Title: WPANWLANWWAN MultiRadio Coexistence
1WPAN/WLAN/WWAN Multi-Radio Coexistence
IEEE 802 Plenary, Atlanta Tuesday, November 13
2007, 900 PM
Presenters Jari Jokela (Nokia) Floyd
Simpson (Motorola) Artur Zaks (Texas
Instruments) Jing Zhu (Intel) Sponsored by
Stuart J. Kerry (802.11 WG Chair) with support
from Roger B. Marks (802.16 WG Chair)
2Authors
3Abstract
- This presentation gives an overview on
multi-radio coexistence with radios operating on
adjacent and overlapping unlicensed or licensed
frequency bands, covering use cases, problem
analysis, and possible directions for solution.
It shows that coexistence has to consider both
proximity and collocation. Collocation imposes
big challenges due to limited isolation and
various interference sources. Need for
cost-effective solution leads to approach where
antennas are shared by multiple radios thus
introducing the requirement for multi-radio time
resource coordination. Todays solutions are
neither effective, nor scalable with number of
radios and number of vendors. Standardization
efforts are needed to provide information
service, command, and air-interface support
necessary for addressing coexistence issues.
4Agenda
- motivation
- state of the art
- media independent time sharing
- conclusion
5Motivation
Many Radios with Limited Spectrum and Limited
Space
FM
6Comparison of Wi-Fi / WiMAX / Bluetooth
Motivation
Wireless technologies have different sweet spots
of operation in terms of coverage, QoS, power,
throughput, etc.
Other names and brands may be claimed as the
property of others.
7Multi-Radio Concurrent Usages
Motivation
WiMAX Coverage
Bluetooth Coverage
Bluetooth Coverage
Wireless Gateway
on the road
Wi-Fi Coverage
Seamless Handover
in home / office
8Coexistence Challenges (1) Inter-Radio
Interference
Motivation
Interferer
Victim
Isolation Requirements
Severe Moderate Cautious No-problem gt55db
40-55db 25-40db lt25db
9Coexistence Challenges (2) Multi-Radio
Integration
Motivation
FM
- Antenna sharing is more and more commonly being
used for multi-radio integration due to limited
space on small form-factor device. - Wi-Fi Bluetooth Integrated Solution
- What is next? Reconfigurable / Software Defined
Radio - Multi-radio usage and performance should not be
sacrificed
10Coexistence-related IEEE Standards
State of the Art
Lack of coexistence support in air-interface for
emerging WPAN/WLAN/WWAN multi-radio device
11State of the Art
Overview of Coexistence Solutions
not scalable, and not support component sharing
media independent, and potentially scalable, but
needs air-interface support
12Case Study 802.11/802.15.1 Time Sharing
Coexistence Mechanisms
State of the Art
- Basic Ideas
- per-packet authorization of all transmissions
- arbitrate the radio activity by priority when
collision happens - Over-The-Air (OTA) Requirements
- maintain radio duty cycles at friendly/low level
- provide flexibility to (re)schedule radio
activity - forecast schedule for other radios to react
Compressibility Selectivity Predictability
IEEE 802.15.2, 2003
Table IEEE 802.15.1 packet types
Commonly used in cellular headset
Difficult to support TS coexistence
Most friendly to TS coexistence
PTA Packet Traffic Arbitration, AWMA
Alternating Wireless Medium Access SCO
Synchronous Connection-Oriented, ACL
Asynchronous Connection-Less, HV High Quality
Voice
13What is the Problem with Time Sharing (TS)?
State of the Art
Device C
Device A
Inter-Radio Interference
Wireless Network 1
Wireless Network 2
TX
TX
(Multi-Radio) Device B
RX
RX
- Radio activities may not always be locally
controllable - 802.11 frame may arrive at any time due to
random access - 802.16 base station to schedule all the
activities of a mobile station - 802.15.1 master to schedule but usually power
constrained - Challenging to provide desirable performance on
each of the coexisting radios - the performance on one radio is usually protected
at the cost of the other radios performance
14Todays OTA Techniques for Time Sharing
Coexistence
State of the Art
- Common Problems
- Inexplicit, after-thought and case-specific, and
difficult to be applied to new usages - Low reliability and low efficiency due to lack of
explicit / reliable support in air-interface
UAPSD unscheduled automatic power save delivery,
CTS Clear-To-Send, eSCO extended SCO
15Limitations of UAPSD
State of the Art
Difficult to predict T4 due to Access Point
implementation specifics, varied channel access
time and transmission time
- Unpredictable AP response time for downlink
traffic - Not applicable to AP experiencing jamming
co-located interferences - wireless residential gateway
- Not efficient to use with asymmetric or heavy
traffic (e.g. data, video, etc.) - video streaming
- additional overhead due to trigger frame / PS poll
16PER Performance with UAPSD
State of the Art
a) Uplink Trigger
b) Downlink Data
- Two .11g Links VoIP (54Mbps) Data (Variable)
- Interference Period 6 Bluetooth Slots
- High (up to 40) downlink PER due to varied
channel access time
17Limitations of 802.16e Sleep Mode
State of the Art
Class A
Listening
Sleep
Class B
Sleep Mode
Coexistence
Inactive
Active
- Not applicable to multiple interferences reports
with different pattern - Coarse granularity frame duration (5ms)
- Bluetooth Slot 625 us
- inefficient when only a small portion is
interfered - Little flexibility
- Rx and Tx may be treated differently in
coexistence - Little reliability Best-Effort
- coexistence is about avoiding interference and
protecting radio activities - reliability is important, and time info needs to
be respected - Other limitations
- Not applicable to other states (e.g. network
entry) - may be intended for other usage (scanning)
18Recap Why Time Sharing?
Media Independent TS
- Power / Frequency control is ineffective in
mitigating wideband co-located interference - further limited by other network factors, e.g.
channel, link budget, etc. - not support component sharing due to integration
- Low duty-cycle radio activity is possible
- broadband / MIMO techniques ? more bits/s
- 802.11 20MHz ? 40MHz
- 802.16 5MHz ? 10MHz ? 20MHz
- MIMO 1x2 ? 2x2 ? 4x4
- Media independent description of radio activity
is possible
- High Data Rate
- Coverage
- QoS Support
- Security
- Low Power
- Mobility
- Multi-Radio Coexistence
Design Considerations of an Air-Interface
19Media Independent Description of Radio Activity
Media Independent TS
t
Active
Inactive
Type 1 Duty Cycle
T
P
Type 2 Bitmap
1
0
0
0
1
1
0
0
0
1
1
0
0
B
- t starting time of an activity cycle
- T duration of each activity burst (Type 1)
- B bitmap (Type 2)
- x time unit
- P burst period i.e., interval between bursts
- ? both type 1 and type 2 descriptions can be
periodic, and P indicate the duration for one
period - N number of bursts
- s type of activity TX, RX, or both
20Explicit Coexistence Support
Media Independent TS
- Explicit Coexistence Feedback
- heterogeneous time granularity
- Bluetooth slot 625us, 802.11 Time Unit
1024us, 802.16 symbol 102.9us, 802.16 frame
5ms - Requirement 1 scalable time unit
- synchronization
- clock drift
- period mismatch
- Requirement 2 information update feedback
control - Explicit Coexistence Protection
- reliable and beyond best-effort
- link adaptation, scheduling, etc.
- Requirement 3 reliable protection
- Goal Media Access Control with multiple
constraints - QoS, channel condition, traffic arrival,
multi-radio coexistence,
21Time Sharing of 802.16 / 802.11 / 802.15.1
Activities
Media Independent TS
3.75ms
625us
M
S
802.15.1 HV3 (33)
5ms
802.16 frame Structure
DL
UL
DL
UL
DL
UL
802.16 Activity (58)
802.11 Activity (20)
15ms
Explicit coexistence support enables seamless
time sharing of radio activates, reduces the
collisions, and ensures desirable performance on
individual radio
Note the pattern may change over time if radios
are not in sync
22What is the benefit?
Media Independent TS
- Better User Experience
- support more multi-radio concurrent usages
- cheaper / smaller device without sacrificing
functionality performance - More efficient usage of wireless medium and
spectrum - prevent ill-guided air-interface behavior
- reduce frame loss and improve reliability
- seamless interaction among radios
- Easier and lower cost integration of multiple
wireless technologies - unified interface / signaling
- scale to number of radios and number of vendors
23 Media Independent TS
802.11v Co-located Interference Reporting
- Simple protocol enables terminal to indicate it
is using several radios simultaneously and
performance of WLAN RX is degraded - Report allows terminal to indicate interference
time characteristics, level, and other
information - Automatic reporting is supported, i.e., whenever
STA realize co-located interference is changed it
can send Report to AP - AP can use reported information several ways, 1)
it can schedule DL transmissions not to collide
with interference slots and 2) it can use
information to adjust e.g., rate adaptation and
retransmission logics
STA
AP
Co-located Interference Request
Other radio operation is started causing
performance degradation
Co-located Interference Report
Other radio operation is stopped
Co-located Interference Report
24Beyond IEEE
Media Independent TS
- Wi-Fi Alliance Converged Wireless Group (CWG) is
working to extend CWG RF Test Plan to cover
Bluetooth / Wi-Fi / Cellular coexistence testing - Bluetooth SIG is defining feature requirements
for coexistence with broadband wireless access
technologies, and Telephony Working Group (TWG)
is currently working towards publishing a
whitepaper to address Bluetooth/WiMAX coexistence - WiMAX Forum Coexistence Ad-Hoc has reviewed
contributions for WiMAX-BT and WiMAX-Wi-Fi
coexistence from Motorola, Altair-Semiconductor,
Nextwave and others. - Coexistence based on the perceived concurrency
approach - Key enabler is power save mode of WiMAX/Wi-Fi for
time sharing and BT MAC retransmission capability - Currently working on harmonizing on the key WiMAX
system requirements to support time sharing at
MAC level
25Summary
Conclusion
- Multi-radio concurrent usage is becoming the
norm, and coexistence is the limiting factor - Existing approaches are ineffective
- limited true concurrency (due to cost, size,
etc.) - best-effort perceived concurrency
- Media independent time-sharing is promising, but
coexistence-awareness in air interface is the
must - explicit coexistence feedback / protection
Is a more coordinated approach to support
coexistence in wireless necessary, or even
possible? http//www.youtube.com/watch?vRh0awIw7
PNY
26Call to Action
Conclusion
- Develop standard-based, scalable, and reliable
coexistence solutions, considering the following
issues - heterogeneous time granularity
- synchronization
- reliable protection
- Add explicit coexistence support to individual
air interface to enable - Predictability forecast activity for other
radios to react - Compressibility maintain radio duty cycles at
friendly level - Selectivity provide flexibility to (re) schedule
activity
27Thank You