Fluid intelligence: the capacity to think logically and solve problems in novel situations, independent of acquired knowledge

Psychology has found the basis of fluid intelligence in the juxtaposition of layered memory and application as means to essentially “connect two fluid ideas with an an abstractly analogous property”. Such a mathematical design would have to be able to therefore derive temporal relationships with weighted bonds between two coherently disparate concepts through the means of similar properties. These properties within node types will have to be self-defined and self-propagated within idea types.


In a pursuit towards a truly dynamic artificial intelligence, it is necessary to establish a recurrent method to decipher the presence of concrete yet abstract entities (“ideas”) independent of a related and coherent topic set.
A considerable amount of work venturing into this field has culminated in the prevalence of statistical methods to extract probabilistic models dependent on large amounts of unstructured data. These Bayesian data analytic techniques often result in an understanding superficial in the context of a true relational understanding. Furthermore, this “bag-of-words” approach when looking at amounts of unstructured data (quantifiable by correct relationships derived between the idea nodes) often relate to a single dimensional understanding of the topics at hand. Traditionally, when these topics are transformed, it is difficult to extract hierarchy and queryable relations using matrix transformations from a derived data set.

The project that I will be describing in the subsequent posts is an effort to change the approach from which dynamic fluid intelligence is derived, finding a backbone in streaming big data. Ideally, this model would be able to take a layered, multi-dimensional approach to autonomous identification of properties of dynamically changing ideas from portions of said data set. It would also be able to find types of relationships, ultimately deriving a set of previously undefined relational schemas through unsupervised machine learning techniques that would ultimately allow for a queryable graph with properties and nodes initially undefined.