NRO Director’s Innovation Initiative
The Cover Page shall not exceed
4,000 characters (approximately one page).
See Attachment 1, Proposal
Format.
The Executive Summary shall not
exceed 8,000 characters (approximately two pages). See Attachment 1,
Proposal Format.
The Technical/Management Section
shall not exceed 20,000 characters (approximately five pages). See
Attachment 1, Proposal Format.
The Price Section shall not exceed
4,000 characters (approximately one page).
See Attachment 1, Proposal
Format.
The Security Section shall not exceed 4,000 characters
(approximately one page). See Attachment 1, Proposal Format.
The following criteria are applied during step 2 of the evaluation (see
section 4.2):
(1) Technical Approach. The degree to which the Offeror's technical approach demonstrates understanding of the technical challenges, including:
a. Descriptions of the study objectives, tasks and subtasks.
b. Discussion of scientific and engineering practices.
c. Discussion and understanding of the technical risks.
(2) Management Approach. The degree to which the offeror's management and project plans
(3)
(4) demonstrate the ability to effectively and efficiently manage and administer the program to a successful conclusion, including:
a. Insight into the project’s progress and into the issues that will arise during the course of the project.
b. A project schedule that reflects the key events of the project and depicts a realistic, time-phased plan to achieve the proposal’s objectives.
c. Clear descriptions of the roles and responsibilities of any teaming organizations describing the offeror’s approach to providing management direction and oversight to these teaming organizations.
d. Clear descriptions of the experience and qualifications of key personnel.
e. Adequate available facilities, equipment and information to achieve the proposal’s objectives.
Program risk identification and mitigation approaches.
, the DII Program is most interested in investigating technologies uniquely applicable to the NRO
.
The DII Program is aimed at developing system concepts and technologies that will substantially enhance the NRO mission.
The DII Program provides an opportunity for pushing the boundaries of technology, processes, and methods to improve NRO products by orders of magnitude.
Any innovative design, method, process, technology, technique
or business practice
with the potential for enabling:
1)
revolutionary and agile approaches that respond
rapidly to new technological opportunities or emerging threats,
2) a substantive NRO mission improvement, or
3)
substantive resource savings
This problem area of interest focuses on all aspects of processing data and information into accurate, timely and useful intelligence products. Example areas of interest include:
(1) Preparation and correlation of information required to map,
plan, understand and execute operations in urban environments. This information should be prepared and
provided rapidly with little or no action on the part of a system(s) operator.
(2) Concepts, technologies, and techniques that allow an intelligence
workforce to provide intelligence users the information they need.
(3) These concepts,
technologies and techniques increase
the productivity of intelligence analysts by at least an order of magnitude.
Potential Contributions to the NRO. The applicability and potential impact of the proposed effort to the NRO mission.
The DII Program is most interested
in projects that significantly impact the ability of the NRO to accomplish
its mission and provide dramatic improvement through new mission capabilities
that directly solve critical intelligence problems.
Innovativeness of the proposed effort. The degree to which the proposed effort presents new and innovative research.
The DII Program is most interested in projects that are investigating previously unknown or uninvestigated technologies, methods, sources, etc.
Uniqueness of the proposed effort to
the NRO. The degree to which the
proposed effort is solely, and uniquely applicable to the NRO.
EXECUTIVE
SUMMARY
1.0
Overview. The executive summary shall not exceed 8,000 characters (approximately
two pages). The Executive Summary section shall include a concise overview of the
project and the following paragraphs:
1.1.
Description of the
proposed effort. Discuss the challenges of
the general technology area. Describe the specific technology to be
investigated. Describe how the proposed effort addresses a Problem Area of
Interest from the solicitation.
1.2. Potential Contributions to the NRO. Discuss the applicability and potential impact of the proposed effort to the NRO mission. The DII Program is most interested in projects that significantly impact the ability of the NRO to accomplish its mission and provide dramatic improvement through new mission capabilities that directly solve critical intelligence problems.
1.3. Innovativeness of the proposed effort. Discuss the degree to which the proposed effort presents new and innovative research. The DII Program is most interested in projects that are investigating previously unknown or uninvestigated technologies, methods, sources, etc.
1.4. Uniqueness of the proposed effort to the NRO. Discuss the degree to which the proposed effort is solely, and uniquely applicable to the NRO. The DII Program is most interested in projects that are unique to the NRO with little or no likelihood of development by other Government or Commercial sources.
Offerors should keep in mind that only
the executive summary is used in Step 1 of the evaluation process to determine
whether or not a proposal is of sufficient interest to the NRO for continued
evaluation in Step 2 of the evaluation process. Offerors are strongly advised to address each section of the
Executive Summary and not to exceed the prescribed character count limit. Characters in excess of the prescribed limit
will be truncated from the proposal and not evaluated.
TECHNICAL/MANAGEMENT
SECTION
2.0
Overview. The Technical/Management section shall not exceed 20,000 characters
(approximately five pages). The
Technical/Management section shall include a concise overview of the current
state-of-the-art, how this project advances that state-of-the-art and the
following paragraphs.
2.1.
Objectives and
Approach. Describe the objectives of the proposed effort and identify the
technical approach to be used to reach the objectives.
2.2.
Technical Risk. Identify relevant
technical issues/risks that the proposed effort will address.
2.3.
Sound Practices. Describe the
theory, simulation, modeling, experimental data, or other sound engineering and
scientific practices that support reaching the project objectives.
2.4. Offeror Capabilities. Describe any capabilities the offeror has that uniquely support the technology area. As a minimum, the following areas are to be addressed: 1) capabilities and relevant experience; 2) previous or current R&D work; 3) related government projects; and 4) related commercial projects.
2.5.
Facilities. Discuss facilities
and equipment requirements and availability for the proposed effort.
2.6.
Task Descriptions. Provide a
description for each of the tasks that represent work to be performed.
2.7.
Schedule. Provide a schedule
for the proposed effort including major milestones.
2.8. Deliverables. Identify all equipment, hardware, software, information, and/or data to be delivered to the NRO as a result of the proposed effort.
2.9.
Organization. Include relevant
organization charts and teaming organization charts, if applicable. Identify
what effort will be performed by which party i.e., Lead Organization, Teaming
Organization, Subcontracts, others, etc.
2.10.
Key personnel. Identify key
personnel and describe their qualifications.
No more than 2 individuals shall
be identified as key personnel.
2.11.
Programmatic risks. Identify and
describe how programmatic risks will be managed.
Abstract
for NRO Director’s Innovation Initiative
Mindtel,
LLC
Perceptualization environment/ perceptual modulation chamber
The
idea is to develop an interactive information fusion
environment with a rich set of multisensory rendering technologies and diverse
array of expressional modalities.
Perceptually enriched, interactively optimized
Representational Methods –
Interactive multi-modal, Multi-sensory perceptualization
of information
Neuro-Cognitive enhancement
Creating renderings of information across the different senses which take advantage of the specific features of multi-sensory physiology to access/accent overt and hidden information.
1. State specific sciences
modes of inquiry which take into account the neurocognitive state of the user in the perception and expression of information.
The presupposition is that what is perceived, thought about, and known is deeply colored and determined by the particular state of mind one is in when interaction with the information occurs.
2.
Perceptual state space modulation
altering the neurophysiological state of a user so as to alter perception and thus thinking about the information being interacted with
Modes of alteration include but
are not limited to
bioacoustic
bioenergetic
psychopharmacological
Interaction with information is limited only by the human nervous system’s ability to access meaning in (sensory) representations.
The perceptualization environment we propose is a generic and malleable tool for targeting the nervous system’s dispositions and capacities for getting into the mind.
In response to the NRO Director’s Innovation Initiation,
MindTel will propose the ‘perceptualization environment’ as a tool for meeting
the intensive information requirements and pressures the Office will experience
in the 21st century.
Our primary concern is with the interface between humans
and information systems.
Our goal is to make smart people smarter by fitting them with the most powerful and forward thinking technology by which their interaction with mission-critical information may be enhanced.
the idea of the perceptualization environment for human-information interaction.
, our purpose is the development of a generic interface tool which may be deployed in any number of diverse contexts of need.
perceptualization chamber
perceptualization
of information;
state specific sciences;
perceptual state space modulation;
perceptual enhancement through neuro cognitive modulation
The growing challenge for those required to interact with
large volumes of diverse information with a view towards intelligent, and at
times rapid, decision making is with perception.
How does a human, in general, perceive information?
What are ways in which perception is hindered or enhanced?
the dual elements
I.
the form in which the information is being
represented
II.
the perceptual cognitive state of the human during
perception of information
In order to address these key features of the human
interaction with information
we must introduce a very practical yet novel perceptual philosophical schema called neurocosmology.
This is quite an abstract idea is a very helpful
means for moving way beyond the current thinking about how humans interact with information and information environments.
we are always conscious things:
·
psyche, or mind(s)
·
biology, or life/living things
·
non-living physicality, or matter/inanimate things
Our linguistic shorthand for these three features of the known world
what we notice
as the content of our mind
living stuff, like our brain or body, or those of
others.
everything else
symbols for mind, life, and matter respectively.
Our goal then address the challenges and technologies for
human-information interaction
because the mind
is the ultimate location of our perceptions and intentions, and
because the mind is embedded somehow within the brain and
its contents are subject to what the brain does,
we will be talking about interaction with information in terms of how the brain, as mediator of what makes it into and out of the mind from the world is best disposed to receive and express that information.
This will lead to a discussion of how we might alter not only the representations of information, but also states of neurophysiology so as to alter perceptual states of the mind therefore optimizing the interaction with information in accord with how the brain best gets data into and out of the mind.
The brain, then,
is the gatekeeper of the mind.
Thus, figuring out ways to massively enhance the mind’s commerce with information
requires that
we understand the options for making the brain more substantially able to receive and process data as well as access things in data which it may not regularly have access to.
Here again is where the idea of altering the brain’s
capacities for accessing information within data will be central
The different possible means for altering the state of the brain will be explored in the context of state specific sciences.
In summary, we must discern how to optimally exploit the abilities of the brain for perceiving information both in physiologically robust representation of information and in neuro- cognitive processes
how information is presented to the human senses is a first order priority.
Emerging interface systems will concurrently present information to the visual, auditory, and tactile senses of the human body.
because human
visual physiology is hindered in some especially time-critical tasks by text.
We will explore optimal representations especially when coupling the factors of volume of information and time constraints
(e.g., medical emergencies). Therefore, signifiers other than text must be explored.
This means looking to visual forms of representation which are open to multi-modal features for conveying meaning (e.g., geometric shapes, colors, movements, morphings, etc.).
transform textual data into new kinds of signifiers for rapid and meaning-rich visualizations.
The same thinking would aim to integrate auditory and
tactile sensory systems into the perceptualization environment
arbitrary forms
which if useful would then be assigned multi-modal significance.
how to address the problem of altering the representations of information.
The essential point is
to open up
new ways of thinking and talking about the systematic optimization of interactive information perceptualization and expression .
we are proposing
conceptual and methodological framework
in some particular scientific discipline makes some kinds
of data visible and significant while other kinds of data remain either
invisible, or else noise or a hindrance.
Think of how within a certain paradigmatic conceptual filter, a
contaminant of cell cultures was an ongoing nuisance which needed to be eliminated. However, for some reason someone decided to
ask a different question about that stubborn contaminant and thus discovered
penicillin. Similarly, think of how
long the placebo effect was this nuisance in clinical drug trials which always
was the enemy of how we measured the effects of new medicines. Eventually some folks thinking from within
some other framework, or boundary space, asked if there wasn’t something very
interesting about positive medical outcomes resulting from biologically
inactive substances in the bodies of patients who believed they were
receiving a real drug. All this to say
that changes in perception disclose heretofore invisible information.
Given that an ASC is an
overall qualitative and quantitative shift in the complex functioning of
consciousness, such that there are new ‘logics’ and perceptions (which would
constitute a paradigm shift), it is quite reasonable to hypothesize that
communication may take a different pattern.
For two observers, both of whom, we assume, are fluent in communicating
with each other in a given SoC, communication about some new observations may
seem adequate to them, or may be improved of deteriorated in specific
ways. To an outside observer, an
observer in a different SoC, the communication between these two observers may
seem ‘deteriorated.’ (Tart, 1972)
State specific sciences are those scientific inquiries which take into account ‘states of consciousness’
Thus,
altering our perceptual cognitive states at calculated points during the design
and execution of experimental process may open us to entire realms of
information which would have remained totally invisible to us.
The idea of perceptual state space modulation is
our attempt to conceptualize what it would look like to introduce state
specific sciences into the discussion of human-information interaction.
Not only do new representations of information promise to show us new and powerful contents of our information which we could not have otherwise seen, but so might changes in brain state give us new perceptions of that information.
Ultimately it is the thoughts which one has about information which leads to decisions and thus processes set in motion to benefit maximally from that information.
Any logic consists of a
basic set of assumptions and a set of rules for manipulating information, based
on those assumption. Change the
assumptions, or change the rules, and there may be entirely different outcomes
from the same data … By changing the paradigm, altering the SoC, the nature of
theory building may change radically.
Thus a person in SoC2 might come to very different conclusions about the
nature of the same events that he observed in SoC1. An investigator in SoC may comment on the comprehensibility of
the second person’s ideas from the point of view (paradigm) of SoC1, but can
say nothing about their inherent validity.
A scientist who could enter either SoC 1 or 2, however, could pronounce
on the comprehensibility of the other’s theory, and the adherence of that
theory to the rules and logic of SoC 2.
Thus scientists trained in the same SoC may check on the logical
validity of each other’s theorizing. We
have then the possibility of a state specific logic underlying theorizing in
various SoC’s…If such sciences could be created, we would have a group of
highly skilled, dedicated, and trained practitioners able to achieve certain
SoC’s and able to agree with one another that they have attained a common
state. While in the SoC, they might
then investigate other areas of interest, whether these be totally internal
phenomena of that given state, the interaction of that state with external,
physical reality, or people in other SoC’s.
(Tart, 1972)
How might one think about modulating states of the brain so as to modulate states of the mind
We have identified several. psychopharmacological interventions exist which have shown promise in enhancing the perceptual and cognitive processes of the brain
neuromodulations of mental/perceptual states .
As neuroscience elucidates the different neurochemical and phenomenological associations with different chemicals, more possibilities for safe and effective use of such substances will be made available.
Another means of inducing alternative SoC is with bioenergetic modulations.
EM and other
kinds of energy modulations have been shown to have diverse influences on
neurophysiology.
Specifically psycho-neurophysiology
We propose to explore certain Acoustic frequency modulations in the perceptualization environment as a means of perceptual modulation.
Acoustic modulations may also be an avenue for perceptual state space modulation.
Manipulated sound is well documented to have effects on the central nervous system which may enhance perception and cognition..
All of this aims at the goal of massively enhancing the human interaction with information so that the best decisions can be made which affect lives, resources, and relationships between government and support entities.
In this abstract our purpose has been to climb out of the box
to think in new ways about the perceptual basis of human interaction with vast and diverse data sources.
There is no mystery that what we are proposing is far
outside the present discussion of interface development. However, there is a larger issue at
stake.
Without pushing the boundaries of what can count as an acceptable means for accessing information and making decisions based upon it, unrealized possibilities to help go unseen.
Multisensory perceptualization of information, state specific sciences, perceptual state space modulation
modulated
representational efficiencies we have found to be critical in the development
of truly cutting edge interface resources.
We aim to make smart people smarter. Quicker faster better sooner
The
perceptualization environment is a tool which we propose to design and develop
such that the National Reconnaissance Office would be substantially bolstered
in its important mission of interacting with immense quantities of diverse
intelligence data.
NRO Director’s Innovation Initiative
Mindtel,
LLC
November
1, 2001
Methods for Perceptually Enhanced Human Interaction
with Information: the Perceptualization Environment
In recent years, the technological capacities of the National Reconaissance Office to access and collect diverse information have increased substantially.
And yet, there is
clear awareness within the organization that the ability is still insufficient, particularly in
this time of growing concern over urban warfare and the atrocious threat of
biological and chemical weapons being used as a means of homeland assault.
In line with this need for even greater capacities to process gathered intelligence,
MindTel is aware of the urgent need which exists for a
rigorous re-consideration of the role of the human in how intelligence
processes are created and conducted for analysis.
The complex and advancing nature of information gathering
need for a more robust integration of the human user into a multipoint and immersive knowledge discovery matrix.
Information gathering and
manipulation technologies are limited in their ability to make a difference to
the extent that the human user is limited in his ability to exploit that
information.
We propose to develop a system sensitive in the conceptual and methodological consideration of the human’s extraordinary abilities for perception, cognition and expression
the primary problem with current interface models for humans
interacting with information systems is the typical emphasis on
technologies for gathering, handling, and storing information,
the hard problems as to how to best present the information to the user has been practically ignored.
What is the best way to not only present information to a user, but more importantly, to give the user tools which allow them to manipulate information in meaningful ways
How can collection be made more valuable by being renderable according the needs and preferences of particular neuro-cognitive systems (human users) tasked to interact with that information?
MindTel seeks to develop an inclusive system based on specific methodologies and emergent interface systems
We propose to develop an approach to the problem which leverages sensory physiological principles with an operational knowledge of human-information system integration.
The priority of our approach is to connect the human to
the content via an interface which exploits the visual, auditory, and the
tactile capacities of the human body for perception.
a much greater
capacity for perceptual interaction with information than the current interface
model permits. .
MindTel will propose
the ‘perceptualization
environment’ as
a multi-modal, multi-sensory,
high performance communications tool for handling the escalating quantities and
types of information the Office will confront in the near and distant
future.
MindTel’s primary goal is to
develop an interface medium
for drastically increasing the accessibility and, perhaps more
importantly, the intelligibility of variant intelligence data.
Intelligibility, or the graspable, available
meaning within information, is determined by the manner(s) in which it is
presented to a user.
The representation and comprehensibility of information are the conceptual and technological challenges we seek to address with the perceptualization environment.
This environment is a unified interface system comprised of a core infrastructure and experimental methodology which optimizes the integration of human intelligence through increased multi-sensory perceptualization and enhanced expressive capacity.
This tool will provide an order of magnitude increase in human-information interaction.
an exploration of states of mind and how their manipulation may
augment the processes of both intelligence and expressivity.
In this area we will introduce the ideas of state specific
sciences and perceptual state space modulation, cognitive state
enhancements.
For enhanced
Querying, Fusion, Creation, and Communication
Human neuro-cognitive integration into the fusing and presenting of information opens the space for discernment of knowledge which would have remained invisible.
When the human is more deeply woven into the processes whereby the machine makes decisions about data and representation, more powerful options for response are available.
This involves, for example, the capacity to specify queries and the representations of the results thereof.
use the search and representation capacities of the system to capture the characterization of a complex cluster of some data,
enabling a powerful capacity to share that information with another expert who will be sent much farther along in the process of action.
Part of what this technology will allow is the opportunity to not just interact with content, but to interact with processes and patterns within information which will then be open to modification.
The pattern is often more significant than the content contained within the pattern.
Attention to the patterns within information is a means of developing sensitivity to a process of optimally handling incoming information
A.3. Physicality & Functionality
Mindtel has developed powerful and generic hardware/software solutions to handle core functional elements of this communications environment.
Our efforts,
implementation of both the conceptual models and
functional prototypes.
The latter will be initial demonstrations of how the many streams of critical, time sensitive information may be innovatively woven together and presented to the user with a high degree of content dynamicity and user control.
Also, the final presentation of information to the user will manifest perceptual diversity; diversity in using the tool to integrate and render information in perceptual styles which depend on mission needs and user biases
We
currently conceive of the perceptualization environment as a physical space,
A room of some
size, yet to be determined, will be built to contain an array of current and
high-end visual and auditory displays.
The
perceptualization environment will be constituted by the following elements:
1.
Hardware/Software
2.
Primary physicality of system
3.
Functionality of integrated components
4.
Open & adaptable operational processes and methods
The goal of the perceptualization environment is to
simultaneously explore and enhance both the
‘State-specific sciences’ refers to the idea that states of the brain affect states of mind (i.e., perception and cognition).
Therefore, it is reasonable to assume that
alterations in brain states will bring out some correlative alterations in perceptual cognitive states;
changes in perception disclose heretofore invisible information.
State specific sciences take into account and exploit ‘states of consciousness’ (SoC) when interacting with particular data.
altering our perceptual cognitive states at calculated points during the design and execution of the interaction process may open us to entire realms of information which would have remained totally invisible.
The idea of perceptual state space modulation is our attempt to conceptualize what it would look like to introduce state specific sciences into the discussion of human-information interaction.
new representations of information promise to show us new and powerful contents of our information which we could not have otherwise seen,
but so might changes in brain state give us new perceptions of that information.
Ultimately, it is the thoughts which one has about information which leads to decisions and thus processes set in motion to benefit most from that information.
How might one think about modulating states of the brain so as to modulate states of the perceiving mind?
We have identified several:
Bio-energetic modulations. Microwaves and other kinds of energy modulations have been shown to have diverse influences on neurophysiology.
possible modulations into
the perceptualization environment.
Acoustic modulations may also be
an avenue for perceptual state space modulation. Manipulated sound can have effects on the central nervous system
which may enhance perception and cognition in important ways.
Hemispheric synchronization is the phenomena whereby communication
between the hemispheres is optimized/altered along some axis resulting in
perceptual and cognitive alterations.
MindTel’s research in this area will be centered on acoustic state modulation.
the perceptualization environment is likely to show value once substantial progress has been made in the development of the perceptualization technologies.
to think in new ways about the perceptual
basis of human interaction with vast and diverse data sources .
What we are proposing is far outside the normative realm of how to construct interfaces and represent information.
Thinking in these ways will require potential users to understand the challenge which confronts them in this time of intelligence gathering.
Without pushing the boundaries of what can count as an acceptable means for accessing information and making decisions based upon it, unrealized possibilities to help go unseen.
We are aiming towards a new kind of perceptually based literacy to aid any process of high quantity, high performance interaction with information.
Arriving at this place in
our thinking has been the result of conceptual cross linking based on a desire
for both a flexibility of functionality and massively enhanced perceptual dimensionality.
The perceptualization environment is a
representational knowledge matrix which addresses the problem of the
insufficient language structures we currently use in digital
communications.
The new language we are working on will no doubt lead to a kind of
perceptual cross
pollination in the different realms where this technology is eventually applied.
Our desire is to be
funded in sufficient measure to
construct a robust
prototype which collects data from sensors, human input, and databases and
turns it into “sentences” in our new perceptual languages.
An example of a user specifying how the machine ought to present him with raw data.
a different way of representing that same data, a much superior way.
and turn particular elements of all that raw text into dynamical geometries
two word roots: cardio(heart) and arterio(artery).
Then we tell it to generate some primitive 3D shape for every 100 occurrences of the roots.
The
next step will be to then have this program begin to alter and
complexify these shapes
in
accord with that part of all those words in the text which represent
additions to these two roots (eg., cardiopulmonary, cardiotoxic, cardiothoracic,
or arteriosclerosis, etc.).
In this way we are attempting to get beyond text/words to represent data and into
Once the basic tools is developed, we can take a data base full of any content from medical textbooks, to the works of Shakespeare, or the works of Aristotle, or the Greek new testament, or the phone book, or the video catalog of the local Blockbuster and
a new literacy of multidimensional dynamical objects to take the place of all that text.
transform the significations of the text/words therein into the significations of dynamical shapes, etc.
Intelligence
analysis will be advanced by a quantum leap.
The perceptualization environment is designed to serve
the intensive information needs of communications/information specialists in
any domain open to the benefit of such a technology.
a.
collect data from diverse sensors on the ground
·
physiological: heart, blood pressure, blood glucose,
etc.
·
chemical: air quality, water quality
·
whether: temperature, wind direction
b.
collect data from human input devices
As more information comes in through sensors and human
input via the PDA into the form fields of those doing assessment on the ground,
the interface’s representation is added to and perceptually enriched in real
time. .
the evolution of the representation in real time as
information continues to come into the system.
the innovation we bring to this element of the interface is in the abstraction of some information as geometries.
These geometry
data are then fused with the topographic map to represent many
parameters from ground data localized by means of GPS coordinates.
important piece of this perceptualization picture is in the representation of information queried from electronic databases.
a representational technique MindTel conceived to handle the vast and growing sources of data needed by a whole host of users from those working the areas of intelligence, medicine, disaster relief, stock trading, and many others.
The idea of Bibliomics is to take textual/numerical data and begin to find ways of abstracting critical elements of it for presentation to a user who either has scarce time for its raw form, or else who needs to ‘see’ features of that data normally invisible when it exists as text or numbers.
The latter covers that information in data we do not even know could be there.
New representations will often disclose what was not know to exist before it could be represented.
This means that textual representation will be substantially transformed because human visual information processing is hindered as text can be a non-optimal representation when confronting the factors of content volume and time limits (e.g., intelligence emergencies).
Therefore, signifiers other than text ought to be explored and experimented with.
visual forms of representation which are open to multi-modal features for conveying meaning (e.g., geometric shapes, colors, movements, shape changes, etc.).
Below are some examples of how we might transform textual data into new kinds of signifiers for rapid and meaning-rich visualizations.
arbitrary forms which if useful would then be assigned multi-modal significance.
visual representation could be condensed and more meaningfully abstracted in some way
diverse resources could be condensed from multiple data stores and more quickly and meaningfully visualized?
a much richer
geometric complexification of the diverse intelligence
the intelligence user has input a query requesting everything
from the geographic location of suspected or known terrorist personnel clusters, to amount of money and locations of their bank accounts, to their spending patterns of the past 2 years including what/where they have purchased and in what amounts.
The queried information could incorporate a large number of variables.
Bibliomic data fusion and dynamic geometrification of the many database streams collected in the search
.
This set of images could be an abstract and dynamic visualization of the needed data.
These are merely examples of the kinds of thinking we are proposing for how to address the problem of altering the representations of information.
The essential point is to open up new ways of thinking and talking about the perceptualization and expression of the vast and diverse data which we and our sponsors will desire from the perceptualization environment.