James Lovelock says we are all part of Gaia, not separate. The tiny microbes -- ones that we hardly knew existed some centuries ago -- give us oxygen and control the planet's temperature, making the planet safe and comfortable (more or less) for all life -- unless we overwhelm them.
Now, he says, with our computers and fiber optics we build for Gaia a fast nervous system she never had before. This is part of our job here it seems. How long before nearly everyone on the planet has a mobile phone or smart phone?
You build a nervous system with fun and nonsense first -- keeping the lines full of stuff moving back and forth -- making long and short connections in every direction. Then once it is in place, you might do something important with it -- when the time comes. What is a tiny baby doing while still in the womb?
Tiny processes. Big ideas. Massive consequences.
Wednesday, April 25, 2012
Thursday, April 19, 2012
Neurological Diversity -- Seeking Diverse Brains as Engines of Discovery
In recent months, I have redrafted various
arguments in an effort to persuade heads of companies, research institutes and
other organizations to seek out and hire creative dyslexics, among with others
with diverse brains – since there is mounting evidence that they may be able to
do work that is more creative than those with brains well suited to academic
success but poorly suited to original discovery or fundamental innovation.
Accordingly, I have proposed that these
organizations make it an explicit part of their mission to include and employ
diverse individuals with diverse kinds of brains for their potential as
“engines of discovery.”
As many of you know, I have advocated this approach
for many years. However, resistance to these ideas and approaches remains
strong.
Some misunderstand my intention and see the
proposal as a way to be kindly and charitable to a disadvantaged population –
whereas my intent is to make the case that these people can (and in many cases
will) be a major benefit to the organization – not the other way around.
Others appear to almost understand the great unused
potential -- but then they fall back into conventional thinking -- claiming
that such individuals should not be sought out because they could not gain
corporate promotions or academic tenure.
What, indeed, are we mainly interested in here?
Major discoveries or innovation? Or mere conventional credentials (however
impressive).
Maybe this is a way of selecting truly innovative
organizations – separating them from those who merely claim to be innovative.
Below, I have listed some of the arguments I have
been using. I welcome comments and suggestions for stronger and more persuasive
statements.
_________________
Alternative Modes of Learning and Thinking
Several organizations have long studied (as
subjects) individuals with dyslexia, Asperger’s syndrome, ADHD and other
alternative modes of learning and thinking.
It is now proposed that this organization make an
explicit effort to hire and do what is needed to support these individuals,
focusing not on what they cannot do, but, rather (given a chance and the right
environment) what some of them can do better than anyone else.
This proposal is consistent with the desire within
the organization to be a source for major scientific discoveries and
technological innovations – and as well as a major theme and vision for the
future of the organization.
Frequently, the focus has been on what is wrong and
finding out how to fix it. However, it is becoming more and more clear that in
some (or many) cases the focus ought to be on finding out what is right -- and
finding ways to bring unusual mixes of talents and capabilities to bear on
leading-edge research and technological problems.
New Assessments and Expectations
Part of this process would inevitably involve the
development of new assessment tools to help identify the subset in each group
that would have the greatest potential for substantial innovation and discovery.
It is axiomatic that many of these individuals will
have unusually great strengths in some areas while they will have surprising
(even shocking) weaknesses in other areas.
Recognition of such patterns of mixed talents
would, of course, need to be part of an enlightened institutional culture.
Otherwise, conventionally successful employees would think “how can they be
expected to do x when they cannot even do y and other similar simple tasks.”
Or, how could they be selected “when their grades and test scores are so low
and uneven.”
In a longer-term solution, it is hoped that, in
time, these individuals will score highly on another set of tests and measures
that have yet to be designed. (In a recent presentation to a audience of young
dyslexic students, one speaker called for the design of new tests on which the
dyslexics would get the top scores while the non-dyslexics would get the lowest
scores. The speaker was surprised to hear this audience, previously attentive
but quiet, break out into spontaneous and enthusiastic applause.)
Another part of this process would be developing
administrative and workplace procedures that would allow these individuals to
survive, prosper and be productive in work environments that seem (at least
initially and indirectly) to be well designed to weed out many of these same
individuals.
If this approach is sound, the result might be
expected to access previously untapped talents – resulting in a substantial
increase in important innovations and discoveries relative to more conventional
approaches and working conditions.
It Is About Time To Take Advantage of Diversity
There is mounting anecdotal and empirical evidence
that the major discoveries and technological innovations sought by major
research institutions come (sometimes or even often) not from the students with
the best academic records but, rather – from students with mixed records, from junior
faculty with doubtful prospects, from experts trained in apparently unrelated fields or from creative non-academic
entrepreneurs whose fresh insights and unexpected discoveries can transform a
field.
There are many stories of remarkable discoveries
from those trained in unrelated fields or those with mixed capabilities.
Yet in spite of these stories, conventional methods
for selection and advancement persist – while extremely talented individuals
are routinely dumped along the wayside.
It seems that it is about time to change this
situation.
For example, in recent years, dyslexia is coming to
be seen, remarkably, as a significant advantage in an increasing number of
fields -- often linked to success in design innovation, entrepreneurial
business and scientific discovery.
Researchers have recently observed a strong ability
among some dyslexics to see clear patterns in extremely complex systems – or to
have an unusual capacity to predict how a news story will unfold or how a trend
will produce unexpected results.
One of the founders of the modern study of
molecular biology was dyslexic and described how he used his powerful visual
imagination to see new patterns and develop fundamental insights (in one case, twelve
years ahead of all others in the field) into the links between the genetic code
and the immune system. Later, a different scientist proved experimentally that
he was correct and received a Nobel Prize.
The US National Science Foundation has been funding
a Harvard-Smithsonian study of when and where dyslexia may be an advantage in
doing science, especially within astrophysics.
In the field of computer graphics and simulation,
dyslexic artists and technologists are often leading innovators.
A world famous professor of paleontology tries to
teach his graduate students “how to think like a dyslexic” so they can see
patterns invisible to others, making discoveries of processes long thought
impossible. The rest is “just memorization,” he says, without innovation or
significant discovery.
Some companies (such as Google) are now
investigating ways of making the workplace better suited for employees with
greater neurological diversity.
Some researchers are now focusing on high-level
creativity, visual thinking and new visual technologies – focusing on the role
of brain diversity (including dyslexia, Asperger’s syndrome and other
alternative modes of learning and thinking).
There are more and more examples -- including one
British family with (over five generations) many visual thinkers, many visual
occupations, many diagnosed dyslexics (especially in the last two generations)
and four winners of the Nobel Prize in Physics.
Two of these prizes are related to the development of x-ray technologies
used in the discovery of the structure of DNA.
For further reading: See the recent book, The Dyslexic Advantage: Unlocking the Hidden
Potential of the Dyslexic Brain by Brock L. Eide, MD, and Fernette F. Eide,
MD, Hudson Street Press, Penguin Group, 2011; especially, Chapter 2, “Dyslexia
from Two Perspectives,” pp. 10-18, and Chapter 4, “Differences in Brain
Structure,” pp. 30-43. Also see, In the
Mind’s Eye: Creative Visual Thinkers, Gifted Dyslexics and the Rise of Visual
Technologies, Second Edition, with Foreword by Oliver Sacks, MD, Prometheus
Books, 2009; Chapter 8, “Patterns in Creativity,” pp. 225-247.
Subscribe to:
Posts (Atom)