This document discusses the limitations of traditional wikis for enterprise knowledge management and how semantic technologies can help address these issues. It describes zAgile's Wikidsmart plugin for Atlassian Confluence, which adds semantic capabilities like structured templates, faceted search, and integration with external data sources to enable more effective knowledge sharing across teams and departments.
2.
Summary .....................................................................................................................3
Introduction.................................................................................................................4
A
Few
Typical
Problems
with
Wikis ..............................................................................4
The
Promise
of
Semantic
Wikis ....................................................................................6
zAgile’s
Approach
to
Semantic
Enablement
of
Wikis ....................................................7
Smart
‘Semantic’
Templates.................................................................................................................................. 7
Semantic
Macros ........................................................................................................................................................ 9
Faceted
search ......................................................................................................................................................... 10
SPARQL
Query.......................................................................................................................................................... 12
Machine-‐based
Annotation................................................................................................................................. 13
Machine-‐Readable
Content ................................................................................................................................ 14
Wikidsmart
Architecture ............................................................................................15
zAgile’s
Semantic
Repository............................................................................................................................. 15
zAgile’s
Semantic
Interface
Layer
(zSLayer) .............................................................................................. 15
zAgile’s
RPC
Server ................................................................................................................................................ 16
zAgile’s
Semantic
Plugin
for
Confluence
(Wikidsmart) ......................................................................... 16
Conclusion .................................................................................................................17
copyright
zAgile
Inc.,
2011
2
3.
Summary
Wikis
have
become
entrenched
in
the
enterprise
as
the
most
common
‘groupware’
application
for
collaboration
amongst
individuals
and
teams.
They
are
easy
to
acquire,
easy
to
setup,
and
easy
to
use
for
capturing
ad
hoc
content
that
teams
desire
to
share
amongst
themselves.
It
is
not
unusual
to
find
dozens
and
sometimes
even
hundreds
of
wiki
instances
within
enterprises.
Whether
it
is
Human
Resources,
Sales,
Marketing,
or
IT,
teams
find
ways
of
leveraging
the
convenience
of
wikis
to
publish
and
share
information
with
each
other.
While
wikis
permeate
the
enterprise,
the
convenience
of
capturing
information,
the
ad
hoc
nature
of
this
information
and
its
lack
of
structure
also
contribute
to
the
general
failure
of
the
wiki
as
an
effective
information
collaboration
tool.
As
the
published
content
grows
into
hundreds
and
thousands
of
pages,
it
becomes
increasingly
difficult
to
organize,
maintain,
access,
and
search.
It
quickly
loses
credibility
and
becomes
stale.
Since
there
is
no
consistency
or
discipline
with
which
information
must
be
published
or
organized,
different
groups
within
an
organization
may
experience
varying
degrees
of
success
with
their
wiki.
Traditional
wikis
also
present
additional
limitations
that
often
constrain
their
usage
as
an
enterprise
groupware
application.
These
constraints
are
not
a
critique
of
the
inherent
design
of
the
wiki
since
it
was
intended
as
a
simple
tool
for
allowing
people
to
capture
information.
We
discuss
them
mostly
in
the
context
of
the
evolution
of
the
wiki
in
the
enterprise.
For
example,
the
page-‐paradigm
for
representing
content
or
information
does
not
support
‘formal
type’
declaration
of
specific
content
in
a
page
or
capturing
any
classification
or
taxonomic
relationship
between
pages
of
information.
Rather,
it
restricts
the
organization
to
simple
page-‐level
hierarchies.
In
multi-‐dimensional
taxonomies,
it
should
even
be
possible
for
a
page
to
be
represented
in
more
than
one
classification
scheme.
And
what
about
inheritance
where
information
in
a
page
may
draw
from
that
already
represented
in
the
parent
page?
or
somewhere
else
external
to
the
wiki?
Many
commercial
wikis
support
information
integration
from
external
sources
through
mashups.
However,
the
context
of
such
integration
is
implied
based
on
its
location
rather
than
through
any
formal
interpretable
relationship
with
the
page
where
it
renders.
There
is
no
inherent
capability
of
dynamically
integrating
content
from
external
applications
based
upon
page-‐level
context.
Wikis
do
not
support
any
federation
of
content.
When
there
are
hundreds
of
wikis
in
an
enterprise,
there
is
no
mechanism
for
sharing
information
across
them.
Wikis
in
such
scenarios
represent
team-‐level
and
department-‐level
information
silos.
copyright
zAgile
Inc.,
2011
3
4.
In
spite
of
these
shortcomings,
wikis
have
the
potential
to
become
an
Information
or
Knowledge
Portal
within
an
enterprise
and
its
users
demand
it.
The
emergence
of
semantic
technologies,
particularly
as
applied
to
wikis
(aka
Semantic
Wikis)
has
gone
a
long
way
to
address
these
gaps.
Here,
we
describe
the
current
limitations
of
wikis
and
how
zAgile’s
Wikidsmart
semantic
technology
provides
ways
of
overcoming
them,
specifically
in
the
context
of
Atlassian’s
Confluence
enterprise
wiki.
Introduction
Wikis
have
become
entrenched
in
the
enterprise
as
the
most
common
‘groupware’
application
for
collaboration
amongst
individuals
and
teams.
They
are
easy
to
acquire,
easy
to
setup,
and
easy
to
use
for
capturing
ad
hoc
content
that
teams
desire
to
share
amongst
themselves.
It
is
not
unusual
to
find
dozens
and
sometimes
even
hundreds
of
wiki
instances
within
enterprises.
Whether
it
is
Human
Resources,
Sales,
Marketing,
or
IT,
teams
across
the
organization
find
ways
of
leveraging
the
convenience
of
wikis
to
publish
and
share
information
with
each
other.
While
wikis
permeate
the
enterprise,
the
convenience
of
capturing
information,
the
ad
hoc
nature
of
this
information
and
its
lack
of
structure
also
contribute
to
the
failure
of
the
wiki
as
an
effective
information
collaboration
tool.
As
the
published
content
grows
into
hundreds
and
thousands
of
pages,
it
becomes
increasingly
difficult
to
organize,
maintain,
access,
and
search.
It
quickly
loses
credibility
and
becomes
stale.
Since
there
is
no
consistency
or
discipline
with
which
information
must
be
published
or
organized,
different
groups
within
an
organization
may
experience
varying
degrees
of
success
with
their
wiki.
A
Few
Typical
Problems
with
Wikis
Some
of
the
key
problems
that
users
face
with
enterprise
wikis
can
be
categorized
into
the
following
major
areas:
1. Content
Organization
is
limited
to
mostly
page-‐level
hierarchies,
quite
analogous
to
binders
on
a
shelf.
Designing
and
maintaining
the
page
hierarchies,
cross-‐referencing
pages
across
major
sections,
tracking
and
updating
them
with
the
most
current
information
and
maintaining
cross-‐reference
links—all
require
significant
manual
processing.
For
example,
in
Confluence,
the
most
typical
method
of
content
organization
is
through
the
use
of
Spaces,
which
may
imply
or
mimic
some
topic,
team
or
department.
The
organization
of
a
space
or
its
contents
is
arbitrary.
Any
type
of
organization
requires
significant
up
front
investment,
occasionally
leveraging
the
consulting
services
of
knowledge
management
experts.
Conversely,
if
the
organization
of
wiki
content
structure
is
ad
hoc,
then
the
success
of
its
deployment
copyright
zAgile
Inc.,
2011
4
5. declines
as
the
usage
and
adoption
grows.
2. Content
Consistency
or
Integrity
can
only
be
achieved
through
diligent
effort.
Constantly
maintaining
and
updating
the
same
information
in
multiple
areas
of
the
wiki
is
often
unrealistic.
As
a
result,
the
wiki
content
quickly
becomes
outdated
and
unreliable.
There
are
some
shortcuts
that
allow
for
the
inclusion
of
a
page
in
another
-‐
but
this
forces
the
reusable
section
to
be
developed
as
a
separate
page.
While
content
management
is
certainly
the
responsibility
of
each
department
or
team,
the
need
to
maintain
its
integrity
and
freshness
varies
with
the
dedication
and
diligence
afforded
to
any
given
team.
Hence,
the
lack
of
consistency
in
the
values
of
such
content
across
the
enterprise.
3.
Content
Categorization
may
be
implied
in
the
page
hierarchy
(or
Confluence
Spaces)
but
there
is
no
inherent
formal
structure
to
support
it.
Does
a
page
depict
a
requirement,
a
process,
profile
of
a
team
member,
an
invoice,
a
customer
account,
information
about
business
partners,
or
instructions
for
a
holiday
party??
There
isn’t
a
way
to
structure
this
information
consistently
and
more
importantly—in
a
reusable
and
machine-‐readable
format.
4.
Content
Attribution
reflects
some
information
or
knowledge
about
a
page,
i.e.
what
is
it
describing?
What
are
its
relationships
with
other
information
concepts?
You
may
be
able
to
glean
that
off
of
the
page
title,
its
place
in
the
page
hierarchy,
its
labels
or
its
Space
container—but
the
page
itself
does
not
contain
any
attribute-‐level
information.
Wikis
typically
provide
some
page-‐level
metadata,
such
as
page
author,
creation
and
modification
timestamp,
and
tags.
However,
they
lack
the
ability
to
capture
formal
attributes
associated
with
the
page
content.
For
example,
if
a
page
represents
a
customer
account,
then
there
is
no
easy
to
way
to
provide
any
attributes
such
as
the
relationship
of
the
account
with
a
contact,
department,
or
industry
domain.
5.
Information
Access
may
be
accomplished
via
searching
the
content
or
page
labels
for
specific
matches,
navigating
through
the
space
and
page
hierarchies
or
looking
for
a
specific
page
title
or
a
URL.
However,
wildcard
matches
to
character
strings
in
content
are
not
often
what
enterprise
users
desire.
They
are
looking
for
a
specific
topic,
such
as
information
related
to
a
project,
document,
bug
or
account.
Furthermore,
since
there
is
no
support
for
formal
attribution,
there
is
no
way
to
search
the
context
of
the
page
itself,
for
example,
all
pages
relating
to
a
customer
account,
invoice,
project
or
release.
Similarly,
all
pages
reviewed
by
J.
Smith
before
October
10,
2011
associated
with
Wikidsmart
project.
This
limitation
results
in
imprecise
search
and
significant
amount
of
effort
on
the
part
of
the
users
to
locate
relevant
information
contained
in
wiki
pages.
Of
course,
there
is
no
way
to
query
for
specific
information
on
a
page.
For
example,
if
a
page
contains
a
list
of
use
cases
pertaining
to
a
feature
or
contacts
for
an
account,
it
isn’t
possible
to
access
a
specific
use
case
or
contact
information.
6.
Information
Integration
with
other
applications
and
vice
versa
is
mostly
limited
to
copyright
zAgile
Inc.,
2011
5
6. data
sharing
via
RSS
feeds
and
mashups,
with
neither
offering
any
formal
context
or
relationship
to
the
page.
If
you
are
capturing
information
about
product
requirements
in
Confluence
then
you
may
also
want
to
integrate
them
with
corresponding
test
cases,
tasks,
and
checkins.
And
you
may
want
to
do
it
both
ways,
i.e.
integrate
information
from
other
tools
into
Confluence
pages
but
also
pull
some
information
from
Confluence
into
other
tools.
However,
other
than
page,
space
and
section-‐level
URLs,
there
is
no
other
mechanism
for
such
integration
because
the
wiki
conventionally
does
not
support
machine-‐readable
formats
for
the
content
that
it
captures.
7.
Static
vs
Dynamic
Content.
The
lack
of
integration
with
other
applications,
and
the
lack
of
attribute
level
support
limits
the
wiki
to
a
static
information
or
knowledge
repository.
If
information
changes
on
one
page
that
change
isn’t
automatically
reflected
everywhere
else
it
may
also
appear
unless
the
entire
page
is
included
in
referring
pages.
It
has
to
be
manually
updated.
In
the
absence
of
such
updates,
the
content
quickly
becomes
inconsistent
and
unreliable.
8.
Content
Federation
can
address
the
problems
many
organizations
face
due
to
the
presence
of
dozens
and
hundreds
of
departmental
wikis.
By
participating
in
a
federated
architecture,
content
becomes
easily
shareable
across
wikis
and
becomes
more
meaningful
across
the
enterprise.
Teams
often
struggle
with
keeping
track
of
what
information
to
capture
in
which
wiki
and
how
to
make
it
shareable.
Of
course,
searching
across
wikis
is
not
possible.
The
Promise
of
Semantic
Wikis
Over
the
past
decade,
there
have
been
a
number
of
initiatives
undertaken
to
tackle
some
combinations
of
the
wiki
limitations
outlined
above.
The
common
focus
is
to
retain
the
ease
of
use
and
collaborative
nature
of
the
wiki
while
allowing
for
the
creation
of
‘semi-‐structured’
content.
Semi-‐structured
here
is
mostly
a
reference
to
the
ease
of
authorship
of
the
content
while
supporting
formal
representation
of
its
semantics,
which
may
be
its
type
or
category,
position
in
the
hierarchy,
inherited
and
direct
attributes,
and
relationships
to
other
objects.
In
these
efforts,
it
is
also
assumed
that
the
‘semi-‐structured’
content
would
be
machine-‐interpretable,
hence
easy
to
share
and
access
across
wiki
pages
and
even
across
applications.
The
goal
of
the
semantic
wiki
is
to
provide
support
for
formal
categorization
and
attribution
of
content.
The
technologies
and
features
vary
with
implementations
but
these,
along
with
the
ability
to
publish
content
that
is
machine-‐readable,
are
clearly
some
of
the
obvious
characteristics
(based
on
the
discussion
above)
that
semantic
technologies
in
wikis
are
expected
to
support.
However
semantic
technologies
provide
for
much
more
than
these
capabilities,
depending
upon
the
implementation.
We
will
discuss
them
in
the
context
of
zAgile’s
Wikidsmart
semantic
extension
for
Confluence
later
in
this
section.
copyright
zAgile
Inc.,
2011
6
7.
zAgile’s
Approach
to
Semantic
Enablement
of
Wikis
zAgile’s
technologies
enable
semantic
capabilities
in
popular
best-‐of-‐class
wikis,
such
as
Confluence,
to
address
the
natural
limitations
of
wikis
discussed
earlier.
It
also
brings
more
power
to
the
wiki
in
its
role
as
an
enterprise
collaboration
application
and
knowledge
portal.
The
semantic
extension,
available
via
Wikidsmart,
turns
Confluence
into
one
of
many
sources
of
semantically
structured,
shareable
content.
This
provides
an
effective
mechanism
for
creating
‘knowledge’
out
of
the
‘relatively
unstructured’
wiki
pages,
while
also
allowing
integration
of
the
wiki
content
with
other
applications.
Furthermore,
this
integration
occurs
both
ways,
i.e.
specific,
typed,
and
semantically
relevant
wiki
content
is
readily
accessible
to
external
applications,
and
Confluence
is
also
able
to
contextually
incorporate
structured
data
from
external
applications
into
its
pages
-‐
to
render
itself
as
a
knowledge
portal.
zAgile’s
Wikidsmart
allows
users
to
leverage
their
existing
Confluence-‐based
content
repositories.
It
allows
users
to
easily
capture
semantic
annotations
of
existing
content
as
well
as
create
new
content
using
semantic
templates
and
semantic
forms.
These
extensions
can
also
be
developed
for
other
commercial
or
open
source
wikis,
provided
that
the
wiki
supports
a
mechanism
for
development
of
user
extensions
and
form
templates.
zAgile’s
approach
also
separates
the
semantic
repository
from
the
wiki
content
so
that
the
wiki
functions
not
as
the
central
and
sole
repository
for
both
unstructured
content
and
semantic
annotations
but
as
one
of
many
application
that
contributes
semantically
relevant
data
to
a
central
repository
accessible
to
all
applications.
This
further
allows
users
to
have
distributed
and/or
federated
semantic
databases.
And
finally,
because
the
semantic
repository
is
accessible
to
all
applications
including
the
wiki
using
the
same
interfaces,
it
facilitates
two-‐way
integration
between
wiki-‐based
content
and
external
applications
that
are
also
creators
and
consumers
of
related
information.
This
level
of
integration
not
only
allows
the
wiki
to
share
common
information
with
other
application
but
also
to
extend
it,
thereby
creating
a
richer
knowledge
repository.
This
level
of
semantic
integration
between
the
wiki
and
other
applications
becomes
a
viable
framework
for
unifying
an
environment
of
disparate
and
heterogeneous
applications,
content
and
processes.
zAgile’s
solution
for
semantic
enablement
of
wikis
consists
of
the
following
high-‐
level
functional
components:
Smart
‘Semantic’
Templates
Through
the
use
of
customizable
form-‐based
page
templates,
Wikidsmart
provides
an
easy
way
for
users
to
create
consistent
and
semi-‐structured
content.
The
elements
of
any
such
form
are
mapped
directly
to
and
captured
in
the
underlying
copyright
zAgile
Inc.,
2011
7
8.
metamodel.
This
allows
for
each
element
on
the
page
to
represent
a
formal
semantic
concept
or
attribute.
For
example,
if
the
page
represents
a
Requirements
Document,
then
another
element
on
the
page
may
represent
a
related
Requirement
Item,
related
Project,
the
Author,
Stakeholder,
or
Task
assigned
to
an
individual
Requirement
Item.
While
leveraging
the
ease
of
the
wiki-‐based
paradigm
for
user-‐
based
content
creation,
the
templates
provide
powerful
medium
for
the
creation
of
semantically
structured
content.
Since
this
content
is
captured
in
a
centralized
repository,
it
is
easily
accessible
to
other
applications.
These
templates
also
contribute
significantly
to
overall
wiki
adoption,
since
they
minimize
user-‐level
page
formatting
(via
wiki
markup)
and
result
in
consistent
page
layouts.
An
example
of
such
a
form
is
illustrated
below
for
creating
a
test
case
as
part
of
a
collection
of
a
test
suite.
The
test
case
has
elements,
which
formally
link
it
to
requirements
(Confluence),
components
(JIRA)
and
test
execution
tasks
(JIRA).
The
list
of
Related
Components,
are
derived
from
the
JIRA
project
associated
with
the
test
suite
(represented
by
the
page).
The
Related
Requirement
list
is
obtained
from
the
feature
linked
to
the
test
suite.
Similarly,
the
following
screenshot
shows
how
a
form-‐based
template
in
Confluence
is
used
to
capture
structured
information
related
to
a
medical
device.
copyright
zAgile
Inc.,
2011
8
9.
The
value
of
the
template-‐based
forms
is
further
enhanced
through
field-‐level
validation
that
may
be
added
using
macro-‐level
parameters
in
the
templates.
The
validation
may
also
be
tied
to
workflow
states
and
roles.
Thus
the
forms
can
almost
behave
like
enterprise
applications,
while
still
retaining
the
wiki
page
paradigm.
Semantic
Macros
zAgile’s
Wikidsmart
provides
macros
that
may
be
used
alongside
wiki
macros
and
markup
to
interact
with
the
semantic
database
and
retrieve
contextual
information
inline
within
the
page
content.
These
macros
provide
a
number
of
capabilities
that
collectively
support
the
implementation
of
knowledge
management
solutions
using
wikis.
The
following
are
a
few
of
the
key
capabilities
provided
via
these
macros,
at
the
page
or
paragraph
level:
Categorization—to
assign
formal
category
to
the
content.
Categorization
allows
you
to
identify
a
page
or
section
to
represent
a
category,
such
as
Requirement,
Hip
Implant,
Invoice,
or
IT
service
request.
Categories
may
represent
hierarchical
structures
and
formal
taxonomies.
Therefore,
it
is
possible
to
have
a
page
(or
section)
that
represents
a
structure
such
as
the
following:
Medical
Device->Implant->Hip
Implant->Primary
Hip
Implant->Primary
Hip
Implant
(cemented)
A
page
or
section
may
also
belong
to
multiple
categories,
as
a
result
of
inference,
based
on
its
properties.
Attribution—to
associate
the
content
with
formal
attributes
that
correspond
to
the
definition
of
the
Category
in
the
metamodel
or
ontology.
These
attributes
or
copyright
zAgile
Inc.,
2011
9
10.
properties
may
be
created
or
associated
(if
they
exist).
For
example,
the
priority
associated
with
a
requirement,
the
surface
coating
of
a
hip
implant,
or
description
of
an
invoice.
Through
categorization
and
attribution,
you
can
create
formal
relationships
between
pages
or
sections
in
the
wiki
that
represent
complex
logical
hierarchies
and
part-‐whole
relationships,
without
the
constraint
of
the
physical
location
of
any
of
the
pages.
For
example,
a
page
may
be
a
Sub
Document
to
one
or
many
Documents
in
other
areas
in
the
wiki.
Such
cross-‐referencing
is
automatic,
dynamic
and
independent
of
the
physical
location
of
the
content.
It
also
does
not
impose
any
tedious
maintenance
overhead.
Reference—for
the
inclusion,
by
contextual
reference,
of
information
that
may
exist
elsewhere
in
the
wiki
or
in
an
application
external
to
the
wiki.
For
example,
including
description
and
status
of
a
bug
(logged
in
JIRA)
on
the
corresponding
requirements
page
in
Confluence,
article
summaries
associated
with
an
implant
offered
by
a
journal,
and
vendor
information
related
to
an
invoice
(from
an
accounting
application).
This
capability
of
being
able
to
embed
references
in
content
allows
for
the
reference
to
be
contextual
and
dynamic,
i.e.
if
the
information
changes
at
the
source,
then
its
references
will
be
automatically
refreshed.
It
eliminates
the
need
for
manually
updating
information
in
wiki
pages
that
is
derived
from
outside
of
those
pages,
either
from
other
pages
in
the
wiki
or
from
external
applications.
It
improves
the
integrity
and
reliability
of
the
overall
content.
External
Integrations—for
two-‐way
direct
and
‘contextual’
integration
with
external
applications.
For
example,
creating
a
JIRA
approval
task
from
within
a
requirement
defined
in
a
Confluence
page.
This
level
of
integration
automatically
creates
a
two-‐
way
link
between
the
task
and
the
requirement
for
ongoing
traceability.
It
provides
the
needed
context,
which
is
missing
if
task-‐related
information
were
simply
pasted
into
that
page.
Similarly,
a
template-‐based
Confluence
page
may
be
created
from
within
Salesforce
to
represent
an
account.
This
page
can
be
used
for
collaborative
inputs
related
to
the
account.
Using
some
of
the
capabilities
discussed
above,
this
page
can
also
automatically
display
cases
reported
for
that
account,
internal
resolution
status
of
each
case
and
product
releases,
which
address
specific
issues
raised
on
behalf
of
this
account.
The
page
becomes
the
focal
point
for
collaborative
activities
related
to
the
account.
Faceted
search
zAgile’s
Smart
Search
allows
the
users
to
specify
the
category
of
information
being
searched.
The
search
criterion
is
applied
to
a
specific
category
rather
than
to
all
content
in
the
wiki.
copyright
zAgile
Inc.,
2011
10
11. Since
the
underlying
metamodel
supports
inheritance,
this
category
may
represent
any
level
in
the
taxonomy.
For
example,
a
Functional
Requirement
may
also
be
searched
using
its
parent
category–Requirement
or
other
super
categories
(Abstract
Requirement,
WorkProduct)
in
its
hierarchy.
The
search
returns
a
structured
result
set,
comprising
of
objects
matching
the
category
specified
in
the
search
parameter.
The
result
set
also
contains
known
attributes
and
relationships
of
the
object—across
applications.
For
example,
when
searching
for
a
requirement,
the
result
set
may
contain
its
author,
reviewer,
related
component
and
stakeholder,
as
shown
in
the
example
below.
copyright
zAgile
Inc.,
2011
11
12.
Since
each
category
has
an
associated
and
formal
set
of
attributes,
it
is
also
possible
to
filter
the
search
results
based
on
the
values
in
these
attributes.
The
‘Power
Search’
mode
presents
the
list
of
relevant
attributes
based
upon
the
category
being
searched,
as
shown
in
the
adjacent
screenshot.
Here,
all
the
attributes
for
‘Requirement’
category
are
retrieved
from
the
metamodel
definition.
The
combo
boxes
will
contain
possible
objects
to
which
the
requirement
may
have
a
formal
relationship,
for
example,
an
associated
JIRA
issue
or
the
document
in
which
it
is
described.
And
finally,
search
isn’t
limited
to
just
wiki
content.
Since
the
wiki
is
integrated
into
a
common
information
platform,
search
has
access
to
information
from
all
sources.
This
is
in
contrast
to
the
typical
search
in
a
wiki,
which
is
limited
to
matching
character
strings
against
page
content,
tags
or
titles.
Therefore,
it
is
possible
in
Confluence
to
search
for
specific
projects
or
tasks
defined
in
JIRA,
or
accounts
defined
in
Salesforce.
SPARQL
Query
SPARQL
(an
RDF
query
language),
similar
in
syntax
to
SQL,
support
declarative
queries
against
graph
databases,
such
as
those
implemented
in
zAgile’s
semantic
repository.
SPARQL
support
in
Confluence
via
Wikidsmart
opens
up
a
number
of
possibilities
for
querying
data
from
any
source,
including
externally
published
content,
as
long
as
it
is
published
in
RDF.
This
provides
interesting
opportunities
for
bringing
information
together
in
a
page
from
a
number
of
sources.
The
query
result
set
may
be
combined
with
other
formatting
macros
in
Confluence,
as
shown
below,
to
create
dashboards
that
bring
information
together
from
a
variety
of
sources.
copyright
zAgile
Inc.,
2011
12
13.
This
illustration
above
is
a
section
of
a
dynamically
generated
page
in
Confluence,
comprising
of
a
number
of
SPARQL
queries
and
Confluence
markup
macros,
and
representing
information
related
to
a
JIRA
project
release
(or
Version)
and
its
related
features,
requirements
and
test
cases
defined
in
Confluence.
In
the
above
example,
a
single
query
returns
Features
being
delivered
in
a
Release,
and
associated
Requirements,
approval
status
and
development
tasks.
Machine-‐based
Annotation
Using
Natural
Language
Processing
techniques,
machine-‐based
annotation
of
unstructured
wiki
content
automatically
tags
words
or
phrases
in
a
page
if
they
match
any
references
in
the
semantic
database.
A
mouse
click
on
the
tagged
word
will
identify
its
category,
source,
and
any
other
contextual
information
associated
with
that
term.
This
eliminates
the
need
to
manually
tag
specific
references
in
paragraphs
and
pages
in
the
wiki.
The
annotation
is
dynamic
and
does
not
impact
copyright
zAgile
Inc.,
2011
13
14.
the
original
content.
Examples
of
its
implementation
include
tagging
clinical
terms
in
article
abstracts
in
a
Confluence
page
with
the
pop
up
displaying
associated
procedures,
videos
and
conditions
associated
with
those
terms.
In
the
context
of
software
engineering
lifecycle,
meeting
notes
related
to
a
project
could
be
similarly
annotated.
The
tags
will
automatically
identify
any
references
to
the
project,
its
related
artifacts
or
tasks.
Machine-‐Readable
Content
Linked
Open
Data
(LOD)
is
a
set
of
guidelines
for
publishing
machine-‐readable
content
that
can
be
interpreted
by
external
agents,
including
search
engines.
This
can
be
extremely
valuable
especially
when
publishing
product-‐related
content
to
an
external
audience.
A
number
of
implementations
in
e-‐commerce
(ex:
Best
Buy)
have
successfully
leveraged
this
capability
to
improve
search
engine
optimization
(SEO).
Wikidsmart
supports
Linked
Open
Data
based
content
publishing.
Within
Confluence
pages,
in
non-‐display
mode,
machine-‐readable
content
can
be
automatically
generated
for
any
semantic
categories
represented
on
the
page.
The
example
below
shows
a
Confluence
page
source
in
LOD-‐based
format,
representing
information
related
to
a
medical
device
(ACF
Femoral
Component)
and
the
manufacturer
of
that
device
(Biomet
Inc.).
The
representation
includes
a
number
of
standard
ontologies
including
GoodRelations,
vCard
and
eClassOWL.
copyright
zAgile
Inc.,
2011
14
15.
Wikidsmart
Architecture
The
following
key
components
describe
the
architecture
of
Wikidsmart
and
further
illustrate
the
ways
in
which
it
allows
Confluence
to
become
integrated
with
other
enterprise
applications.
zAgile’s
Semantic
Repository
The
semantic
repository
comprises
of
a
set
of
formal
ontologies
and
metamodels
specific
to
a
domain
of
interest.
Specifically,
the
repository
supports
formal
ontologies
based
on
OWL
(Web
Ontology
Language)
language—a
W3C
specification.
The
ontologies
provide
a
highly
structured
framework
for
the
capture
and
annotation
of
semantically
relevant
data
pushed
from
the
participating
applications.
They
also
facilitate
integration
of
this
data
across
related
metamodels,
as
well
as
allow
for
inferencing
and
reasoning
for
implied
categorizations
and
inheritance
of
attributes.
zAgile’s
Semantic
Interface
Layer
(zSLayer)
The
semantic
interface
layer
provides
wikis
and
other
applications
with
interface
to
this
repository.
It
is
a
middleware
that
resides
between
the
ontology
repository
and
the
client
applications.
It
provides
a
consistent
way
to
interact
with
the
ontology
through
lightweight
serialize-‐able
objects
that
can
be
exchanged
across
the
web.
It
also
maintains
a
Lucene
index
that
is
intended
to
be
a
fast
way
to
search
and
retrieve
individual
information
but
that
is
also
transparent
to
the
client
applications.
copyright
zAgile
Inc.,
2011
15
16.
zSLayer
also
provides
an
option
to
query
the
ontologies
it
handles,
allowing
the
client
application
to
choose
which
ontology
it
wants
to
query
or
if
it
wants
to
use
the
main
merged
ontology
that
holds
all.
Via
connectors,
all
applications
and
consumers
of
the
repository
can
use
a
consistent
API
to
access
the
semantic
repository.
This
layer
also
supports
standard
query
languages
like
SPARQL
which
can
be
embedded
within
wiki
pages
for
querying
and
navigating
the
semantic
graphs
in
the
repository.
zAgile’s
RPC
Server
This
server
provides
a
set
of
XML-‐RPC
methods
for
accessing
zSLayer,
which
applications
(XML-‐
RPC
clients)
can
use
to
query
or
save
semantic
data.
This
server
organizes
and
prepares
the
semantic
data
to
be
readable
by
a
client
application
written
in
any
language.
It
also
supports
that
access
in
JSON
format
by
using
URLs
for
querying
the
repository.
zAgile’s
Semantic
Plugin
for
Confluence
(Wikidsmart)
This
plugin
provides
the
interface
between
Confluence
and
the
zAgile
Semantic
Server.
It
supports
macros
for
creating
templates
and
forms
in
Confluence
for
annotating
wiki
pages.
Templates
are
based
upon
the
ontologies
and
metamodels
defined
in
the
semantic
repository.
They
allow
annotation
of
existing
content
as
well
copyright
zAgile
Inc.,
2011
16
17.
as
creation
of
new
forms
and
pages.
This
plugin
also
supports
macros
for
embedding
SPARQL
queries
within
wiki
pages,
as
discussed
above.
Conclusion
This
paper
highlights
the
power
and
capabilities
of
Wikidsmart
as
it
extends
Confluence
for
deeper
integration
within
the
enterprise
as
a
collaboration
application
and
an
information
portal.
This
level
of
integration
results
from
the
implementation
of
a
metamodel-‐driven
architecture
and
semantic
capabilities
built
on
an
integration
platform
hosted
by
zAgile’s
zCALM
Server.
Wikidsmart
is
a
commercial
open
source
product,
available
on
SourceForge
and
from
zAgile.
For
more
information
on
Wikidsmart,
please
contact
info
at
zAgile.com.
copyright
zAgile
Inc.,
2011
17