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WiMAX Campus Deployments and Experiments Meeting at GEC-14
- Schedule
- Description
- Agenda
- 1) Introductions
-
2) GENI WiMAX Deployment Tasks and Issues
- 2.1) Co-exist with Clearwire
- 2.2) Netspan Network Management System for Airspan Base Station
- 2.3) Updated/new WiMAX RF AggMgr
- 2.4) Add mobility/handover functions
- 2.5) Add "yellow nodes" to WiMAX Sites, as WiFi access points and …
- 2.6) Add OMF/OML to WiMAX Sites
- 2.7) Connect WiMAX Sites to I2 Backbone Network
- 2.8) Roaming Mobile Station using Android Handset
- 3) Experiments
-
4) GENI WiMAX Site Deployment Status and Plans
- 4.1) BBN Site Extension Plan
- 4.2) WINLAB/Rutgers University Site Extension Plan
- 4.3) UCLA Site Extension Plans
- 4.4) Clemson University Site Deployment Plan
- 4.5) University of Wisconsin Site Extension Plan
- 4.6) University of Michigan Site Deployment Plan
- 4.7) Wayne State University Site Deployment Plan
- 4.8) Temple University Site Deployment Plan
- 4.9) Drexel University Site Deployment Plan
- 4.10) UMass Amherst Site Update
- 4.11) NYU Poly Site Update
- 4.12) Univ of Colorado at Boulder Site Update
- 4.13) Columbia University Site Update
- 5) Adjourn
-
References
- R1 GENI WiMAX Strategy
- R2) WiMAX Licenses
- R3) Airspan Profile-C Base Station, with Associated Hardware and Software
-
R4) WiMAX Site Configuration
- R4.1) Updated WiMAX RF AggMgr for NEC Base Station
- R4.2) WiMAX RF AggMgr for Airspan Base Station
- R4.3) Adding OMF/OML Configuration
- R4.4) GIMI I&M Tool Set to Cover WiMAX Sites
- R4.5) Adding Login Service for Remote Users
- R4.6) Federating with ProtoGENI Cluster
- R4.7) Adding "Yellow Node" with WiFi Access Point, for Dual-homed …
- R4.8) Adding Mobility/Handover Functions
- R5) Connecting WiMAX Site to Backbone Network
- R6) Mobile Station Platforms
- R7) Types of Experiments
- R8) Spectrum Survey Experiment
- R9) Throughput Experiment Using iperf
- R10) Throughput Experiment Using Bit Torrent
- R11) Raw IP and UDP Traffic Generators
- R12) Using OMF and OML in Your Experiment
- R13) Remote Experiments
- R14) Multiple Site Experiment: Mobility First
WiMAX Campus Deployments and Experiments Meeting at GEC-14
Schedule
Tuesday, July 10, 1:30pm - 3:30pm
Room: TBD
Session leader: Harry Mussman (GENI Project Office, Raytheon BBN Technologies)
Description
This session will first review the status of WiMAX site deployments and extensions.
Then, it will consider several GENI WiMAX strategic issues, including GENI WiMAX experimenter support.
Agenda
This is a tentative agenda, which may change.
NOTE: We have many topics to cover in a short time. PLEASE bring only the designated number of slides, and provide a link to additional information. THANKS!
1) Introductions
1:30pm
2) GENI WiMAX Deployment Tasks and Issues
1:35pm
2.1) Co-exist with Clearwire
1:35pm
Harry Mussman (GPO) and Ray Raychaudhuri (WINLAB)
Summary of license arrangements, some limited to 1 year, up to $4k to renew
Discussions with Clearwire
Discussions with the FCC
Suggested Approach
[ 1 status slide]
2.2) Netspan Network Management System for Airspan Base Station
1:40pm
Moderator: Manu Gosain (GPO)
Add Netspan system at each site
Later, may replace with WiAMX RF AggMgr
[ 1 configuration slide]
2.3) Updated/new WiMAX RF AggMgr
1:45pm
Ivan Seskar (WINLAB)
Update WiMAX RF AggMgr for NEC base station (2.5.3+)
Feed to centralized managment DB (at WINLAB)
[ 2 config, status slides]
Coming: New WiMAX RF AggMgr for Airspan base station
2.4) Add mobility/handover functions
1:55pm
Parmesh Ramanathan (Wisconsin)
Projects requiring handover include: Clemson, Wayne State and Wisconsin.
Projects that can contribute handover technology include: Rutgers WINLAB and Wisconsin.
Also, commercial handover technology available from Airspan. (Gregg Tome (Airspan))
Process to find a good solution?
[ 1 status slide]
2.5) Add "yellow nodes" to WiMAX Sites, as WiFi access points and fixed "mobile stations"
2:00pm
Manu Gosain (GPO) and Ivan Seskar (WINLAB)
Configuration, with interfaces, management, etc.
How can these be provided to sites?
[ 1 config, status slide]
2.6) Add OMF/OML to WiMAX Sites
2:05pm
Derek Meyer (Wisconsin), MAnu Gosain (GPO)
Equip a WiMAX site with full OMF/OML capabilities, installing on VMs
Include Login Service for Remote Users
Coming: Plan to Federate with ProtoGENI Cluster
[ 1 config, status slide]
2.7) Connect WiMAX Sites to I2 Backbone Network
2:15pm
Manu Gosain (GPO), Fraida Fund (NYU Poly), Ivan Seskar (WINLAB)
Connect a WiMAX site to the GENI I2 backbone network
Update WiMAX RF Agg Mgr to map MS groups into VLAN tags
Add switch
Connect switch to I2 backbone
Mesh of VLAN connections in I2 backbone
What other WiMAX sites can be added?
[ 1 config, status slide]
2.8) Roaming Mobile Station using Android Handset
2:20pm
Harry Mussman (GPO)
Discussions with Sprint about unlocked HTC Evo handset
Possible: Sprint MVNO arrangement for pay-as-you-go data service
[ 1 status slide]
3) Experiments
2:25pm
3) Types of experiments
3.1) Local experiments
Manu Gosain (GPO)
3.2) Remote experiments, used for tutorials
Fraida Fund (NYU Poly)
3.3) Multi-Site experiments
3.4) Gathering experimenters?
4) GENI WiMAX Site Deployment Status and Plans
2:35pm
Paper including sections on basic and extended WiMAX sites, and on WiMAX research and service experiments: pdf
Current GENI WiMAX sites, licenses and base stations spreadsheet
4.1) BBN Site Extension Plan
2:35pm
Manu Gosain (GPO)
Status
Changing frequency, per request from Clearwrie
Bringup Airspan
Installed; working
Add OMF/OML
In process: Install on HP server, splitting functions onto different VMs
Connect to I2 backbone network
Connected; working; used for tutoriala
[ 2 status, experiments slides]
4.2) WINLAB/Rutgers University Site Extension Plan
2:40pm
Ivan Seskar (WINLAB)
Status
Bringup Airspan
Remote access to BSs
Connect to I2 backbone network
[ 2 status, experiments slides]
4.3) UCLA Site Extension Plans
2:45pm
Mario Gerla, Giovanni Pau (UCLA)
Extension plan
Add x1 Airspan BS near UCLA dormitories; possibly other BSs.
x1 (2510 Mid: 2560MHz to 2630MHz)
License status
Location and backhaul
Mobility and handover
Planned experiments
Add OMF/OML
Connect to I2 backbone network
[ 2 status, experiments slides]
4.4) Clemson University Site Deployment Plan
2:50pm
K-C Wang, Reece Johnson (Clemson)
Clemson slides
Extension plan
Add x1 Airspan BS near campus
Add x2 Airspan BS near Greenville; connect via DOT fibers.
Want handover near I85/I385 intersection.
x3 (2510 Lo: 2496 to 2570 MHz)
License status
Location and backhaul
Mobility and handover
Planned experiments
[ 2 status, experiments slides]
4.5) University of Wisconsin Site Extension Plan
2:55pm
Suman Banerjee, Derek Meyer (Wisconsin)
Extension plan
Add Airspan to building/tower near Capitol.
Connect via Madison unified fiber project
Outside contributions for power and poles.
x1 (2510 Mid: 2560MHz to 2630MHz)
License status
Location and backhaul
Mobility and handover
Planned experiments
Add OMF/OML
Connect to I2 backbone network
[ 2 status, experiments slides]
4.6) University of Michigan Site Deployment Plan
3:00pm
Morley Mao (Michigan)
Extension plan
Add one Airspan on top of building
Will signals penetrate into buildings?
One frequency from Clearwire
x1 (2510 Lo: 2496 to 2570 MHz)
Location and backhaul
Mobility and handover
Planned experiments
[ 2 status, experiments slides]
4.7) Wayne State University Site Deployment Plan
3:05pm
Hongwei Zhang, Yu Chu (Wayne State)
Extension plan
Plan: one site with three sectors, and 3 Airspan base stations.
One frequency (10MHz) from Clearwire x3 (2510 Mid: 2560MHz to 2630MHz)
License status
Location and backhaul
Mobility and handover
Planned experiments
[ 2 status, experiments slides]
4.8) Temple University Site Deployment Plan
3:10pm
Shan Lin, Jie Wu (Temple)
Extension plan
x1 (or x2?) Airspan base stations (2510 Mid: 2560MHz to 2630MHz)
Two frequencies from Clearwire, shared with Drexel
Location and backhaul
Mobility and handover
Planned experiments
[ 2 status, experiments slides]
4.9) Drexel University Site Deployment Plan
3:15pm
Kevin Wanuga, Jeff Wildman, Kapil Dandekar (Drexel)
Extension plan
x1 (or x2?) Airspan base stations (2510 Mid: 2560MHz to 2630MHz)
Two frequencies from Clearwire, shared with Drexel
Location and backhaul
Mobility and handover
Planned experiments
[ 2 status, experiments slides]
4.10) UMass Amherst Site Update
3:20pm
Mike Zink, Cong Wang (UMass Amherst)
Status
Add OMF/OML
Connect to I2 backbone network
Planned experiments: use to integrate GIMI tools
[ 2 status, experiments slides]
4.11) NYU Poly Site Update
3:25pm
Thanasis Korakis, Fraida Fund (NYU-Poly)
Status
Planned experiments
[ 2 status, experiments slides]
4.12) Univ of Colorado at Boulder Site Update
3:30pm
Dirk Grunwald (Colorado)
Status
Add OMF/OML
Connect to I2 backbone network
Planned experiments
[ 2 status, experiments slides]
4.13) Columbia University Site Update
3:35pm
Henning Schulzrinne, Jan Janak (Columbia)
Status [ 1 slides]
Add OMF/OML
Connect to I2 backbone network
Planned experiments
[ 2 status, experiments slides]
5) Adjourn
3:40pm
References
R1 GENI WiMAX Strategy
Harry Mussman (GPO)
a) Goals for GENI WiMAX site deployments:
Satisfy needs of local research experiments
Support multi-site experiments, e.g., MobilityFirst
Support remote experimenters
Support multi-site applications?
Are we missing something? support for instruction?
b) Sol 2 base station deployments:
Update to include OMF/OML structures, including LoginService
Add GENI AM API
Complete, and update to new software that support multiple VLANs, etc.
Connect via switch to I2 backbone, via OF switches if there
Consider how to setup multi-site slice, and include other GENI resources
Consider federated operation
Consider adding WiFi AP to support dual-homed experiments, e.g., MobilityFirst
c) Sol 3 base station deployments:
Consider 3.6GHz operation?
Study commercial campus deployments, to understand coverage and applications: U Colorado, Boulder; Northern Mich U; UMass Dartmouth
Order Airspan base stations and related items, for delivery 1/2012
Complete installation within Spiral 4! (within 1 year)
Decide on how to provide ASN-GW for handover
Consider open-source ASN-GW? or ASN-GW from Airspan?
How could we use Wisconsin mobility engine?
d) Mobile stations:
Reference MS is Linux netbook, with Intel WIMAX modem card, internal or external
Reference vehicular MS?
Reference handset MS? Need to be able to unlock Sprint-supported device?
e) Experiment support:
Move to OMF/OML, for better support and for easier sharing
Consider alternate techniques for throughput measurements
Consider how to setup multi-site slice, and include other GENI resources
GIMI project committed to supporting WiMAX sites
How can we make it easy for experimenters?
f) Other topics:
Interworking with carriers (Clemson)
Use of carrier resources, i.e., WiNTeB
How could we add LTE? any match of equipment, frequencies and mobile stations?
g) CONCERN:
Do not have resources to do all of the above! how do we decide?
What is the best way to support campus projects?
What is the best way to support experimenters?
R1.1) Options for Introducing LTE Equipment
Moderator: Harry Mussman (GPO)
Ray Raychaudhuri (WINLAB)
Ivan Seskar (WINLAB)
Patrick Gossman (Wayne State) The Case for LTE
Gregg Tome (Airspan)
R2) WiMAX Licenses
R2.1) Co-exist with Clearwire
R3) Airspan Profile-C Base Station, with Associated Hardware and Software
Ivan Seskar (WINLAB) and Harry Mussman (GPO)
a) Choice of Airspan to provide a WiMAX base station for new GENI WiMAX sites
NEC is not able to provide a WiMAX base station for new GENI WiMAX sites
WINLAB and the GPO have decided to purchase base stations from Airspan, a commercial company pursuing target customers such as universities and small carriers.
For example, the Univ of Colorado at Boulder IT Dept has installed an Airspan system with 4 sectors, that covers the campus. They have been pleased with Airspan.
WINLAB has a frim quote from Airspan for their MacroMAXe profile-C WiMAX base station unit, and related items.
Airspan brochure
MacroMAXe Product Specification
Airspan Deployment Plan for Univ Colorado at Boulder
b) Rutgers will provide a kit including:
Airspan MacroMAXe profile-C WiMAX base station unit, for outside mounting
Choice of frequency:
(2510 Lo: 2496MHz to 2570MHz)
(2510 Mid: 2560MHz to 2630MHz)
(2510 Hi: 2620MHz to 2690MHz)
(3650: 3650MHz to 3700MHz)]
NOTE: WINLAB needs to know frequency choices during November (or early December), so that they can place an order with Airspan for delivery late 2011 or early 2012!
Sector antenna, with x4 RF jumper cables
2x4 MIMO, supported by base station and antenna
GPS antenna, with surge suppressor and cable
DC power cable, from base station unit (outside) to testbed (inside)
Network management software license, 1 per base station
Figure 3-1 Airspan MacroMAXe Base Station with Antenna
c) Campus will need to provide:
Pole for mounting
DC power supply (-48v, approx 300W)
Ethernet cable, from base station unit (outside) to testbed (inside); consider copper (may be a problem with lightning surge) or fiber (requires MM fiber cable, and fiber interface on switch)
Windows server to host network management software
Linux server to host OMF software
Ethernet switches, and other network equipment, for access (configuration to be provided)
d) Additional kits can be purchased from Airspan
Price is approximately $15,000.
e) It is expected that additional base stations kits will be purchased for some (or all) Sol 3 GENI sites in Spiral 5.
Thus, campus site might be able to add additional sectors, at no cost.
Planning for next year will be done later this year.
Consider including additional sectors within your technical plan right away.
f) Note: Airspan indicates that they expect to introduce a new base station unit within the next year.
Somewhat reduced performance/range.
Approximately half the cost
g) Airspan indicates that their sector antenna provides:
A 90degree pattern, which is consistent with proper coverage over a 120degree sector.
Four internal elements, to support 2x4 MIMO.
Airspan can provide provide x4 omni-directional antennas, but the cost is much higher, and the range is signifcantly reduced.
h) Airspan shows that their profile-C base station unit can be configured to operate without an ASN GW and without a RADIUS (authentication) server.
In this mode, a list of allowed base stations must be configured into the base station, and groups of these base stations are mapped to a VLAN on the ethernet port.
This appears to be consistent with the current NEC base station unit operated with the ASN GW/WiMAX RF AggMgr code that has been provided by Rutgers/WINLAB
MacroMAXe Configuration Guide
i) Airspan shows that if handover operation is desired, an ASN GW must be provided, plus typically an associated RADIUS (authentication) server.
In this case, the base station unit operates with IP at the interface.
R3.1) Netspan Network Management System
R4) WiMAX Site Configuration
R4.1) Updated WiMAX RF AggMgr for NEC Base Station
R4.2) WiMAX RF AggMgr for Airspan Base Station
R4.3) Adding OMF/OML Configuration
R4.4) GIMI I&M Tool Set to Cover WiMAX Sites
R4.5) Adding Login Service for Remote Users
R4.6) Federating with ProtoGENI Cluster
R4.7) Adding "Yellow Node" with WiFi Access Point, for Dual-homed Experiments
R4.8) Adding Mobility/Handover Functions
Moderator: Parmesh Ramanathan (Wisconsin)
Projects requiring handover include: Clemson, Wayne State and Wisconsin.
Projects that can contribute handover technology include: Rutgers WINLAB and Wisconsin.
Also, commercial handover technology available from Airspan. (Gregg Tome (Airspan))
Process to find a good solution?
[ slides]
WiMAX site with multiple base stations and mobility management
R5) Connecting WiMAX Site to Backbone Network
R6) Mobile Station Platforms
R6.1) Fixed Mobile Station using "Yellow Node"
R6.2) Roaming Mobile Station using Linux Netbook
R6.3) Linux driver for Teltonika modem
R6.4) Roaming Mobile Station using Android Handset
R7) Types of Experiments
Paper including sections on basic and extended WiMAX sites, and on WiMAX research and service experiments: pdf
R8) Spectrum Survey Experiment
R9) Throughput Experiment Using iperf
Manu Gosain (GPO) and Harry Mussman (GPO)
Overview of basic throughput experiment, using bidirectional iperf, both TCP and UDP
The basic throughput experiments we have done utilize iperf, both TCP and UDP.
In iperf, the data is generated in the client, and flows to the server.
We put the client in the Mobile Station, and the server in the Base Station.
We used -d dualtest (bidirectional mode), where test is initiated at the client, data begins to flow to the server, and then a second data flow starts at the server; at the end of the test, results are available at the client.
Because of this, all tests can be initiated at the Mobile Station, and then results are available there.
iperf results in the TCP mode depend upon buffer sizes; overall delay; and lost packets.
Because of wireless propagation conditions, lost packets are common, and slight changes can significantly affect the measured throughput.
Thus, TCP results are highly variable; we took multiple measurements at each point, and identified the best and worst results.
It would certainly be good to have a better way to evaluate available channel bandwidth.
On the other hand, most apps use TCP and the variable results are typical of how these apps would see the channel.
iperf results in the UDP mode, counts % packets received, for a given (fixed) transmit rate.
If the rate is set below the available bandwidth, typically 100% of the packets are received.
If the rate is set above the available bandwidth, typically % of the packets are received typically equals available bandwidth divided by offered bandwidth, but there is no way to understand how many packets are actually lost.
An extended test that ramped up the offered bandwidth in multiple tests, could actually verify the available bandwidth; this could then be repeated to see real variations in available bandwidth.
References:
R10) Throughput Experiment Using Bit Torrent
Fraida Fund (NYU Poly)
Overview of throughput experiment, using bit torrent.
Advantages
Reference
More information & source code
Use the NYU-Poly WiMAX testbed
R11) Raw IP and UDP Traffic Generators
Surat (Au) Teerapittayanon (MIT)
Overview of new raw IP and UDP traffic generators, to accurately gauge available channel bandwidth.
slides
R12) Using OMF and OML in Your Experiment
Christoph Dwertmann (NICTA)
Basic throughput experiment using OMF/OML
OML'ified apps we know of include:
gpslogger
Iperf
omf_nmetrics
omf_trace
otg and otr
wlanconfig_oml
Yantt (Yet another network testing tool)
SNMP wrapper
Repository for OML'ified apps
List of available modules with OMF and OML for use in your experiment
Approach for adding OMF and OML interfaces to additional modules
R13) Remote Experiments
R14) Multiple Site Experiment: Mobility First
Kiran Nagaraja (WINLAB)
Overview of current Mobility First multiple-site experiment.
What additions are needed?
1) Add WiFi AP to each site.
2) L2 path from MS to core
Experiment done without human intervention, by using x2 MAC addresses, and emulating packet loss to fake mobility.
Consider these as possible sites by GEC13: WINLAB; BBN; NYU Poly; UCLA; Colorado.
Attachments (13)
-
2012_07_09_Geni_Conference.ppt (327.0 KB) - added by 12 years ago.
University of Wisconsin-Madison status update
- GEC14-WiMAX-NYUPoly.pdf (403.0 KB) - added by 12 years ago.
-
WayneWiMAX-deployment-planAndStatus-GEC14.pdf (986.6 KB) - added by 12 years ago.
Status update at GEC14
- 071112 WiMAX GEC14 Wrap-Up Agenda.ppt (253.0 KB) - added by 12 years ago.
- GEC14-WiMAX-Clemson.ppt (310.5 KB) - added by 12 years ago.
- geni-meeting-temple-july2012.pptx (892.3 KB) - added by 12 years ago.
- ucla 2012-July-10-GEC.pptx (2.3 MB) - added by 12 years ago.
- BBNStatus 0710wimaxmeeting14gec.ppt (223.5 KB) - added by 12 years ago.
- NetspanMgmtSystem 0710wimaxmeeting14gec.ppt (494.0 KB) - added by 12 years ago.
- WiMAXSiteConnectivity 0710wimaxmeeting14gec.ppt (268.0 KB) - added by 12 years ago.
- 071012 GEC14_WiMAXOverview.ppt (274.0 KB) - added by 12 years ago.
- GEC13 drexel GENI.ppt (944.5 KB) - added by 12 years ago.
-
vmsetup_at_uwmadison.pdf (233.3 KB) - added by 12 years ago.
University of Wisconsin-Madison VM Server Setup