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Production of Knowledge_D.Foray_chapter3 -EbruBasak
1.
The
Economics
of
Knowledge
Chapter
3:
“Production
of
Knowledge”
by
Dominique
Foray
Ebru
BAŞAK
ebru.basak@gmail.com
646612
2. Production
of
Knowledge-‐1
• Research:
A
“Distance”
Activity
of
Production
and
Consumption
• Different
Types
of
Research?
• Why
Is
R&D
Important?
• The
Diffusion
of
Science-‐Based
Research
• Research
Collaboration
• Increasing
Returns
in
the
Production
of
Knowledge
2
3.
Production
of
Knowledge-‐2
•
Learning-‐by-‐Doing
•
•
•
•
•
•
•
The
Main
Economic
Issue
Learning
as
Experimentation
during
Production
Users
at
the
Heart
of
Knowledge
Production
Maximizing
Learning
Potential
Transition
toward
the
Knowledge
Economy
Coordination
Model
of
Knowledge
Production
Collaboration
in
Knowledge
Production
3
4. Production
of
Knowledge
Crea%ng
Genera%ng
Producing
Knowledge
is
produced
in
different
ways
that
can
be
defined
in
terms
of
a
dual
dichotomy.
4
5. Production
of
Knowledge
Off-‐line
• through
formal
R&D
work
off-‐line
(ie
isolated
and
sheltered
from
regular
production
of
goods
and
services)
On-‐line
• through
learning,
on-‐
line,
where
individuals
learn-‐by-‐
doing,
(not
isolated,
individuals
can
assess
what
they
learn
and
share
practices)
5
6. Four
Forms
of
Knowledge
Production
Off-‐line
process
of
knowledge
creation
On-‐line
process
of
knowledge
creation
Learning-‐
by-‐doing
R&D
Search
Model
Formal
Coordination
Model
integration
Informal
Integration
Table
3.1
6
7. It
is
useful
to
create
a
second
dichotomy
between
two
types
of
knowledge
genera;ng
ac;vi;es
search
model
• knowledge
generation
may
involve
search
processes
within
domains
that
are
relatively
unexplored
or
underexploited.
This
is
the
search
model
of
knowledge
generation.
coordination
model
• the
processes
of
increasing
complexity
in
industrial
architectures
involve
somewhat
different
needs
for
the
systems
of
knowledge
generation.
There
is
a
need
to
produce
“integrative
knowledge,”
such
as
norms,
standards,
and
common
platforms.
These
processes
comprise
a
coordination
model
of
knowledge
generation.
7
8. Key
Concepts
Research:
Concept
that
when
knowledge
is
produced
through
search
processes,
in
some
kind
of
organized
and
formal
way
Research
and
Development
(R&D):
is
used
for
intellectual
creation
undertaken
systematically
for
the
purpose
of
increasing
the
stock
of
knowledge
8
9. Research:
A
“Distance”
Activity
of
Production
and
Consumption
Research
Centers,
universities
and
R&D
Labs
are
the
main
institutions
that
have
the
explicit
aim
of
creating
knowledge
The
main
characteristic
of
these
activities
is
their
situation
“at
a
certain
distance”
from
places
of
production
and
consumption.
This
distance,
which
can
at
once
be
spatial,
temporal,
and
institutional,
is
needed
to
nurture
the
talent
of:
“philosophers
or
men
of
speculation,
whose
trade
it
is
not
to
do
anything,
but
to
observe
everything;
and
who,
upon
that
account,
are
often
capable
of
combining
the
powers
of
the
most
distant
and
dissimilar
objects.
In
the
progress
of
society,
philosophy
or
speculation
becomes
like
every
other
employment,
the
principal
or
sole
trade
and
occupation
of
a
particular
9
class
of
citizens.”
(Adam
Smith,
Wealth
of
Nations)
10. Research: A “Distance” Activity of
Production and Consumption
This
notion
of
distance
is
essential
because
It
enables
us
to
distinguish
researchers
from
other
producers
of
knowledge.
The
distance
can
be
large
or
small—research
is
far
from
industry
or
close
to
it—and
even
if
it
is
a
source
of
problems,
it
has
to
exist
to
allow
for
the
division
of
labor
and
the
development
of
research
related
occupations
(Mowery
1990;
Nelson
and
Wright
1992).
In
20th
century,
R&D
labs
to
companies
à
upsurge
of
specific
occupations
and
skills.
Even
if
the
share
of
research
in
the
stock
of
intangible
capital
necessarily
remained
small,
R&D
activity
has
been
a
mainstay
of
national
innovation
systems
since
the
beginning
of
the
20th
century.
10
11. Different Types of Research
Basic
(Fundamental)
Research
Applied
Research
Production
of
Infratechnology
11
12. Basic
(Fundamental)
Research
Basic
or
fundamental
research
aims
at
producing
basic
knowledge
that
allows
for
a
fundamental
understanding
of
the
laws
of
nature
or
society.
This
first
category
is
like
surveying:
it
generates
maps,
that
is,
informational
outputs,
that
raise
the
return
to
further
investment
in
exploration
and
exploitation
12
13. Applied
Research
Applied
research
and
development
aims
at
producing
knowledge
that
facilitates
the
resolution
of
practical
problems.
This
second
category
deals
with
the
practical
implementation
of
basic
knowledge
that
gives
rise
to
applied
product
and
process
technologies.
13
14. Production
of
Infratechnology
There
is
finally
a
particular
class
of
activity
which
is
functionally
different
from
the
first
two
but
is
difficult
to
identify
and
measure.
This
category
concerns
the
production
of
infratechnology,
meaning
sets
of
methods,
scientific
and
engineering
databases,
models,
and
measurement
and
quality
standards
that
support
and
coordinate
the
investigation
of
fundamental
physical
properties
of
matter
and
the
practical
implementation
of
basic
knowledge
(Tassey
1992).
14
15. Different Types of Research
These
categories
are
defined
in
terms
of
the
extent
of
their
exploratory
nature
and
their
distance
from
commercial
application.
This
categorization
not
seem
to
correspond
to
the
reality
of
certain
sectors
in
which
basic
research
seems
closely
related
to
the
market
(e.g.,
the
pharmaceutical
and
biotechnology
sectors).
15
16. Different Types of Research?
The
dis%nc%on
between
these
two
types
of
basic
research
is
important
because
it
prepares
people’s
minds
for
analyzing
situa;ons
in
which
basic
research
is
close
to
the
market.
16
17. Why Is R&D Important?
In
the
process
of
knowledge
production
the
notion
of
“distance”
activity
makes
R&D
an
important
functionality:
1. Economic
aspect:
meaning
that
R&D
cannot
be
subjected
to
the
same
kind
of
cost-‐effective
and
just-‐in-‐time
managerial
approach
as
the
regular
activity
of
goods
and
service
production.
2.
Cognitive
aspect
means
that
the
distance
between
the
laboratory
and
the
real
world
makes
it
possible
to
undertake
experiments
while
using
the
lab
to
control
some
aspects
of
the
reality.
17
18. Economic Aspect
The
main
motivation
of
explicit
R&D
activities
is
the
production
of
knowledge.
An
entrepreneur
or
a
policy
maker
who
is
launching
a
R&D
program
is
perfectly
aware
that
this
activity
is
fraught
with
many
uncertainties.
Given
this
uncertainty,
research
activities
cannot
be
managed
and
outputs
evaluated
in
the
same
way
as
in
the
regular
production
of
goods
and
services.
This
creates
a
sort
of
“isolated
or
protected
world”
for
R&D
which
is
less
dependent
on
cost
effectiveness
and
timely
delivery
of
outputs
than
are
other
economic
activities.
Even
a
failure
in
R&D
can
be
viewed
as
a
useful
informational
output.
Particularly
when
it
happens
at
the
basic
research
stage,
the
failure
contributes
to
a
better
“map”
of
cognitive
opportunities.
18
19. Economic Aspect
“Sheltered”
when
managerial
decisions
taken
under
some
kind
of
economic
constraint
Following
economic
and
management
analysis
of
the
Japanese-‐
type
firm
(Aoki
1988),
efforts
were
made
to
bring
the
R&D
function
closer
to
product
development.
The
aim
was
to
subject
processes
of
knowledge
production
to
the
immediate
needs
of
the
market.
The
decline
of
corporate
R&D
laboratories,
the
relocation
of
research
structures
and
budgets
within
operating
divisions,
and
the
creation
of
internal
markets
for
research
were
all
trends
toward
a
stronger
dependence
of
research
on
market
needs,
emphasis
on
shorter-‐term
objectives,
and
introduction
of
more
cost
effective
research
techniques
and
practices.
.
19
20. Economic Aspect
But
there
is
a
basic
confusion
between
the
idea
that
research
is
“endogenous”
because
it
is
constrained,
influenced,
and
oriented
by
the
economy
and
society
(Rosenberg
1982),
and
the
incorrect
idea
that
all
distance
must
be
reduced.
By
eliminating
all
distance
it
seems
that
one
loses
the
capacity,
peculiar
to
research,
to
trigger
radical
changes
by
conceiving
major
innovations
that
will
create
tomorrow’s
markets.
20
21. Cognitive Aspect
Explicit
R&D
activity
is
also
important
because
it
makes
it
possible
(in
most
cases)
to
conceive
and
carry
out
well-‐defined
and
controlled
experimental
probes
of
possible
ways
to
improve
technological
performance
and
to
get
relatively
sharp
and
quick
feedback
on
the
results
(Nelson
1999).
Well-‐defined
and
controlled
experimental
probes
require
isolation
the
technology
from
its
surroundings.
of
Experimentation
often
uses
simplified
versions
(models)
of
the
object
and
environment
to
be
tested.
Using
a
model
in
experimentation
is
a
way
of
controlling
some
aspects
of
reality
that
would
affect
the
experiment,
in
order
to
simplify
analysis
of
the
results.
The
ability
to
perform
exploratory
activities
that
would
not
otherwise
be
possible
in
real
life
is
a
key
factor
supporting
rapid
knowledge
advances.
21
22. The Diffusion of Science-Based Research
Scientifically
Based
Research:
research
that
is
guided
and
informed
by
a
science
which
has
reached
the
predictive
stage.
Only
science
in
the
predictive
stage
provides
results,
which
are
usable
immediately
to
advance
technological
knowledge
(Kline
and
Rosenberg
1986)
Some
industrial
sectors
have
used
for
a
long
time
scientific
approaches
to
create
knowledge
(electricity,
chemicals)
(Rosenberg
1992).
Yet
most
major
technological
breakthroughs
were
not
directly
based
on
science.
It
has
been
the
slow
expansion
of
the
model
of
science
illuminating
technology
that
has
spawned
innovation
in
sectors
where
scientific
research
rarely
or
never
resulted
in
innovation.
22
23. The Diffusion of Science-Based Research
A
scientific
approach
contributes
to
innovation
in
three
different
ways
Provides
a
more
systema;c
and
effec;ve
base
for
discovery
and
innova;on.
Allows
for
beIer
control
(quality,
impact,
regula;on)
of
the
new
products
and
processes
introduced.
May
be
at
the
origin
of
en;rely
new
products
or
processes.
23
24. The Diffusion of
Science-Based Research
These
3
scientific
approaches
seem
to
conquer
new
ground
all
the
time,
even
those
sectors
that
appear
a
priori
to
resist
them.
Drug
discovery
is
a
good
example
of
a
domain
that
has
recently
been
characterized
by
a
shift
from
a
random
approach
through
large-‐scale
screening
toward
a
more
science-‐guided
approach
relying
on
knowledge
of
the
biological
basis
of
a
disease
to
frame
a
research
strategy.
24
25. The Diffusion of
Science-Based Research
“Double-‐blinding
method”
in
the
health
and
pharmaceu%cal
sector,
This
method,
reduces
the
risk
that
wishful
thinking
or
other
poten;al
biases
may
influence
the
outcome.
Randomized
controlled
trial
or
randomized
field
trial
is
the
kind
of
scien%fic
method
offering
a
large
poten%al
to
generate
scien%fic
knowledge
and
robust
evidences
on
a
broad
range
of
topics
in
various
fields
of
social
and
educa%onal
research
(Fitz-‐Gibbon
2001)
25
26. The Diffusion of
Science-Based Research
The
cons;tu;on
of
scien;fic
knowledge
bases
directly
useful
to
innova;on,
in
most
sectors.
The
idea
is
not
to
rehabilitate
the
old
linear,
so-‐called
“science
push”
innova%on
model,
but
to
grasp
the
structure
of
knowledge
systems
characterizing
areas
with
the
biggest
advances
in
knowledge
and
know-‐how.
Research
Developm
ent
Productio
n
Marketing
26
27. The Diffusion of
Science-Based Research
The
connection
of
scientific
research
to
innovation
has
two
distinct
forms:
First,
scientific
knowledge
production
upstream
from
industrial
sectors
allows
more
effective
innovative
research
that
escapes
from
empiricism.
•
For
example,
knowledge
of
the
properties
of
transition
of
certain
materials
renews
innovation
in
the
adhesive
sector.
Second,
the
appearance
within
the
firm
itself
of
scientific
investigation
tools.
• For
example,
in
the
automotive
sector
fast
and
inexpensive
simulations
enable
massive
and
repid
experimentation
required
for
developing
complex
safety
devices.
(Thomke
2001,
75).
27
28. The Diffusion of
Science-Based Research
These
different
developments
all
point
to
the
idea
that
any
research
problem
warrants
an
effort
at
collecting
scientific
data,
and
that
appropriate
forms
of
experimentation
are
necessary
and
most
often
possible.
As
shown
by
K.
Smith
(2000),
one
of
the
features
of
the
knowledge
economy
is
that
many
industries
are
now
firmly
based
on
complex
scientific
knowledge.
28
29. Research Collaboration
Rationales
of
collabration:
ü Sharing
research
costs
ü Avoiding
duplicative
projects
ü Creating
larger
pools
of
knowledge
ü Which
in
turn
generate
greater
variances
from
which
more
promising
avenues
of
research
can
be
selected
ü The
economic
gains
to
be
generated
from
division
of
labor
in
research
activities.
Those
rationales
still
apply
for
the
collaboration
developed
in
the
domain
of
basic
research.
29
30. Research Collaboration
Example,
Genom
project
contortia
Taking
advantage
from
different
teams’
specializations
and
to
combine
them
Consortia
are
set
up
to
put
together
a
large
enough
collection
of
samples
in
order
to
produce
knowledge
of
a
better
quality,
or
knowledge
which
could
not
be
obtained
otherwise.
30
31. Increasing Returns in the Production of
Knowledge
Various
Forms
of
Complementarity
Many
forms
of
complementarity
between
elements
of
knowledge
are
at
the
base
of
knowledge
production.
These
complementarities
have
been
studied
extensively
in
the
fields
of
technological
knowledge
(Maunoury
1972;
Gille
1978)
and
scientific
knowledge
(David,
Mowery,
and
Steinmueller
1992;
Rosenberg
1992).
Everywhere,
transfers,
transpositions,
and
new
combinations
allow
knowledge
to
advance.
31
32. Increasing Returns in the Production of
Knowledge
Increasing
Returns:
This
no;on
of
complementarity
in
knowledge
produc;on
is
a
way
of
saying
that
I
do
not
share
the
argument
that
exploita%on
of
a
knowledge
field
is
governed
by
the
law
of
decreasing
returns
that
applies
in
the
world
of
exhaus%ble
resources.
In
terms
of
that
law,
the
more
one
invents
the
less
there
remains
to
invent,
so
that
it
is
necessary
to
devote
more
resources
to
obtain
a
result
at
best
equivalent
to
past
achievements.
32
34. Increasing
Returns
in
the
Production
of
Knowledge
There
are
limits
to
the
effect
of
complementarities
and
indivisibilities;
knowledge
production
can
enter
into
a
zone
of
decreasing
returns.
Basic
Research
(Creation
of
generic
knowledge)
Trigger
Decreasing
returns
Push
Shift
in
the
productive
function
Constant
increase
in
research
activity,
without
moving
too
deeply
into
the
domain
of
decreasing
returns
Everything
depends
on
the
ar;cula;on
and
balance
between
pure
basic
research
and
34
applied
research
and
between
public-‐sector
and
private
sector
research.
35. Learning-by-doing
• Learning-‐by-‐doing
as
a
“joint”
activity
related
to
both
production
and
use
• Learning-‐by-‐doing
is
a
form
that
is
related
to
manufacturing
(and/or
utilization)
• It
leads
many
kinds
of
productivity
improvements
• Productive
experiences
(the
accumulation
of
doing)
• Improvement
of
productive
performance
35
36. Learning-by-doing
• “The
unit
cost
of
manufactured
good
production
tends
to
decline
significantly
as
more
are
produced”
• This
phenomenon
was
first
observed
in
the
aircraft
industry
• This
systematic
relationship
is
shown
by
Arrow’s
theory
of
endogenous
technical
change
• Productive
performance
is
increased
by
productive
experience
and
improvements
• Learning-‐by-‐doing
should
not
be
confused
with
incremental
innovation
36
37. Learning-by-doing
• Learning-‐by-‐doing
generates
only
technological
or
organizational
increments
• Most
incremental
innovations
are
not
produced
only
through
learning-‐by
doing
mechanism
• Idea
of
learning
as
a
joint
activity
has
been
effectively
developed
by
Arrow
who
said:
“
«The
motivation
for
engaging
in
the
activity
is
the
physical
output,
but
there
is
an
additional
gain
which
may
be
relatively
small
in
information
yet
which
reduces
the
cost
of
further
production.»
37
38. Learning as experimentation doing
production
• Horndhall
effect:
based
on
repetition
and
incremental
development
of
expertise
• By
repeating
a
task,
one
becomes
more
effective
in
executing
that
task.
• Another
level
of
learning
is
“explicitly
cognitive”
it
consist
of
online
experiments.
• This
learning
is
based
on
an
experimental
concept,
where
data
is
collected
so
that
the
best
strategy
or
better
design
for
the
future.
38
39. An example for online
experiments
Adam
Smith
mentions
a
little
boy
who
repeatedly
opens
and
closes
the
valve
between
a
boiler
and
a
cylinder,
and
who
thus
discovers
a
device
enabling
the
valve
to
open
and
close
automatically:
“One
of
the
greatest
improvements
that
has
been
made
upon
this
machine,
since
it
was
first
invented,
was
in
this
manner
the
discovery
of
a
boy
who
wanted
to
save
his
own
labour.”
Repeated
Action
Experimental
Learning
More
effective
way
of
doing
39
40. Learning
as
experimentation
doing
production
The
importance
of
experimental
learning
depends
on
the
nature
of
the
activity:
• There
are
high-‐risk
activities
in
which
the
agents
have
to
limit
their
experiments
• since
they
could
carry
out
their
“normal
performance”
that
has
to
be
achieved.
Airline
pilots
or
surgeons
cannot
learn
in
this
way
• By
contrast,
a
teacher
can
carry
out
educational
experiments
• A
craftsman
can
look
for
new
solutions
to
a
particular
problem
during
the
production
process.
40
41. Users at Knowledge Production
Nathan
Rosenberg
emphasizes
learning-‐by-‐
doing
related
to
the
use
of
a
product
or
process:
• using
generates
problems;
problem-‐solving
capacities
are
opened
and
learning
occurs.
• Faced
with
new
and
unexpected
local
situations,
users
have
to
solve
problems,
thus
in
a
position
to
teach
and
inform
those
who
design
systems.
41
42. Learning-by-using
Learning-‐by-‐using
process
has
two
aspects
Final
users
learn
how
to
use
the
product
This
learning
process
can
be
extremely
important
when
use
of
the
product
involves
complex
tasks,
including
maintenance,
operating
procedures,
and
optimal
control.
Final
users
learn
about
the
performance
characteristics
of
the
product
which
are
highly
uncertain
before
the
product
has
been
used
for
a
long
period.
This
improved
understanding
of
the
relationship
between
specific
design
and
performance.
The
feedback
loops
in
the
development
stage
leading
to
some
kind
of
optimal
design
after
many
repetition
are
crucial.
In
this
case,
when
learning-‐by-‐using
results
in
design
modification,
Rosenberg
uses
the
notion
of
embodied
knowledge.
42
43. Learning-by-using
In
innovation
activities
q the
user
will
be
motivated
to
find
a
solution
that
will
fit
exactly
with
his
or
her
specific
needs
and
circumstances.
There
is
a
subjective
case
at
modify
process.
q Users
in
a
very
broad
sense
acquire
a
certain
kind
of
knowledge
that
is
particular
to
a
specific
site
and/or
usage.
This
is
the
case
for
the
user
of
a
machine
tool
or
a
medical
instrument
and
for
the
“user”
of
a
valley
or
beach
q the
impact
of
“sticky”
knowledge
when
knowledge
is
costly
to
transfer
(e.g.,
knowledge
about
some
particular
circumstances
of
the
user),
the
position
of
problem
solving
activity
can
shift
from
supplier
to
user.
43
44. Maximizing learning potential
First,
in
a
“doing”
context,
maximizing
the
learning
benefit
requires
the
addition
of
instrumentation
in
order
to
take
advantage
of
observational
opportunities
on
the
production
line.
Second,
organizational
design
matters.
Extreme
technical
specialization
is
of
course
damaging
to
cognitive
learning.
Ø Practice-‐based
learning
environment.
(Taylorist
and
Fordist
divisions
of
labor)
Ø The
design
of
fault-‐tolerant
organizations,
thanks
to
fault-‐tolerant
organizational
designs,
errors
and
failures
are
not
result
in
totally
blocking
the
system.
(more
robust,
less
dependent)
Third,
it
is
important
to
create
special
incentive
structures
and
organizational
forms,
Ø to
support
learners
and
encourage
them
to
reveal
new
knowledge
(acquired
by
doing)
Ø to
create
documents
and
thus
generate
knowledge
objects,
and
to
memorize
and
share
that
knowledge.
44
45. The Coordination Model of
Knowledge Production
• Complex
coordination
problems
produce
“integrative
knowledge”
• Norms,
standards,
infratechnologies,
common
product
development
platforms
• integrative
knowledge:
– compatibility,
interoperability,
interconnectivity
between
subsystems
– exploitation
external
network
• Collaboration
in
Knowledge
production,
cannot
be
explained
only
by
economics
of
R&D
• The
traditional
solution
relied
on
vertical
integration
• changing
outsourcing
and
supply
management
• requiring
strong
coordination
mechnanisms
45
46. Innovation in Knowledge
Economy
There
are
three
models
for
innovation
in
knowledge
economy:
• The
first
is
related
to
scientific
nature
of
research
methods
• Secondly,
users’
engagement
which
is
based
on
knowledge
production
is
vital
to
understand
role
of
it
• Thirdly,
increasing
complexity
and
modularity
of
industry
creates
integrative
knowledge
46
47. Three Critical Models of Innovation
Model
1
Model
2
Innovative
Opportunities
Scientific
developments
Critical
Relations,
Crucial
Organizations
Universities-‐
industries,
startups
User
needs
and
Problems
capabilities
raised
by
integration
in
complex
technological
systems
User-‐producers
Architect
and
User
module
communities
designers,
strategic
and
standardization
consortia
47
Table
3.3
Model
3