on March 25, 2020 from https://files.eric.ed.gov/fulltext/EJ1060125.pdf


IMAGE CREDITS:

An example artificial neural network with a hidden layer.

en:User:Cburnett / CC BY-SA (http://creativecommons.org/licenses/by-sa/3.0/) Retrieved on March 12, 2020 from https://upload.wikimedia.org/wikipedia/commons/e/e4/Artificial_neural_network.svg


The Field of AI (Part 07): a bibliography with URLs

compared to the previous posts this post is very rough and messy. When time permits I will clean it up.


Here below are a few lists associated with my personal learning about the academic field of AI and its related fields.

I am not an expert in this field; rather the contrary. I am interested in considering questions related with bringing technology literacy into the thinking of educators and learners within the K-12 realm. The resources below and elsewhere here in this blog are mainly catered to high school (or those beyond). If some resources seem too advanced, they were added to show where one could aim to learn toward or where one could end up if one continued studies in this area. Therefore, some resources are technical while others are not.

This post includes a name list. It is a list of what I understand to be leading voices in the field. Secondly, there is a bibliography of works I found online or offline.

I superficially or more profoundly browsed these , in search of a better understanding and contextualization (in a historical and trans-disciplinary setting).

Where found and available URLs are offered. Some additional or the same URLs or references can be found in other posts (see the one on mathematics and the field of AI, to name but one).

Lastly, a list of URLs to data sets is included at the end of this post.

An Incomplete List of Leading Voices

As a young learner on your educational path and as a young participant in your community you might like to find some references that can give you an idea or that can ignite your imagination of how and where and with whom to walk your path towards growing into tomorrow’s AI expert.

We learn on our own but better even by the guidance of others and by observing and learning from what they have done or are doing.

Here below is a list of historical figures and present-day scholars. The list is surely not complete and needs continued updating. The list does not imply a preference imposed by the author. It tries to highlight a few scholars from around the world, scholars from within China and scholars that are in pure academic research as well as in innovation and entrepreneurial areas. More scholars and innovators, involved in important work in the field of AI, are missing than those listed. It also is incomplete as to what all the work is that these experts have been involved in up till now. The list does however give you a spark, a hint and points you in directions you can further explore by means of your own research and study.

Maybe you can add a few names to this list. Perhaps one day your work will be a beacon as well for another young learner.

Following The Master Part 1: Some Historical, Foundational key-Figures or Technological Pioneers in the Earliest Development of the field of AI.

·         BOOLE, George (1815 – 1864)
·         Dr. CHOMSKY, Noam (1928 – )
·         SHANNON, Claude
·         Dr. FEIGENBAUM, Edward (1936 –     )
·         Dr. FREGE, Gottlob (1848 – 1925)
·         Dr. GÖDEL, Kurt (1906 – 1978)
  • Mathematician and one of the most important logisticians.
    • His work lies at the mathematical and logical foundation of, for instance, Turing’s work.
·         Dr. GOOD, Irving John (1916 – 2009)
    • [2] on “intelligence explosion,”[3] that are claimed to have led to today’s hypothetical concept of the “technological singularity”.[4] Similar to this present-day hypothesis, Dr. Good envisioned a potential future creation, in the likes of what we now call the future-existence of an Artificial General Intelligence agent, (AGI), that would be able to solve human concerns and that would far outweigh human (intellectual) ability. He felt it stood to reason that it would be the last invention humans had to make.[5]
·         Dr. HOLLAND, John Henry (1929 – 2015)
  • 1929-2015
    • While suggested by Turing[6], he pioneered Genetic Algorithms with other scientists such as Dr. GOLDBERG, David Edward.
·         Dr. Licklider, J. C. R. (1915 – 1990)
·         Dr. McCARTHY, John (1927 – 2011)
  • Inventor of the LISP programming language, used in the early research and development of AI systems
    • Co-founder of the academic field of Artificial Intelligence
    • Invented the term “Artificial Intelligence”
·         Dr. MINSKY, Marvin (1927 – 2016)
  • Co-founder of The MIT Artificial Intelligence Lab
    • Leading voice on and pioneer in Artificial Intelligence
    • Built the first neural network learning machine in 1951
·         Dr. NEWELL, Allen (1927 – 1992)
·         Dr. PAPERT, Seymour (1928 – 2016)
·         Dr. ROBINSON, John Alan
·         ROCHESTER, Nathaniel
·         Dr. SAMUEL, Arthur (1901 – 1990)
  • A pioneer in computer gaming and AI
    • He put the term and the research surrounding “Machine Learning” on the map in the 1950s and with his paper: “Some Studies in Machine Learning Using the Game of Checkers“. IBM Journal of Research and Development. 44: 206–226
  • ·         STRACHERY, Christopher
·         Dr. TURING, Alan (1912 – 1954)
  • By many referred to as the father of Artificial Intelligence.
    • Created fundamental theories of Computation and in Computer Science; e.g. the idea of the binary digital language of ones and zeroes, the (theoretical) Turing Machines
    • Created the Turing Test allowing to see whether or not a machine showcased intelligent behavior[8]
    • Created the first electronic computer
·         Dr. von NEUMANN, John (1903 – 1957)
  • [blablabla]
    • Most computers, as we know them today, are based on his conceptualizations.
  • Dr. WÁNG Hào (王浩)(1921 – 1995)
    • Tsinghua University graduate
    • Mathematician, philosopher and logistician.
    • Proved hundreds of mathematical theories with a computer program written in 1959
    • Inventor of the Wang Tiles; proved that any Turing Machine can be turned into Wang Tiles.
    • Inventor of a number of computational models.
  • Dr. ZADEH, Lotfi Aliasker (1921 – 2017)
    • AI researcher, mathematician, computer scientist
    • Inventor[9] of Fuzzy Mathematics, Fuzzy Algorithms, Fuzzy Sets, Fuzzy Logic and so on.  Over-simplified, Fuzzy logic is a generalization of Boolean logic and a form of many-value logic, with values in-between 0 and 1 (whereas traditionally, logic operates with values that are either on or off; one or zero; right or wrong).
Mini Project #___ : Inspiration by Following the Old Masters
  • Which of these figures or their work are you most inspired by? Why?
  • Can you find some other historical figures associated with research & developments (R&D) in AI whom you are inspired by?

Following The Master Part 2: Some Present-day Leading Figures in the field of AI (in alphabetic order) with attention to Chinese Scholars

The following is an incomplete list composed as of January 2020. Please note, more experts or leading voices are mentioned across the text chapters (e.g. see footnotes and references; see section 05 of this text). The author apologizes to any expert or leading voice that might not yet be represented or that might be inaccurately represented here. Pease contact the author so that refinements can be added. The aim is to give young learners some sort of direction, motivation, hints and passion for the field of AI. Thank you for your support:

  • ·         Dr. BENGIO, Yoshua:  Research into Artificial Neural Networks, Unsupervised Machine Learning and Deep Learning
  • ·         Dr. BLEI, David M.: research in Machine Learning, Statistical Models (e.g. Topic Modeling), algorithms, and related topics.
  • ·         Dr. BOSTROM, Nick: Research in ethics surrounding Artificial Superintelligence.
  • ·         Dr. BREASEAL, Cynthia: Research in Human-Robot Interaction.
  • ·         Dr. BRYSON, Joanna: Research in AI ethics and in AI systems helping to understand biological intelligence
  • ·         Dr. Chén Dānqí 陈丹琦: a Tsinghua & Stanford Universities graduate. Assistant Professor at Princeton University. Main field of research in Natural Language Processing (NLP).
  • Graduate from and Professor at the Institute of Computing Technology, Chinese Academy of Sciences. Selected by MIT Technology Review as one of the 2015 top 35 innovators under 35 years old. Research and developments in large-scale Machine Learning solutions, Deep Learning, reduction of energy requirements or computational costs, brain-inspired processor chips, and related topics.
  • ·         Dr. DUAN Weiwen: AI Director of the Department of Philosophy of Science and Technology, The Institute of Philosophy, The Chinese Academy of Social Sciences (CASS). He specializes, among others, in ignorance in sciences, philosophy of IT, Big Data issues, and Artificial Intelligence. Dr. Duan is the deputy chairman of the Committee of Big Data Experts of China. His research is supported by the National Social Sciences Fund of China (NSSFC).
  • Research and developments in Emotional AI, subtle expression recognition, facial recognition.  Entrepreneur in related AI developments.
  • ·         Dr. ERKAN, Ayse Naz: Research in Content Understanding & Applied Deep Learning.
  • ·         Dr. FREUND, Yoav: Research and advances in algorithm design, Machine Learning and probability theory.
  • ·         Dr. FUNG, Pascale馮雁: leading researcher in Natural Language Processing.
  • Research on Human-centered AI, autonomous vehicles, Deep Learning, robotics
  • Research on algorithm design, Bayesian Machine Learning, Computational Neuroscience, Bioinformatics, Statistics and other areas.
  • ·         Dr. GOERTZEL, Ben Research on and developments in AGI and robotics.
  • Research and developments in Machine Learning and Deep Learning
  • Neuroscientist. Research and developments in Artificial General Intelligence (AGI), Machine Learning (AlphaGo) and related topics.
  • ·         Dr. HINTON, Geoffrey E:  Leading AI academic, computer scientist and cognitive psychologist with a focus on artificial neural networks. The great-great-grandson of the logician George Boole ( who’s work on, among others, algorithms for logic deduction, is still of computational importance). Dr. Hinton is considered one of the most prominent pioneers in Deep Learning.
  • ·         Dr. HUTTER, Marcus. researching the mathematical foundations of AI and Reinforcement Learning; leading authority on theoretical models of super intelligent machines.
  • Trained Dr. Ng and other leading scholars in the field of AI. Research in Machine Learning, recurrent neural networks, Bayesian networks in Machine Learning and other links between Machine Learning and statistics
  • ·         Dr. KARPATHY, Andrej: Research on Deep Learning in Computer Vision, Generative Modeling, Reinforcement Learning, Convolutional Neural Networks, Recurrent Neural Networks, Natural Language Processing
  • Research on Artificial Intelligence (e.g. Learning platforms for humans; Content recommendation, etc.)1
  • ·         Dr. KURZWEIL, Ray: a legendary authority on AI and thinker on the technological singularity
  • ·         Dr. LAFFERTY, John D.: Research in Language and graphic models, semi supervised learning, information retrieval, speech recognition.
  • ·         Dr. LECUN, Yann: Research in computational neuroscience, Machine Learning, mobile robotics, and computer vision. Developed the ‘Convolutional Neural Networks’ (a model of image recognition mimicking biological processes)
  • ·         Dr. LI Fei-fei: AI scientist & Machine Learning expert with a focus on computational neuroscience, image / visual recognition and Big Data. Pushed the collection and creation of large quality datasets and this towards the improvement of algorithm design. The result was ImageNet, containing more than 10million hierarchically organized images.
  • ·         Dr. LI Kāifù: research on Machine Learning and pattern recognition. The world’s first speaker-independent, continuous speech recognition system; investor in mainly China’s AI R&D; Chairman of the World Economic Forum’s Global AI Council; author on AI and a leading force in supporting the training of AI-related engineers in China.
  • ·         Dr. LI, Sheng李生 : leading research on Natural Language Processing (NLP) and one of China’s pioneers in this field. Graduate from and professor at the Harbin Institute of Technology (HIT). President of Chinese Information Processing Society of China (CIPSC).
  • Former President of Beihang University and Professor of Computer Science at the Beihang University. Co-lead China’s National Engineering Laboratory of Deep Learning. Research in AI and network computing.
  • ·         Dr. LIM, Angelica: robotic development & human-styled learning
  • ·         Dr. LIN Dekang: A Tsinghua University graduate. Senior research scientist in Machine Learning, Natural Language Processing and more at a major AI lab.
  • ·         Dr. LIN Yuanqing: A Tsinghua University graduate. Research and developments in AI, Big Data, Deep Learning,
  • ·         Dr. LIU, Ting (刘挺): research and development in the area of Natural Language Processing.
  • Fudan University graduate. Leading AI researcher and developer with a focus on autonomous driving and other aspects in the field of AI. Leadership in related industry.
  • ·         Dr. MARCUS, Gary: Research on natural and artificial intelligence in areas of psychology, genetics and neuroscience.
  • ·         Dr. McCALLUM, Andrew: Research in Machine Learning (i.e. Semi Supervised Learning, natural language processing, information extraction, information integration, and social network analysis)
  • ·         Dr. MIN Wanli: A University of Science & Technology of China graduate. Research and developments in AI applications, traffic pattern recognition, Machine Learning and related aspects.
  • AI researcher, famous AI educator, worked on autonomous helicopters, Artificial Intelligence for robots and created the Robot Operating System (ROS). Research in Machine Learning (Reinforcement Learning, Supervised Learning, …). IS also well-known for his online course material.[10]
  • ·         Dr. Oliphant, Travis: Scientific Computing developer. Created NumPy, SciPy and Numba. Founded Anaconda and more
  • Data Scientist. Research in Big Data, Data Mining and Machine Learning. Editor of KDnugget (a source for Data Science and Machine Learning).
  • Research in AI in self-driving vehicles
  • ·         Dr. RUS, Daniela L.: research in self-reconfiguring distributed and collaborative robots (e.g. autonomous swarms), autonomous environment-adaptable shape-shifting machines (this is of use where conditions cannot be foreseen and therefore cannot be hard-coded)
  • ·         Dr. RUSSELL, Stuart J.: author of the most cited book (together with Dr. NORVIG, Peter) on AI which is also used in about 1300 universities, across about 116 countries as AI course material. He did research on inductive and analogical reasoning. He founded the Center for Human-Compatible Artificial Intelligence
  • ·         Dr. SCHMIDHUBER, Jurgen: AI scientist with a focus on and self-improving AI and (recurrent) neural networks, used for speech recognition. He works on AI for finance and autonomous vehicles.
  • ·         Dr. SCHöLKOPF, Bernhard: Research in Machine Learning, Brain-computer interfaces, and other related areas,
  • ·         Dr. SHAPIRE, Robert: Research and Developments in Machine Learning, Decision Trees, Game Theory.
  • ·         Dr. SHEN Xiangyang; Industry leader in Research and Development in the field of Artificial Intelligence.
  • AI scientist with a focus on learning. One of the creators behind the AI method known as modern Computational Reinforcement Learning.
  • ·         Dr. SWEENEY, Latanya: Research in the area of biases in Machine Learning algorithms
  • ·         Dr. TANG Xiaoou: Research in computer vision, pattern recognition, and video processing. A leading entrepreneur.
  • ·         Dr. TEGMARK, Max: Investigates existential risk from advanced artificial intelligence
  • ·         Dr. WHYE, Teh Yee: Research in Machine Learning (Deep Learning), Statistical Machine Learning and Face Recognition.
  • ·         Dr. THRUN, Sebastian: Research in Machine Learning, autonomous vehicles, probabilistic algorithms, robotic mapping.
  • ·         Dr. VALIANT, Leslie: research and advances in computational theory, complexity theory, algorithms and machine learning.
  • ·         Dr. VAPNIK, Vladimir: Research in the area of Machine Learning and Statistical Learning. Co-invented the Support-Vector Machine Method
  • Research in the area of Machine Learning, Deep Learning and Reinforcement Learning
  • 王海峰: a Harbin Institute of Technology graduate. Leadership in AI developments with foci on Deep Learning, Big Data, computer vision, Natural Language Processing (NLP), machine translation, speech recognition, personalized recommendations, and so on.
  • ·         Dr. WU Hua: A graduate from the Chinese Academy of Sciences. Cutting-edge breakthroughs in Conversational AI & Natural Language Processing (NLP), dialog systems, Neural Machine Translation and related topics.
  • ·         Dr. XU Wei: A Tsinghua University graduate. Received the title of “Distinguished Scientist”. Research and developments in areas of Deep Learning, image classification, autonomous vehicles, translation processes, and so on,
  • ·         Dr. YANG Yiming: Research in Machine Learning
  • ·         Dr. YE Jieping: A Fudan University graduate. Research and developments in Big Data, Data Mining, Machine Learning, autonomous vehicles, and so on.
  • ·         Dr. YU Dong: A Zhejiang University graduate. Research and developments in Speech recognition, Natural Language Processes, natural language understanding, and related topics.
  • ·         Dr. YU Kai: a Nanjing University graduate. Research and developments in Deep Learning, pervasive AI hardware systems, facial recognition, automatic ordering, driver-assistant systems, and related areas.
  • ·         Dr. ZADEH, Reza: Research on Discrete Applied Mathematics, AI, Machine Learning
  • Research on technical models for Brain-inspired AI, AI Ethics and Governance. Professor and Deputy Director at Research Center for Brain-inspired Intelligence (RCBII), Institute of Automation, Chinese Academy of Sciences. He is Director for the Research Center on AI Ethics and Governance, Beijing Academy of Artificial Intelligence. Dr. Zeng is a board member for the National Governance Committee for the New Generation Artificial Intelligence, Ministry of Science and Technology China.
  • A Hefei University of Technology graduate. Professor of Machine Learning at the Peking University (aka Beida; 北京大学, PKU). Former Vice Dean of the School of EECS. Research in Machine Perception, computer vision and other related areas.
  • ·         Dr. ZHANG Bo: Co-leads China’s National Engineering Laboratory of Deep Learning. A member of the member of the Chinese Academy of Sciences. A graduate from and Professor at Tsinghua University. Research in Machine Learning, neural networks, task and motion planning, pattern recognition, image retrieval and classification, and other areas.
  • ·         Dr. ZHANG, Min张民: research and development in the area of Natural Language Processing at the Soochow University (in Sūzhōu, Jiāngsū Province, P.R. China; Sūzhōu Dàxué, 苏州大学).
  • 张潼). Research focus on Machine Learning algorithms and theory, statistical methods for big data and their applications, computer vision, speech recognition, Natural Language Processing, and so on.
  • ·         Dr ZHAO, Tiejun (赵铁军): research and development in the area of Natural Language Processing.
  • Graduated from 3 Chinese universities: Northeastern University, Beihang University and the Chinese Academy of Sciences, Institute of Automation. Conducts research on Machine Learning and Explainable AI at one of the front-running labs in AI development.
  • ·         Dr. ZHOU Jingren: A graduate from the University of Science and Technology of China. Research and Developments in AI, Big Data, large scale Machine Learning, Speech and Language Processing, image & video processing, and so on.
  • ·         Dr. ZHOU, Ming: cutting edge research and development in the area of Natural Language Processing.
  • Doctor of Science at the Chinese Academy of Sciences. Research and Developments in ChatBots, conversational interfaces, and related areas.
Mini Project #___: Inspiration from Following Today’s Masters
  • Which of these figures or their work are you most inspired by? Why?
  • Can you find some more details and up-to-date information about your chosen role model?
  • Can you find some other leading figures you are inspired by that are also working in the field of AI and that are not (yet) in this list?
  • Can you figure out how your choice of leading figures relates to AI and to other researchers by creating an Entity-Relationship Model (see example here)?

[1] Retrieved on March 27, 2020 from https://library.stanford.edu/collections/edward-feigenbaum-papers

[2] Good, I.J. (1965). Speculations Concerning the First Ultraintelligent Machine. in F. L. Alt and M. Rubinoff (eds.). (1966). Advances in Computers Vol.6: pp. 31–88.

[3] Bostrom. N. (2014). Superintelligence: Paths, Dangers, Strategies. Oxford: Oxford University Press

[4] Shanahan, M. (2015). The Technological Singularity. The MIT Essential Knowledge Series. Cambridge, MA: The MIT Press.

[5] Good, I.J. (1965). p.33

[6] Turing, A. M. (October, 1950). “Computing Machinery and Intelligence” in Mind Lix(236), 49:433-460. pp.459-460

[7] Robinson, John Alan (January 1965). A Machine-Oriented Logic Based on the Resolution Principle. J. ACM. 12 (1): 23–41 Retrieved on March 24, 2020 from https://web.stanford.edu/class/linguist289/robinson65.pdf

[8] Turing, A. (1948). Intelligent Machinery. http://www.turingarchive.org/viewer/?id=127&title=1 and https://weightagnostic.github.io/papers/turing1948.pdf see: Copeland, J. (2004). The Essential Turing. Oxford: Clarendon Press. pp. 411-432

[9] Zadeh, L. A. (1965). Fuzzy Sets. Information and Control, 8(3),pp. 338–353. Online: Elsevier Inc. ScienceDirect; Retrieved on March 18, 2020 from https://www.sciencedirect.com/journal/information-and-control/vol/8/issue/3

[10] An example of Dr. Ng’s online course material: https://www.coursera.org/learn/machine-learning

A List of Leading Academic Voices, Bibliography, References, Examples & URLs

AI Magazine. Online: Association for the Advancement of Artificial Intelligence. Retrieved on April 21, 2020 from:

Algebra basics and beyond can be studied via these resources retrieved on March 31, 2020 from https://www.ck12.org/fbbrowse/list?Grade=All%20Grades&Language=All%20Languages&Subject=Algebra

Al-Jazarī, Ismail al-Razzāz; Translated & annotated by Donald R. Hill. (1206). The Book of Knowledge of Ingenious Mechanical Devices. Dordrecht, The Netherlands: D. Reidel Publishing Company. Online Retrieved on March 25, 2020 from https://archive.org/details/TheBookOfKnowledgeOfIngeniousMechanicalDevices/mode/2up

Alpaydin, E. (2020). Introduction to Machine Learning. The MIT Press Essential Knowledge Series. Cambridge, MA: MIT Press. Retrieved an introduction on March 25, 2020 from https://mitpress.mit.edu/contributors/ethem-alpaydin Lecture notes to the 2014 print retrieved from https://www.cmpe.boun.edu.tr/~ethem/i2ml3e/

Angwin, J., et al. (2016). Machine Bias. There’s software used across the country to predict future criminals. And it’s biased against blacks. In Pro Publica Retrieved on July 23rd, 2019 from https://www.propublica.org/article/machine-bias-risk-assessments-in-criminal-sentencing

Anthony, S. (March 14, 2017). DeepMind in talks with the National Grid to reduce UK energy use by 10%. Online: ars technica. Retrieved February 14, 2020 from https://arstechnica.com/information-technology/2017/03/deepmind-national-grid-machine-learning/

Bacaër, N. (2011). Verhulst and the logistic equation (1838). A Short History of Mathematical Population Dynamics. London: Springer. pp. 35–39.  Information retrieved from https://link.springer.com/chapter/10.1007%2F978-0-85729-115-8_6#citeas

Barat, J. (2013). Our Final Invention: Artificial Intelligence and the End of the Human Era.  New York: Thomas Dunne Books

Baum, S. (2017). A Survey of Artificial General Intelligence Projects for Ethics, Risk and Policy. The Global Catastrophic Risk Institute Working Paper 17-1. Onine: The Global Catastrophic Risk Institute. Retrieved on February 25, 2020 from https://papers.ssrn.com/sol3/papers.cfm?abstract_id=3070741

Bayes, T. (1763). An Essay towards solving a Problem in the Doctrine of Chances.  Retrieved on March 13, 2020 from the University of California, Irvine, School of Social Sciences at https://www.socsci.uci.edu/~bskyrms/bio/readings/bayes_essay.pdf  and with some additional annotations from MIT OPenCourseWare at https://ocw.mit.edu/courses/literature/21l-017-the-art-of-the-probable-literature-and-probability-spring-2008/readings/bayes_notes.pdf

BBC Bitesize. What is an algorithm? Retrieved on February 12, 2020 from https://www.bbc.co.uk/bitesize/topics/z3tbwmn/articles/z3whpv4

Bieda, L. (2009). Making Sense and Nonsense of Markov Chains. Online, retrieved on March 31, 2020 from https://rarlindseysmash.com/posts/2009-11-21-making-sense-and-nonsense-of-markov-chains  AND https://gist.github.com/LindseyB/3928224 

Berke, J.D. (2018).What does dopamine mean? Online: Nature Neuroscience 21, 787–793. Retrieved on March 27, 2020 from https://www.nature.com/articles/s41593-018-0152-y#citeas  

Berridge, K. C. et al (1998). What is the Role of Dopamine in Reward: Hedonic Impact, Reward Learning or Incentive Salience? In Brain Research Reviews 28 (1998) 309-369. Elsevier

Bermúdez, J. L., (2014). Cognitive Science: An Introduction to the Science of the Mind. Cambridge: Cambridge University Press. Retrieved on March 23, 2020 from https://www.cambridge.org/us/academic/textbooks/cognitivescience 

Bird, S. et al. (2010). Natural Language Processing with Python — Analyzing Text with the Natural Language Toolkit. Retrieved on April 29, 2020 from https://www.nltk.org/book/ AND https://www.nltk.org/book_1ed/ AND https://www.nltk.org/nltk_data/

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Sarkar, D. (2019). Text Analytics with Python. A Practitioner’s Guide to Natural Language Processing. Bangalore: Apress.

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Statistics basics and beyond can be studied via these resources retrieved on March 31, 2020 from https://www.ck12.org/fbbrowse/list?Grade=All%20Grades&Language=All%20Languages&Subject=Statistics

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Additionally, an incomplete list of online data sets:

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Data sets

Data set location area
http://cricsheet.org/downloads/  
http://usfundamentals.com/download  
http://www.sports-reference.com/  
http://yann.lecun.com/exdb/mnist/  
  https://data.world/  
https://dev.twitter.com/streaming/overview  
https://stocktwits.com/developers/docs  
https://www.ehdp.com/vitalnet/datasets.htm  
https://www.quandl.com/data/FRED/documentation/documentation  
https://www.quandl.com/data/WIKI/documentation/bulk-download  
https://www.quandl.com/open-data  
https://www.quantopian.com/data  
https://github.com/awesomedata/awesome-public-datasets Agriculture, biology, climate, weather, earth sciences, economics, education, energy, finance, healthcare, …
http://datamarket.azure.com/browse/data?price=free Agriculture, weather and so on
https://openlibrary.org/developers/dumps Book library data sets
137.189.35.203/WebUI/CatDatabase/catData.html   Cat images
https://archive.org/details/2015_reddit_comments_corpus Chat data set
https://developer.twitter.com/en/docs/tweets/search/overview Chats-related content data
https://developers.facebook.com/products/instagram/ Chats-related content data
https://dataportals.org/search Civil, country, etc.
  http://gcmd.nasa.gov/ earth sciences and environmental sciences
https://nces.ed.gov/ Education data sets
https://nces.ed.gov/ education demographics in the USA and the world
http://www.mlopt.com/?p=6598 Electric Vehicle recharge points dataset from Northern Ireland and Republic of Ireland
http://www.cs.cmu.edu/~enron/      Email text as data set
http://open-data.europa.eu/en/data/ EU civil data sets
https://data.europa.eu/euodp/en/home EU civil, social
https://opendatamonitor.eu/frontend/web/index.php?r=dashboard%2Findex European data sets
http://vis-www.cs.umass.edu/lfw/ Faces data set
http://www.imdb.com/interfaces/ Film data
http://www.bfi.org.uk/education-research/film-industry-statistics-research Film data (UK)
https://markets.ft.com/data/ finance
https://www.imf.org/en/Data finances, debt rates, foreign exchange
https://cmu-perceptual-computing-lab.github.io/foot_keypoint_dataset/ Foot Keypoint Dataset (Carnegie Mellon University)
https://opencorporates.com/ Global database of companies
https://trends.google.com/trends/ Global internet searches
https://comtrade.un.org/ Global trade
  http://yann.lecun.com/exdb/mnist/ handwritten digits examples, and a test set of 10,000 examples
https://www.data.gov/health/ Health (USA)
http://data.nhm.ac.uk/ historical specimens in the London museum
https://www.glassdoor.com/developer/index.htm Human resource related data sets
https://archive.org/details/audio-covers image processing research data set
  https://archive.ics.uci.edu/ml/datasets/Iris Iris flowers data set. This is claimed to be one of the better freely available classification sets. It is used in the beginners project on Machine Learning and classification.
https://www.bjs.gov/index.cfm?ty=dca law enforcement in the USA
http://www.londonair.org.uk/london/asp/datadownload.asp London air quality data
http://archive.ics.uci.edu/ml/datasets.php Machine Learning
  http://archive.ics.uci.edu/ml/ Machine Learning data sets
http://mldata.org/ machine learning datasets for training systems
http://www.msmarco.org/ machine learning datasets for training systems in reading comprehension and question answering
https://aws.amazon.com/datasets/million-song-dataset/ Music data set
  https://opendata.cityofnewyork.us/ New York City data sets
https://data.worldbank.org/data-catalog/health-nutrition-and-population-statistics Nutrition, health, population
https://go.developer.ebay.com/ebay-marketplace-insights Online sales datasets (mainly USA)
http://opendata.cern.ch/ particle physics experiments data
https://exoplanetarchive.ipac.caltech.edu/ planets and stars
https://data.worldbank.org/ population demographics, economics
https://www.qlik.com/us/products/qlik-data-market population, currencies
https://deepmind.com/research/open-source/kinetics pose and action data sets
http://fivethirtyeight.com/ public opinion on sport and more
https://www.google.com/publicdata/directory public-interest data (USA)
https://scholar.google.com/ Scholarly text as data sets
https://science.mozilla.org/projects Sciences
https://cooldatasets.com/ Sciences, civil, entertainment, machine learning, etc.
https://www.ukdataservice.ac.uk/ social, economic population in the UK
http://www.databasesports.com/ Sports data
https://data.gov.uk/ UK civil, social
https://data.unicef.org/ UNICEF data sets, civil
http://data.un.org/ United Nations data sets
  http://data.humdata.org/ United Nations humanitarian data sets
https://archive.ics.uci.edu/ml/index.php University of California Machine Learning dataset
https://lodum.de/ University of Münster data sets
https://www.data.gov/ USA civil, social
https://ucr.fbi.gov/ USA crime statistics
http://www.census.gov/data.html USA population
https://www.yelp.com/dataset User data sets, (Yelp users)
http://opendataimpactmap.org/ Various
http://plenar.io/ Various
https://ckan.org/ Various
https://datahub.io/search Various
https://dataverse.org/ Various
https://github.com/datasets/ various
https://knoema.com/ various
https://opendatakit.org/ Various
https://opendatamonitor.eu/frontend/web/index.php?r=dashboard%2Findex Various
https://registry.opendata.aws/ Various
https://rs.io/100-interesting-data-sets-for-statistics/ various
https://www.columnfivemedia.com/100-best-free-data-sources-infographic Various
https://www.kaggle.com/datasets Various data sets
https://github.com/freeCodeCamp/open-data Various for coders
  http://datahub.io/ Various open data sets
https://www.kaggle.com/ Various, general data resource
https://www.reddit.com/r/datasets/comments/exnzrd/coronavirus_datasets/    https://github.com/CryptoKass/ncov-data Virus data set
https://wiki.dbpedia.org/ Wikipedia data sets
https://www.who.int/gho/database/en/ World Health Organization data sets
https://cdan.dot.gov/query   https://github.com/wgetsnaps/ftp.nhtsa.dot.gov–fars Traffic, USA, fatality data set
http://www.image-net.org/  Images as huge quality dataset
http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.296.9477&rep=rep1&type=pdf  
http://xiaming.me/posts/2014/10/23/leveraging-open-data-to-understand-urban-lives/ New York (civil) data sets and more

AI application in social settings: Facial Recognition & Surgical Masks

In some Asian countries the deployment of AI applications for facial recognition in the public sphere has been well on its way. In these same countries, for other reasons, may people are used to wearing facial masks. Some wear them, respecting their fellow citizens, when going through the motions of a cold or other illness. Some wear them to protect themselves from pollutants in the air. At times, facial masks or coverings are used to protect oneself from the effects of sunlight or sandstorms.

In European countries, for instance, masks have been used during festivities such as carnival and during civil disobedience acts, such as demonstrations. Presently, yet reluctantly, a few more individuals use surgical masks or similar filtering masks to protect themselves from illness. In general, until recently, governments in the EU have not been promoting their usage.

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Now that surgical masks are used even more onto faces within the general population, will this have an effect on investments made in AI research and developments towards facial recognition in the public sphere? Will it effect the usability of these systems already in place?

predicting pandoflux: a natural shift in Artificial sentiments on Emerging planetary patterns.

While browsing LinkedIn one can quickly sense the site is filled with professionalized visionaries professing the future.

This is the wonderful imagination we can expect from entrepreneurs, inventors, innovators, some makers, a few or more artists, a number of artisans, a whole lot of movers & shakers and policy makers’ think-tank spokespersons, who all frequent this social platform.

These days and months, since the end of 2019 into 2020, I have been noticing a shift into how that “just-a-flu” morphed into an emergency for a relatively few, into a pandemic for some more and into a fore-bearer of dramatic change to the human species, mapped without or with climate change (as an instigator of epidemics).

For some this has “suddenly” appeared the last two weeks or so. For others — that is, for those who are global nomads or global citizens, anyone from around the world living in China yet with loved-ones around the world; any Chinese citizen living in the world — this is now going into its 4th month and counting. For even fewer this was, now in retrospect, foreseeable; or so does the power of probability theory offer us.

Making a forecast, in the spirit of this biased opinion piece here, I foresee to be influenced in an emotionally heightened manner, as it has been, for another 3 months. That’s a very personal event of 6 to 7 months; for each one of those who fit the above category. That is, if I’m allowed being a bit too self-centered, not anticipating the passing of anyone close in these coming months because of virus-related complications.

Then there will be the echoes and reflections (and hopefully as little fall-out as possible) following this. Perhaps adding another 6 months? I’m just using a wild unsubstantiated version of prediction. I will call this my not so impressive “prediction” of the “Pandoflux”. Is a world of, and a world in, change a progressive world? Or, is progress what we do with change in relation to others and their context?

My predicting is not impressive to me since I also sense that flux seems simply inherent; even at a cellular or deeper level; even if we are imposingly-conserving. The latter too will pass, while its mechanism seems ever there?

Although I am very serious when I smile, is this attitude implied here too flippant or is it rather a watered-down version of a Taoist view on the world? At the least, I want you to think with me. Give it a moment.

Things will never be the same again…. we will never go back to how it was.” Previously, in a pre-pandemic sense, such statements seemed to come with an undertone of optimism and progressive thinking. Now, peri-pandemic, it sounds as if driven by fear and loss. It does not have to be, though.

Again, without wanting to be callous nor frivolous, nothing ever is the same and one can never ever go back to how something was before. That is, unless the affect of the memory of a change can be wiped from any mind that has been zapped back into a previous state. You know, like a reset button and a factory preset as the one suffered by Buzz Lightyear, in one of the Toystory animation franchises. Buzz too could not forget his previous setting.

Humanity and its events, however, are not a cartoon. It might seem like one, at times, but this tends to smell of sarcasm, disdain or at least of irony at the awkward moment. Indeed, perhaps this writing runs that risk as well.

When is the right moment to speak of change? Where and by who? When can we observe markers of change? What is such marker but a trigger of a parameter in a probability calculation of an environment that has always been in flux and has thrived on change?

In that regard, and as a side note, is a Machine Learning application an agent of change? Is it rather an agent in a process of corroboration that change is inherently part of the human experience and nature, as formalized via the field of advanced Calculus? Is perhaps such an AI application a neurotic obsession with control and its implied hanging onto a veil of pseudo-fixed and comforting insight?

After all, is a pattern not a pattern because it does not change? Or does it? What shall we call a pattern that is not to be recognized as a fixed pattern; chaos or rather, life?

I choose the latter.

When some individuals reminisce over the obvious how-it-was and the yet unknown changes to come, which dynamic pattern do they envision? A Chaotic one or one of LIFE?

In the struggles we face, whichever type, form, degree or function, we humans do want a sense of meaning as to the changes or the continuity these struggles imply. We make choices. We choose and recognize patterns.

This choice is there even if it is the meaning-giving idea of letting-go, breathing-out, moving-on and not looking for or clinging-on meaning in one attribute of a struggle in question. That is meaning. It could specifically be concerning if the meaning-giving labeling turns out as a painfully meaning-less one; driving one to the brink of or into madness and despair. That too is meaning. Meaning-giving is geared towards giving a future to a past event or to an event imagined becoming a past.

It is equally so as it is with communication: there is no such thing as no communication . One can not not-communicate with one’s brain; that meaning-giving thing between our ears. Even if we are trying to delegate this meaning-creation to the artificial realm of Machine Learning . This meaning-giving is inescapable.

On the other multiple ends of this 4-dimensional spectrum (yes, try to imagine this in a 3D high fidelity manner with a variable changing attribute over time), we can either observe small-minded yet large-sounding conspiracies of contrasting flavors and we can also see analyses of large Geo-political potentials and paradigm shifts.

This morning I was presented with a snippet of just that; the latter that is. The former is too irritating to me, while I do care about its extreme dangers.

In the earliest hours of the morning, I wake up very early, I was listening to BBC News World Service and its Newshour show. In it the astronomic numbers of applications for unemployment benefits in the USA were discussed. The data indicated about 10 million individuals were “shed” from their previous employment . Yes, “shed,” a word used in reporting as if humans are prickly needles from an ever-green pine tree that surprisingly looses its convoluted leaves. They and those without health insurance in the USA were discussed and then this was followed by an interview with Noam Chomsky. He was introduced as the academic who has “a radical solution to the economic shock” yet, who himself has repeatedly, and in this interview, rebutted this by stating that neo-liberalism is the radical paradigm here.

The episode, Newshour-20200402-USJoblessClaimsHitNewRecord, was retrieved on April 3, 2020 from http://www.bbc.co.uk/programmes/w172x2ylvg5rx9l

I suppose there is a reason why this morning the BBC, of all newscasters, suddenly interviewed Professor Noam Chomsky… no longer only Ms. Amy Goodman does so…

Later that same morning, I was sent a second item. It was a audio-video recording of an interview given by the present-day governor of New York State.

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Yes, one competes in a free market construct. Is this “free,” though? Is the following forecast, here below, of not-so-much-change too esoteric? Could it, in the end, be the common USA citizen, with house loans and student loans, in the billions, and some of whom can not afford insurance, that shall pay for this? Is this an attribute of the so-called change we have to see happen (from our distance)?

This pandemic could very well be a massive shift in some human consciousness that previously did not see the issues we are facing. Now, that is without linking this to climate change which has been done, preceding the pandemic in that it was suggested that with climate alterations pandemics might become more frequent.

It might be that the idea of nothing ever being the same again, which some are talking about, is the re-delegation of education to the parents turned teacher, on top of their in-house distant working, their gig-economy project, their home-cooked meals and their in-house floor-mopping.

Isn’t human civilization (at least quantatitively) perceived as great because its members have invented the process of delegation? At least, one person is not looking forward to this change in delegational power:

Or, the foreseen change might be that new EdTech APP we can innovate on with increased human-originated data collection and Machine Learning processes in support of the mother company and its marketing or advertising-placement strategies.

Will it be a never-seen-before change in child-like bickering, finger-pointing, belly-button staring and saddening forms of competing between (nation) states?

Or, is it a change in a form derived from that which people such as Noam Chomsky are speaking of ?

Humans are living proof of the possibility of a multitude of patterns in change and in changing patterns. Surely changing patterns of and in life are as well. Life and lives without meaning and meaning without life and lives, are not the changes a human needs.

Luckily for you, I cannot offer you any of these or other such changes, nor am I a forecaster.

I breathe out. At the least, I can offer one constant of hope: be well and do well, my fellow earthling.