The Virtual Immersive Learning (VIL) test bench implements a virtual collaborative immersive environment, capable of integrating natural contexts and typical gestures, which may occur during traditional lectures, enhanced with advanced experimental sessions. The system architecture is described, along with the motivations, and the most significant choices, both hardware and software, adopted for its implementation. The novelty of the approach essentially relies on its capability of embedding functionalities that stem from various research results (mainly carried out within the VICOM national project), and “putting the pieces together” in a well-integrated framework. These features, along with its high portability, good flexibility, and, above all, low cost, make this approach appropriate for educational and training purposes, mainly concerning measurements on telecommunication systems, at universities and research centers, as well as enterprises. Moreover, the methodology can be employed for remote access to and sharing of costly measurement equipment in many different activities. The immersive characteristics of the framework are illustrated, along with performance measurements related to a specific application.
1. Introduction
Virtual Immersive Communications (VICOM) is a national project
funded by the Italian Ministry of Education,
University and Research (MIUR), started in November 2002 and ended in May 2006
(http://www.vicom-project.it). The project goal has been the design of a
communication system's architecture able to provide mobile virtual immersive
services. The architectural framework and its functionalities have been
demonstrated with two service test benches, denoted as Mobility in Immersive
Environment (MIE) and Virtual Immersive Learning (VIL),
respectively. In particular, the VIL test bench implements a virtual
collaborative immersive environment, capable of integrating natural contexts
and typical gestures, which may occur during traditional lectures, enhanced
with advanced experimental sessions. Two training courses have been realized:
the first one was oriented to virtual restoration of paintings, whereas the
second one concerned e-measurement applications, enabling students to remotely
control real devices and instrumentation, located at the National Laboratory
for Multimedia Communications in Naples, Italy, and at WiLab in Bologna,
Italy, respectively.
A 3D virtual reality application allows the real-time
interaction between a lecturer or instructor and students, who are not
physically present in the same classroom. Students were grouped inside a number
of well-equipped classrooms, interconnected through an IP network.
Traditional approaches to Virtual Reality (VR) are based on
complex and relatively expensive devices, such as head-mounted displays (HMDs),
data gloves, and CAVE systems [1]. Instead, the proposed approach to realize
the VIL test bench has leveraged results that were the output of research
activities related to specific work packages of the VICOM project. In
particular, VIL exploits audio and video processing algorithms to realize an
immersive interaction with the virtual class, a specific database to share and
manage all context information, a multimedia board and an embedded haptic interface
to show different approaches to virtual reality applications, hardware/software
architectures specifically designed and realized to control real measurement
instruments and devices (which may also be placed in different laboratories),
and virtual restoration tools to improve the quality of digital reproductions
of paintings.
Accessing remote laboratory instrumentation
and performing experiments, either individually or under the supervision of an
instructor, have become key elements in distance learning and training, not
only in technical disciplines. So, the layout and the output of a demo
laboratory session on a telecommunication measurement experiment (interference
generation and control over a wireless LAN) are also described.
The paper is organized as follows. In Section 2 the required
hardware components are illustrated, while in Section 3 the software system
architecture is presented. Section 4 summarizes some performance results of the
e-measurement software architecture, also in comparison with commercial
solutions. Finally, Sections 5 and 6 discuss an operative example and user
mobility issues, respectively, while in the last section conclusions are drawn.
2. Hardware Components
In the VIL scenario, the generic user reaches a VIL real
classroom and logs in to the system through an accounting phase, to define the
user's profile and know the seat reserved. Then, the lecturer and students
enter the virtual classroom, where they are represented by their avatars, and
reach their own virtual workspace. So, the real-time lecture takes place in a
virtual context-aware environment, where interactions occur in a natural way,
by means of scene analysis systems and immersive input devices. Finally,
lectures are complemented with experimental laboratory sessions, oriented to supervised
telerestoration and cooperative telemeasurements, exploiting specialized
virtual laboratory software.
The proposed scenario has been realized in order to be
compliant with the economical resources of the VICOM project. To this aim, all
useful research results from project work packages have been embedded into the
system, rather than relying on very expensive hardware available on the market
for data acquisition and visualization in immersive environments.
The fulfillment of the VIL goals has required the
specification and the acquisition of the equipment of some enhanced classrooms,
through which lecturers and students can take part in the immersive lecture.
These classrooms were interconnected through the CNIT national network, mainly
based on a satellite platform (DVB-RCS-like [2]), allowing the bidirectional
interconnection of a large part of CNIT research units and laboratories. The
network, provided by Eutelsat, operated in Skyplex technology over the Ka band (HotBird6
Satellite) [3], by providing an overall satellite bandwidth of 2 Mbps, shared
among the active earth stations. In particular, such network connected some CNIT
and CNR (National Research Council) laboratories in Naples, Bologna, Florence,
Genoa, and Pisa, (Italy) which have taken part in the development of the VIL test bench.
Since different types of enhanced classrooms are possible,
each center can choose the specific test bench components to highlight. A fully
equipped classroom would include the hardware components explained in the
following, to list all significant functionalities.
Video rendering systems. For the students' class, we have selected a
visualization system composed by a
projection screen, two linear polarization filters, two XGA projectors, and
passive glasses (see Figure 1). An autostereoscopic display is used for the
lecturer. Both systems must be equipped with a professional graphics
workstation.
Audio rendering systems. For the
students' class we have chosen wireless headphones, while normal loudspeakers
are sufficient for the lecturer.
Input devices (see Figure 2). Any user can interact with the Graphical User Interface (GUI)
through input devices providing different immersion sensations. The user can
choose a simple mouse, a 3D mouse with six degrees of freedom, a haptic
interface (provided by the PERCRO laboratories of Pontedera, Italy), or a multimedia
board (provided by the CNIT research unit at the University of Florence,
Italy).
Contribution devices. During the lectures or the laboratory experiments,
audio and video interaction of any user must be allowed. For the students'
class we have selected a Pan-Tilt-Zoom (PTZ) dome camera (whose control is
allowed via VISCA commands) and omnidirectional microphones, while simple
commercial devices are sufficient for the lecturer. Video System Control Architecture (VISCA) is a network protocol designed to interface a wide variety of video devices
to a computer.
Scene analysis systems. These
systems allow the acquisition and analysis of context information. They need an
accurate tuning to overcome the environment problems (room size, light, noise
level, reverberation, etc.). In particular, the Audi location system,
provided by the research unit at the Technical University of Milan [4], allows
locating the position of the speaker making a reservation, through the phase
processing of the acquired audio signals (it includes an array of microphones,
audio mixer, computer for the processing, and deadening panels), while the Request
Identification System, provided by the CNIT research unit at the University
of Genoa [5], allows making a reservation for a question or intervention simply
by raising a hand, by means of video processing techniques (it includes dome
camera and a computer for processing). Finally, a specific application,
developed by the CNIT research unit at the University of Cagliari,
is able to control the PTZ dome camera to transmit the video of the student
making a reservation.
Video rendering system for the students' class.
Input devices.
3. Software Architecture
The software architecture is illustrated in Figure 3. The common
experience manager (CEM) is certainly the main block of such architecture,
as it manages both e-learning and experimental laboratory sessions. Context is
captured and analyzed by the scene analysis (SA) module, through arrays
of microphones and cameras. Such information is stored in the VIL database and managed by a Java interface.
Main blocks of the software architecture.
Any student can select a
synchronous or asynchronous instruction course. In the former case, the CEM
manages the interaction between students and lecturer through a token-based
mechanism: the lecturer is able to entirely release or to share its privileges,
communicating with the CEM through an immersive Graphical User Interface (GUI). Interactive inputs (II) allow interaction with the virtual environment,
while contribution inputs (CI) permit to ask questions during a lecture,
after being enabled by the lecturer: interventions occur by video and audio
streaming. In the latter case, a student can download a previous lecture stored
in the Lectures' Repository by means of the video communications over
IP (VIP)-teach recorder and visualize these offline contents by using a
specific player.
Finally, the LabNet server (LNS)
and the instrumentation cluster manager (also named experience
manager) provide the remote control of real laboratory instrumentation, as
presented in Section 3.2.
3.1. Graphical User Interfaces
A new immersive GUI has been developed to support 3D contents in the synchronous
e-learning application VIP-Teach,
provided by LightComm (http://www.lightcomm.it). The components of this GUI
(see Figure 4) are video (MPEG4 codec), chat, ppt presentations, 3D space, and
management window (with the list of students online and of those making a
reservation). In particular, 3D contents in the lecture session are realized in Virtual Reality Modeling Language (VRML) and controlled by Java
applications to obtain highly interactive and immersive worlds, whose behavior
is modified by user actions [6] in real-time. 3D Studio
Max, VIZ and Maya, among others, can be used to generate and export
nonelementary environments in VRML files format. They in
fact allow navigation in the 3D environment, management of collisions among 3D
objects, visualization of the avatars of other users moving in the environment,
visualization of reservation events and information about users, search of an
avatar by name and selection of a laboratory session.
GUI in the lecture session.
During the lecture, the lecturer can select a laboratory session, simply by clicking on a
virtual door present in the scene. 3D contents in the laboratory sessions (see
Figure 5) are modeled through 3D Studio Max and controlled through eXtreme
Virtual Reality (XVR) by VRMedia (http://www.vrmedia.it/).
GUI in the
laboratory sessions.
The telerestoration session, realized by the CNIT research
units at the Universities of Florence and Pisa
S. Anna, allows experimenting virtual restoration techniques
(such as crack removal and lacuna filling) on high-resolution digital copies of
famous paintings [7], while the two telemeasurement sessions permit to
interact with real instrumentation. In the many-to-one paradigm,
developed in the CNIT National Laboratory for Multimedia Communications
(Naples) [8], the experience is collaborative, namely, the GUI interface allows
the lecturer to transfer the experiment's control to the students, while in the one-to-many paradigm, realized at the WiLab laboratories (Bologna) [9],
it is possible to interact with a “measurement chain,” whose instrumentation is
geographically distributed in different locations.
As concerns telerestoration, the devised tool aims at
obtaining a digital version of the artwork where all damages have been removed;
the great advantage is that if a mistake was made, the artwork does not suffer any kind of injury, and the virtual
restorer can start again the restoration process. This can be useful for
educational aims, in order to look at the artwork as it was in the intent of
the artist who made it, and for guidance aims, in order to give the actual
restorer the possibility to perform some useful tests before choosing the best
restoration technique. The telerestoration session [10] permits to download
high-quality digital images in bitmap format, to zoom in the images, and to
restore a crack and a lacuna according to the techniques actually used during
restorations. Indeed, cracks and lacunas are two of the main problems a
painting or a fresco can be affected by. They deteriorate the artworks more or
less significantly depending on their number and their severity.
The telerestoration session is able to remove cracks in a
semiautomatic way, as it requires the aid of a human user, who has to select
one of the pixels belonging to the crack; the reason for this is that only an
observer can decide if a dark line is a crack or it belongs to the texture or
the subject of the artwork. So suitably initialized, the restoration automatic
procedure is able to recover the whole crack by means of an interpolation technique.
Lacunas
occur when some parts of the artwork collapse and fall down, resulting in a
lack of paint. The telerestoration session operates by repainting the parts
that have collapsed according to some restoration methods, such as chromatic
selection, chromatic abstraction, rigatino, and pointellism.
Their aim is to fill in the lacuna, so as to recover the coarse uniformity of
the artwork and avoid the presence of annoying holes in the whole image.
As regards
the telemeasurement system, the virtual instruments in the many-to-one paradigm
represent the laboratory “active elements,” in the sense that knobs, buttons,
and displays present on their front panels can be dynamically controlled by the
users or updated on the basis of measurement results. These active elements are
handled by Java applets (running within the framework of an XVR application),
which communicate with the server-side infrastructure in order to exchange
commands, data, and results to/from the real remote instrumentation.
XVR, by
means of which all laboratory sessions have been represented, is an integrated
environment for the rapid development of Virtual Reality applications. XVR is
structured in two main modules: the ActiveX control module, which hosts the
very basic components of the technology (like the versioning check and the
plugin interfaces), and the XVR Virtual Machine (VM) module, which contains the
core of the technology (such as the 3D graphics engine, the multimedia engine,
and all the software modules managing the other built-in XVR features).
XVR
features include: client plugin as an ActiveX control for Internet Explorer,
import of models from 3DSMax 4.0 or higher, advanced OpenGL rendering engine,
dedicated script language (S3D), vertex and pixel shaders' support, supplied
byte-code compiler, run-time expandable module capabilities, HTML pages
interaction using JavaScript or VBScript, video textures supporting AVI, import
of FLASH images as 3D textures. Supported audio formats include WAV, MIDI, MP3, and WMA; other features are positional 3D
audio support, input devices' management, remote connections support (TCP and
UDP management).
3.2. Server-Side Architecture
The main components of the CEM are the VIP-Teach server, the LabNet server, and the 3D server, as shown in
Figure 6.
Main components of CEM.
The VIP-Teach server is able to manage users' accounts and
permissions, enrol the students in the lectures, and activate the PowerPoint
viewer on the remote PCs. It can be followed by a web portal, for the management
of the lectures' calendar and for the offline diffusion of ppt presentations,
and by a recorder that allows recording the lecture.
The LabNet server [8], an ad
hoc supervising central unit (SCU), manages access to a generic experiment,
guaranteeing interoperability and synchronization among users. Particularly,
owing to a control module, it
makes the experience collaborative, allowing a super user (the lecturer) the
possibility to pass the instrumentation control (token) to users of inferior
level (the students), through the VIP-Teach client interface. Besides, owing to
the data
provision module, the instrument data are distributed to users in
multicast fashion, and can be visualized on the 3D interface, via a Java-based adaptation
layer.
The 3D manager (i.e., the main component of the 3D server) is a pure Java application able to
manage the VIL database and information related to the graphical
representation, and to handle authorizations of avatars and the logical
structure of the scene.
At the transport layer, the VIP-Teach server adopts UDP for
audio/video streams and TCP for session management. TCP is also used by the 3D
server. The LabNet server adopts both TCP and UDP, and their use will be
specified in more detail below.
The software architecture for e-measurement experiments,
developed at the National Laboratory for Multimedia Communications in Naples,
is shortly explained in Figure 7, by using a top-down approach. The SW modules involved in
the architecture are explained in the following.
The 3D GUI displays the instrument
data and communicates with the rest of the architecture via a Java-based
interface.
The LNS (LabNet server)
manages the access of users to the experiments and distributes the instrument
data.
The experience manager manages the allocation of the instruments in the individual experiments, the
correspondence among the experiment's variables and actions on the
instrumentation drivers.
The experience database contains the experiment table (to list the instruments involved in each one)
and instrument table (to define the allocation state).
Test beds are the
set of instrumentation drivers for e-measurement sessions.
User data communication relies upon UDP, in unicast or
multicast fashion. This connectionless communication protocol is light and
efficient even on a satellite link, but also unreliable. Therefore, the LNS has
to deal with lost packets and quality of service (QoS) problems. Laboratory
sessions often involve a large number of user stations, and so multicast
transmission should be chosen (wherever it is supported by the network) for a
more efficient use of the available bandwidth. On the other hand, for each kind
of user, there is a reliable control connection to the server over the TCP
communication protocol. It is used both for token exchange and for starting or
taking part in an experiment. TCP is heavier than UDP, but it guarantees
stability and control of parameters that are critical for the correct working
of the system.
SW architecture for e-measurement session.
The LNS knowledge is limited to the
experiments and to their allocation, based on different types of user access,
but it does not concern the instruments being used. The experience manager in
fact establishes the link between the LNS and the heterogeneous instrumentation
world, managing the instruments' allocation and drivers' actions. In particular,
to call the driver procedures, the experience manager adopts remote
procedure calls (RPCs) through Simple Object Access Protocol (SOAP), using Extended Markup Language (XML) to encode its calls and HyperText
Transfer Protocol (HTTP) as a transport mechanism [11]. The drivers recognize
SOAP-RPC messages and translate them into reading/writing commands on the instruments'
allocation involved in the experiment.
3.3. Client-Side Architecture
Figure 8 shows the main components of the remote classroom.
In accordance with the GUI, we have considered two main software modules: the VIP-Teach
Client and the 3D Client.
Main components of the remote classroom.
The VIP-Teach Client provides students and lecturers
with the elements needed to actively take part in the lecture; this set of
tools includes several audio/video contents and ppt presentations, as well as
chat box, management window, and shared board. Furthermore, the VIP-Teach
Client interacts with VIP-Teach server to manage users' accounts, to
receive/transmit the audio and video contents from/to own peers, according to
the relative roles, to transfer the information related for token management to
the LNS control module, to interact with the VIL database to publish the token
holder in the context space, and to extract the reservation data.
The VRML/XVR-based 3D Client provides context
information and creates a 3D immersive representation of the class and
instruments involved in the lecture. The VRML/XVR Client interacts with the 3D Manager to log the users and
present context information (i.e., user identity, avatar position, students in
reservation), with the LNS data-provision module to write and read instrument
and painting data via the Java-based adaptation layer, and with the VIL database
for data upload/download.
3.4. Context Data Exchanging
A MySQL DB, named VIL database and shown in Figure 9, is used to exchange context
data. It consists of 8 tables, regarding both user and environment.
The static tables contain user profiles, authorization, environment
settings, and experiments' descriptions.
The graphical data update is
provided by two dynamic tables: user dialog (in which any client writes
its own data) and user information (in which the 3D manager inserts
global data to provide the updates to all clients).
The Hand UP table is used by
external applications, such as the scene analysis systems and VIP-Teach, to
manage the reservation.
The location table is used in order to identify
the actual experiment or to change it.
The VIL database.
4. Performance of the E-Measurement Software Architecture
The LNS represents the core of the e-measurement software architecture and, in a sense,
it can be viewed as middleware providing elements to offer services through a
common interface, in order to establish a contact between who asks for a
service and who offers it. During its design and implementation, much attention
was paid to address several crucial concerns, such as
the intrinsic heterogeneity of the application environments and of the instruments;
the software portability and scalability;
the level of flexibility (to interact with every kind of equipment in a simple way);
the capability of multicasting data
gathered from the measurement instrumentation for an efficient use of the
transmission resources.
All these
aspects, although quite relevant, are not sufficiently well focused, and are often
neglected, in some products available on the market.
A significant number of tests have been carried out on the LNS, also in
comparison with another very popular commercial software package, with two main
goals: to evaluate the LNS effectiveness in the presence of
channels characterized by high delay-bandwidth products (such as satellite
links) and to know
the maximum throughput sustainable by the LNS in terms of data dispatching and
managing.
4.1. LNS Performance on a Satellite Link
The testing of LNS on a real satellite link [12] aimed
at
evaluating the efficiency of the
LNS in terms of packet loss and jitter of data packets observed at the receiver
end;
comparing the effectiveness of the
proposed software platform with the “data socket server (DSS)” of the LabVIEW
suite, a commercial and very popular software package by National Instruments
to remotely pilot instrumentation.
The experimental setup that was used for
performance evaluation is depicted in Figure 10.
The experimental setup for performance evaluation.
The “variable generator” (VG) plays the role of an experiment manager, producing
every D seconds a set of data packets conveying a group of 60 variables
(the total net payload amounts to 8400 bytes). Since the variables generated at
the VG are the same in both cases, the possible differences in performance can
be attributed to the different protocols, data storing, retrieving, and
forwarding strategies adopted by the LNS and the DSS. The multicast capability of the LNS was not
exploited in these tests, for fairness in the comparison, as the DSS version used did not support multicast.
Besides the
satellite experimental setup, other two quite similar setups have been
exploited. In the former, the client stations are connected to the LNS/DSS via
a terrestrial link, whose bandwidth amounts to the average capacity measured at
the IP layer on the satellite link (1.2 Mbps). In the latter, the client
stations are directly connected to the LNS/DSS by means of a high-speed (100 Mbps)
LAN, without the presence of routers and satellite links.
Tables 1
and 2 (from [12]) summarize the packet loss and the root mean square (RMS)
of the delay jitter (i.e., the difference between the expected and the actual
variable transit time, namely, the time a variable needs to reach a client
since its arrival at the LNS/DSS) versus the timing variable D in LAN,
Terrestrial, and satellite scenarios, respectively. The former table shows data
related to the LNS while the latter reports data obtained with the DSS. (Whenever the variable losses
exceeded 30%, we have preferred to omit the corresponding RMS because there are
too few data in order to compute a stable and reliable RMS value and sometimes
the DSS itself crashes.)
Performance results in the presence of the LNS.
Variable time D [ms]
LAN
Terrestrial
Satellite
Loss [%]
RMS [μs]
Loss [%]
RMS [μs]
Loss [%]
RMS [μs]
1000
0
70 ± 2
0
139 ± 71
0
16615 ± 70
500
0
72 ± 3
0
170 ± 78
0
15980 ± 240
350
0
75 ± 4
0
258 ± 90
0
11030 ± 530
300
0
71 ± 5
1.6
14141 ± 78
2.3
9120 ± 212
Performance results in the
presence of the DSS.
Variable time D [ms]
LAN
Terrestrial
Satellite
Loss [%]
RMS [μs]
Loss [%]
RMS [μs]
Loss [%]
RMS [μs]
1000
0
16750
0.2
103000
60
—
500
0
14500
25
189000
82
—
350
1.3
24500
60
—
96
—
The results
highlight that the LNS performance is almost unaltered in passing from a LAN to
a terrestrial link environment, while a satellite link yields higher RMS
values. However, also in this latter case, the RMS values never exceed 3% of
the timing variable. Moreover, no loss is present for timing variables of 1000,
500, 350 milliseconds. The losses at 300 milliseconds are due to the queue
length, inadequate to completely allocate room for the data bursts.
On the contrary, the performance of the DSS dramatically decreases when a satellite
link is in use. Comparing the columns of Table 2 related to the terrestrial and
satellite links, highlights how the propagation delay, inherent to the
satellite link, strongly affects the overall performance of an e-measurement
platform centered on the DSS. Furthermore, the DSS appears unable to manage
bursts of variables, whose interarrival times are less than 350 milliseconds.
Most likely, the main reason for the different behavior of the LNS and the DSS
resides in the transport protocol. The DSS uses TCP as a transport protocol,
whose performance may be negatively affected by the presence of a large
bandwidth-delay product, whereas the LNS relies on UDP (without any reordering
mechanism). However, the adoption at the application level of TCP by the DSS
does not assure the absence of loss of variables at the receiver end. This is
probably due (the actual DSS working mechanism is undocumented) to the fact
that the DSS likely discards the variables arrived too late. On the contrary,
although the LNS extensively uses UDP packets to convey information, the UDP
lightness and the efficiency of the LNS allow a de facto “reliable” delivery.
Obviously, the efficiency drastically increases by enabling the multicast
capability owned by the LNS.
4.2. LNS Maximum Throughput
A second group of tests was carried out aiming at estimating and comparing the maximum
throughput sustainable by the LNS and DSS, by measuring the value of variables'
loss at the receiver ends in a simple LAN scenario with 4 client stations. In
each row, Table 3 [13] reports the variables' loss observed when the LNS and
the DSS are in use, at a specific level of traffic load produced at the VG. Above 2100 kbps, the variable
loss introduced by the DSS cannot be measured, as the DSS seems incapable to
support such heavy loads; variables' updates are no longer notified to the user
stations, and sometimes the DSS itself crashes.
Variables' loss at the user stations versus different loads produced at the VG.
Load produced
LNS variables'
DSS variables'
at the VG
loss
loss
269 kbps
0%
0.2%
340 kbps
0%
9.5%
2100 kbps
0%
33%
15 Mbps
0%
—
20 Mbps
5.24%
—
25 Mbps
26.37%
—
Again, the
performance of the LNS appears to be significantly better than that shown by
the DSS; furthermore, especially as concerns the packet loss, the performance
of the DSS dramatically decreases when heavy loads are produced by the VG.
5. An Operative Example
A specific remotely controlled demo has been set up in the many-to-one telemeasurement session
by the National Laboratory for Multimedia Communications in Naples. Its goal
is to remotely test the operating conditions of a WLAN, in the presence of
an adjacent interfering channel, produced by a vector signal generator.
In particular, the qualitative (and, to some extent, quantitative) analysis of the
channel throughput is allowed, by observing the quality of a received video
sequence and the number of dropped packets and, at the same time, by viewing
the resulting waveform on the display of a virtual instrument representing a
remotely controlled real spectrum analyzer. The video TX produces a Motion-JPEG
encoded stream that feeds the access point (AP) on the right of Figure 11. The
RF output of this AP is combined with an interfering signal produced by an Agilent
E-4438C vector signal generator. The resulting sum traverses a splitter,
where the main part of the signal power is directed to the video receiver
through a second AP. The decoded video stream is retransmitted over a satellite
WAN link or over the Internet (from the National Laboratory for Multimedia
Communications in Naples to any remote site) toward the remote observer. Another
part of the interfered signal reaches a spectrum analyzer (Agilent E-4404B), where the
interference phenomenon can be remotely displayed. The GPIB bus (suitably
bridged to the laboratory LAN by the E-NET device) disseminates commands and
gathers responses from the instruments, thus permitting their complete remote
control.
Demo architecture in the many-to-one telemeasurement
session.
In our experimental setup, the video TX is represented by a VLC application [14],
which generates the signal under test (viz the MotionJPEG-encoded
video), while the interfering traffic consists of a deterministic constant bit
rate signal, whose power can be selected by the remote user.
By using
the 3D GUI (see Figure 12), it is possible to turn the virtual instrumentation on and off, by clicking
on ON/OFF buttons, to see the interfered signal characteristics on a
device's display (e.g., a spectrum analyzer), to observe the quality of a
received video sequence, to pass and revoke the token to/from a student, to
know the statistics of a video transmission and to set the values of experiment
variables, by clicking on the instrument's buttons.
GUI in the many-to-one telemeasurement session.
For example, when the two transmissions are on nonoverlapping channels (interfering
traffic on CH 1 and video one on CH 7) any user can see a very fluent received video, practically no
dropped packets, and the classical spectrum of a WLAN transmission. If the
interfering signal is shifted on an adjacent channel (CH 6), it is possible to
see some dropped packets and a low video quality. If the two transmissions are
on the same channel (CH 7), the video transmission is completely stopped and it is possible to see a very
disturbed spectrum. At this point, if the amplitude of the interfering signal
is lowered, the video transmission can start again.
6. User Mobility Issues
The VIL test bed does not address mobility issues explicitly. As a matter of fact, the
core of the distance learning application does not change, even in case the
client used to follow a lecture or access a laboratory session is characterized
by a certain degree of mobility. Wireless access, a requisite for mobility, has
been indeed considered, since the connection in the example experiment we have
described relied upon a satellite link. In this respect, it is worth
remembering that the LabNet server protocol, adopted for the management of the
client population in the access and control of the measurement devices, has
been shown to exhibit a very satisfactory degree of robustness when used over
high bandwidth-delay product networks (e.g., satellite or even some types of
wireless cellular networks), also in comparison to widespread commercial
solutions. Moreover, the full functionalities of the system may be accessed
from a wireless network in general, provided that a transmission speed in the
range 0.8–1 Mbps is
achievable. Problems regarding security should be handled by appropriate
authentication and data protection. Possible QoS provisioning mechanisms may be
adopted over the wireless link and at the wired/wireless network boundaries.
As regards specifically user
mobility, a link with the mechanisms developed within the VICOM project (mobile
immersive environment (MIE) testbed) for localization and user guidance may be
established. Such mechanisms, based on the use of multiple localization
techniques, would facilitate the mobile users in reaching specially equipped
classrooms, where they can take advantage of advanced interfaces (e.g.,
multimedia board, haptic interfaces, or 3D video rendering).
Future developments will regard the establishment of a software interface between LINDA
in a mobile environment (LIME) [15], the middleware used for handling the
distribution of the context data in the MIE testbed, and the VIL database, to
automatically acquire profiles of mobile users when they enter the classroom.
A final observation regards the adoption of IPv6 at the network layer, especially in
conjunction with the need of facing user mobility issues. The VIL test bench
has been implemented over IPv4 networks, but it could easily migrate to IPv6.
In particular, the Mobile IPv6 (MIPv6)
protocol, an IETF standard [16] to provide transparent host mobility within
IPv6, should be considered, as it presents several differences to its IPv4
counterpart that provide a simpler, more streamlined protocol (among others, no
need for foreign agents, route optimization as standard, integrated support—care of address (COA)
and ingress filtering, destination options, COA and multicast routing, use of
IPv6 anycast for home agent discovery, etc.).
7. Conclusions
The paper has presented the design and implementation of the
VIL test bed and its main related motivations, as well as critical aspects. The
software and hardware strategies, allowing reproduce the context of a real
academic classroom in a virtual environment, have been described in some
detail.
High portability, good flexibility, and, above all, low cost,
make this approach appropriate for educational and training purposes, mainly
concerning measurements on telecommunication systems, at universities and
research centers, as well as enterprises.
Moreover, the methodology can be employed for remote access
to and sharing of costly measurement equipment in many different fields of
activity. In fact, the results of a number of tests prove the effectiveness of
the proposed solution in terms of both high-sustainable throughput levels and
low-delay jitter in comparison with a very popular commercial software package,
also in the presence of channels characterized by high delay-bandwidth products
(such as satellite links).
As regards in particular the access and management of remote
measurement instrumentation and laboratory equipment in general, it is worth
mentioning that the LNS platform adopted in the VIL test bench is gradually
evolving toward a web services and Grid-based architecture [17], which exploits
the functionalities initially developed in the framework of the GRIDCC European
project [18]. Specifically, the concept of instrument element (IE), developed by GRIDCC, provides a set of services to control and monitor
remote physical devices; users view the IE as a set of web services, which
provide a common language to the cross-domain collaboration and, at the same
time, hide the internal implementation details of accessing specific
instruments. The integration of the VIL representation capabilities with
Grid-based Remote Instrumentation Services has been addressed in [19].
Acknowledgments
This work was funded by the Italian Ministry of Education and
Scientific Research (MIUR) in the framework of the FIRB_VICOM project. The
support of the previous LABNET project in creating the e-measurement framework
is also gratefully acknowledged. This work is an extended version of a paper presented at IMMERSCOM 2007, Bussolengo (Verona), Italy.
TougawD.Doug.Tougaw@valpo.eduWillJ.Jeff.Will@valpo.eduVisualizing the future of virtual reality20035481110.1109/MCISE.2003.1208635Digital Video Broadcasting (DVB)Interaction Channel for Satellite Distribution SystemsETSI EN 301 790, 2003DavoliF.NicolaiG.RongaL. S.VignolaS.ZappatoreS.ZinicolaA.A Ka/Ku band integrated satellite network platform for experimental measurements and services: the CNIT experienceProceedings of the 11th Ka and Broadband Utilization ConferenceSeptember 2005Rome, Italy715723AntonacciF.antonacci@elet.polimi.itLonoceD.MottaM.SartiA.sarti@elet.polimi.itTubaroS.tubaro@elet.polimi.itEfficient source localization and tracking in reverberant environments using microphone arrays4Proceedings of the IEEE International Conference on Acoustics, Speech, and Signal Processing (ICASSP '05)March 2005Philadelphia, Pa, USA1061106410.1109/ICASSP.2005.1416195PivaS.BonamicoC.RegazzoniC.LavagettoF.RivaG.VatalaroF.DavideF.AlcañizM.A flexible architecture for ambient intelligence systems supporting adaptive multimodal interaction with users2005Amsterdam, The NetherlandsIOS Press97120PierleoniP.Di BiaseT.CancellieriG.FiorettiF.PasqualiniS.DavoliF.PalazzoS.ZappatoreS.The dynamic construction of multi-user VRML 3D environment for immersive learning on the web2006New York, NY, USASpringer49750910.1007/0-387-30394-4_34CappelliniV.cappellini@det.unifi.itBarniM.CorsiniM.De RosaA.PivaA.ArtShop: an art-oriented image-processing tool for cultural heritage applications200314314915810.1002/vis.313DavoliF.Franco.Davoli@cnit.itSpanòG.Giuseppe.Spano@cnit.itVignolaS.Stefano.Vignola@cnit.itZappatoreS.Sandro.Zappatore@cnit.itLABNET: towards remote laboratories with unified access20065551551155810.1109/TIM.2006.880919AndrisanoO.oandrisano@deis.unibo.itContiA.a.conti@ieee.orgDardariD.ddardari@deis.unibo.itRoversiA.alberto.roversi@cnit.itTelemeasurement and circuit remote configuration through heterogeneous networks: characterization of communications systems200655374475310.1109/TIM.2006.870335BartoliniF.BarniM.CaldelliR.Research of the image processing and communications lab. of the University of Florence in the cultural heritage field5146Optical Metrology for Arts and MultimediaJune 2003Munich, Germany116126Proceedings of SPIE10.1117/12.504620VollonoA.ZinicolaA.DavoliF.PalazzoS.ZappatoreS.A new perspective in instrumentation interfaces as web services2006New York, NY, USASpringer45146110.1007/0-387-30394-4_31BerrutiL.DavoliF.VignolaS.ZappatoreS.Del ReE.RuggieriM.Interconnection of laboratory equipment via satellite and space links: investigating the performance of software platforms for the management of measurement instrumentation2007New York, NY, USASpringer657666BerrutiL.VignolaS.ZappatoreS.sandro.zappatore@cnit.itInvestigating the performance of a middleware protocol architecture for tele-measurement200821550952310.1002/dac.905VLC—Video LAN Client, http://www.videolan.org/PiccoG. P.MurphyA. L.RomanG.-C.JazayeriM.WolfA.Developing mobile computing applications with LIMEProceedings of the 22th International Conference Software Engineering (ICSE '00)June 2000Limerick, IrelandACM Press76676910.1109/ICSE.2000.870491IETF RFC 3775Mobility Support in IPv6Berruti L.CaviglioneL.DavoliF.PolizziM.VignolaS.ZappatoreS.DavoliF.MeyerN.PuglieseR.ZappatoreS.On the integration of telecommunication measurement devices within the framework of an instrumentation Grid2008New York, NY, USASpringerGRIDCC project, http://www.gridcc.org/BerrutiL.CaviglioneL.DavoliF.Joining virtual immersive environments and instrumentation grids for distance learningProceedings of the IFIP WG 3.6., 3.4. and 3.8. Joint Working Conference on Information Technology for Education and Training (iTET '07)September 2007Prague, Czech Republic1628