Title: EECS%20380:%20Wireless%20Communications%20CDMA
1EECS 380 Wireless CommunicationsCDMA
Michael L. Honig Department of EECS Northwestern
University
May 2011
2The Multiple Access Problem
How can multiple mobiles access (communicate
with) the same base station?
- Use different frequencies (FDMA)
- Use different time slots (TDMA)
- Use different pulse shapes (CDMA)
- Use some combination of frequencies and time
slots (OFDMA)
3Two-User Example
1
0
bits
1
1
0
1
User 1
s1(t)
T
T/2
time
T
3T
2T
4T
5T
-1
chips
0
1
1
1
0
s2(t)
User 2
T
T
2T
3T
4T
5T
T/2
time
2
received signal r(t) s1(t)s2(t)
T
2T
4T
5T
3T
-2
4Orthogonality and Asynchronous Users
1
1
0
1
0
1
s1(t)
T
3T
2T
4T
5T
-1
1
0
1
1
0
s2(t)
T
2T
3T
4T
5T
time
Asynchronous users can start transmissions at
different times.
- Orthogonality among users requires
- Synchronous transmissions
- No multipath
5Correlator, or Matched Filter Receiver
delay
user 1's symbol multiple acess interference
(MAI) from user 2
s1(t) s2(t-?)
user 2's symbol multiple acess interference
(MAI) from user 1
6Processing Gain (PG)
7Processing Gain (PG)
- Fundamental tradeoff increasing the PG
- decreases the correlation between random
signatures. - decreases interference.
- increases the bandwidth of the signal.
8Correlation and Bandwidth
0
frequency
correlation between s1 and s2 ? multiple access
interference
s2
9Properties of CDMA
- Robust with respect to interference
- No frequency assignments (eases frequency
planning) - Asynchronous
- High capacity with power control
- Power control needed to solve near-far problem.
- Wideband benefits from frequency/path diversity.
- Benefits from voice inactivity and sectorization.
- No loss in trunking efficiency.
- Soft capacity performance degrades gradually as
more users are added. - Soft handoff
10Near-Far Problem
SO THEN THE THIRD TIME I CALLED CUSTOMER
SERVICE, I SAID
11Near-Far Problem
amplitude A1
User 1
amplitude A2
User 2
A1A2 (correlation of s1 and s2)
User 1s bits
A1 s1(t)A2 s2(t)
Output of correlator receiver is signal
interference. As the interferer moves closer to
the base station, the interference increases. In
practice, power variations can be up to 80 dB!
12Closed-Loop Power Control
raise power
User 1
lower power
User 2
13Closed-Loop Power Control
raise power
User 1
lower power
User 2
14Closed-Loop Power Control Properties
raise power
User 1
lower power
User 2
15Properties of CDMA
- Robust with respect to interference
- No frequency assignments (eases RF planning).
- Asynchronous
- High capacity with power control.
- Power control needed to solve near-far problem.
- Wideband benefits from frequency/path diversity.
- Benefits from voice inactivity and sectorization.
- No loss in trunking efficiency.
- Soft capacity performance degrades gradually as
more users are added. - Soft handoff
16Bandwidth and Multipath Resolution
reflection (path 2)
direct path (path 1)
multipath components are resolvable
??(delay spread)
signal pulse
signal pulse
?
T lt ?
T gt ?
T
17CDMA and Path Diversity
- CDMA uses wideband signals (chips are very narrow
pulses), which makes much of the multipath
resolvable. - A RAKE receiver collects (rakes up) the
energy in the paths
?
power delay profile
received signal
received signal with combined multipath
18Properties of CDMA
- Robust with respect to interference
- No frequency assignments (eases RF planning).
- Asynchronous
- High capacity with power control.
- Power control needed to solve near-far problem.
- Wideband benefits from frequency/path diversity.
- Soft capacity performance degrades gradually as
more users are added. - Benefits from voice inactivity and sectorization.
- No loss in trunking efficiency.
- Soft handoff
19CDMA Capacity
- Performance depends on
- Let S Transmitted power (per user), R
information rate (bits/sec), - W Bandwidth, K Number of users
- Eb S/R (energy per second / bits per second)
- N0 (Number of interferers x S)/W ((K-1) x S)/W
- Therefore Eb/N0 (W/R)/(K-1) (Processing
Gain)/(K-1) - For a target Eb/N0, the number of users that can
be supported - is K (Processing Gain)/(Eb/N0) 1
20CDMA Capacity
- Performance depends on
- Let S Transmitted power (per user), R
information rate (bits/sec), - W Bandwidth, K Number of users
- Eb S/R (energy per second / bits per second)
- N0 (Number of interferers x S)/W ((K-1) x S)/W
- Therefore Eb/N0 (W/R)/(K-1) (Processing
Gain)/(K-1) - For a target Eb/N0, the number of users that can
be supported - is K (Processing Gain)/(Eb/N0) 1
21CDMA Capacity
- Performance depends on
- Let S Transmitted power (per user), R
information rate (bits/sec), - W Bandwidth, K Number of users
- Eb S/R (energy per second / bits per second)
- N0 (Number of interferers x S)/W ((K-1) x S)/W
- Therefore Eb/N0 (W/R)/(K-1) (Processing
Gain)/(K-1) - For a target Eb/N0, the number of users that can
be supported - is K (Processing Gain)/(Eb/N0) 1
22CDMA Capacity Example
- For IS-95, want Eb/N0 7 dB
- For 3G, want Eb/N0 3 to 5 dB
- Suppose W1.25 MHz (single-duplex), R 14.4 kbps,
target Eb/N0 7 dB - K 1 (1.25 106)/(14.4 103)/5.01 ? 18
- Compare with GSM, cluster size N3
- K 8 (users/channel) ( of 200 kHz channels)
- 8 1.25 106 / (200 103 3) ? 16
23Increasing CDMA Capacity
24Increasing CDMA Capacity
- Must reduce interference
- Antenna sectorization
- Interference reduced by 1/3
- Trunking efficiency is not a majorissue (no
channels/time slots). - Voice inactivity automatically increasesthe
capacity relative to TDMA with dedicatedtime
slots. - CDMA has a soft capacity each additional user
marginally degrades performance for all users.
25Properties of CDMA
- Robust with respect to interference
- No frequency assignments (eases RF planning).
- Asynchronous
- High capacity with power control.
- Power control needed to solve near-far problem.
- Wideband benefits from frequency/path diversity.
- Soft capacity performance degrades gradually as
more users are added. - Benefits from voice inactivity and sectorization.
- No loss in trunking efficiency.
- Soft handoff
26Interference and CDMA Capacity
- If interference is reduced by a factor 1/g, then
the number of - interferers can be increased by g (N0 is replaced
by g x N0) - If W/R is large, then reducing interference by
1/g - (approximately) increases the capacity by a
factor of g.
27Refining the Capacity Estimate
- Capacity for previous example is 9 18 ? 162
- Have not accounted for
- Other-cell interference
- Approximately 1/3 to 1/2 of total interference
powerK ? 1/(11/2) K ? 108 - Multipath / fading
- Some multipath is combined by the Rake receiver,
the rest is interference - Power control inaccuracy
28Properties of CDMA
- Robust with respect to interference
- No frequency assignments (eases RF planning).
- Asynchronous
- High capacity with power control.
- Power control needed to solve near-far problem.
- Wideband benefits from frequency/path diversity.
- Benefits from voice inactivity and sectorization.
- No loss in trunking efficiency.
- Soft capacity performance degrades gradually as
more users are added. - Soft handoff
29Soft Handoff (CDMA) Make before break
DURING
AFTER
BEFORE
MSC
MSC
MSC
BSC
BSC
BSC
BSC
BSC
BSC
Hard Handoff (TDMA)
MSC
MSC
MSC
BSC
BSC
BSC
BSC
BSC
BSC
30Applications of Spread-Spectrum
- Military (preceded cellular applications)
- Cellular
- Wireless LANs (overlay)
31Military Spread Spectrum
- Can hide a signal by spreading it out in the
frequency domain. - Requires a very large PG (several 100 to 1000).
- Enemy must know spreading code (the key
containing 100s of bits) to demodulate too
complicated for simple search. - Spread spectrum signals have the LPI/LPD
property low probability of intercept / low
probability of detect.
spread
noise level
frequency
0
0
frequency
32Applications of Spread-Spectrum
- Military (preceded cellular applications)
- Cellular
- Wireless LANs (overlay)
33CDMA vs. TDMA(early 1990s)
TDMA
CDMA
342G CDMA IS-95 or cdmaOne
- Introduced by Qualcomm (San Diego)
- Direct-Sequence Spread Spectrum signaling
- FDD
- Wideband channels (1.25 MHz)
- Tight, closed-loop power control
- Sophisticated error control coding
- Multipath combining to exploit path diversity
- Noncoherent detection
- Soft handoff
- High capacity
- Air-interface only uses IS-41
35TDMA vs. CDMAPerformance Critera
Capacity Users per Hz per km2
Channel conditions System assumptions Perfect
power control? Modulation and coding?
Complexity
Power control (CDMA) Synchronization
(TDMA) Equalization Frequency assignment
Flexibility
Integrated services (voice/data) Multimedia Va
riable rate/QoS
363G Air Interfaces
- Also referred to as multicarrier CDMA
- 1X Radio Transmission Technology (RTT) 1.25 MHz
bandwidth (1 carrier) - Supports 307 kbps instantaneous data rate in
packet mode - Expected throughput up to 144 kbps
- 1xEV (Evolutionary) High Data Rate standard
introduced by Qualcomm - 1xEV-DO data only, 1xEV-DV data and voice
- Radio channels assigned to single users (not
CDMA!) - 2.4 Mbps possible, expected throughputs are a few
hundred kbps - 1xEV-DV has twice as many voice channels as IS-95B
37Service Providers and Technologies
Verizon Cellular PCS (850 1900 MHz) CDMA 20001 x EV-DO LTE 8-128 Kbps up to 2.5 Mbps
ATT/Cingular Cellular (850 1900 MHz) GSM/GPRS/EDGE UMTS/HSPA up to 512 kbps
Sprint Clearwire PCS (1900 MHz) CDMA2000 1 x EV-DO WiMax 8-128 Kbps up to 2.5 Mbps
T-Mobile PCS (1900 MHz) GSM/GPRS/EDGE UMTS/HSPA 8-350 Kbps
NexTel Public service band (800 MHz) iDEN (TDMA) WiDEN4 25-64 kbps near 100 kpbs
U. S. Cellular Cellular PCS (850 1900 MHz) 1 x EV-DO up to 2.5 Mbps
4Wideband version of iDEN.
1Merged with Sprint. 2Limited LTE coverage.
3Limited WiMax coverage.
38Applications of Spread-Spectrum
- Military (preceded cellular applications)
- Cellular
- Wireless LANs (underlay)
39Spread Spectrum Underlay
- FCC requirements on spectrum sharing in the
unlicensed (Industrial, Scientific, Medical
(ISM)) bands - Listen before talk
- Transmit power is proportional to the square root
of the bandwidth.
telemetry
hospital monitor
spread spectrum signal
frequency
40Spread Spectrum Underlay
- FCC requirements on spectrum sharing in the
unlicensed (Industrial, Scientific, Medical
(ISM)) bands - Listen before talk
- Transmit power is proportional to the square root
of the bandwidth. - Spread spectrum signaling is robust with respect
to a narrowband interferer. - To a narrowband signal, a spread spectrum signal
appears as low-level background noise.
telemetry
hospital monitor
spread spectrum signal
frequency
41Variable-Rate CDMA
42Variable-Rate CDMA
- To increase the data rate we can
- Increase the number of signatures per user
- More signatures ? more power, more interference
- Reduce the number of chips per bit
- Decreases immunity to interference (must increase
power) - Increase the number of bits per symbol
- QPSK ? 8-PSK ? 16 QAM requires more power
- How is voice capacity affected by the presence of
high-rate data users?
43Frequency-Hopped CDMA
44Hop Rate
- Can make synchronous users orthogonal by
assigning hopping patterns that avoid collisions. - Fast hopping generally means that the hopping
period is less than a single symbol period. - Slow hopping means the hopping period spans a
few symbols. - The hopping rate should be faster than the fade
rate (why?).
45Hop Rate
- Can make synchronous users orthogonal by
assigning hopping patterns that avoid collisions. - Fast hopping generally means that the hopping
period is less than a single symbol period. - Slow hopping means the hopping period spans a
few symbols. - The hopping rate should be faster than the fade
rate so that the channel is stationary within
each hop.
46Properties of FH-CDMA
47Properties of FH-CDMA
- Exploits frequency diversity (can hop in/out of
fades) - Can avoid narrowband interference (hop around)
- No near-far problem (Can operate without power
control) - Low Probability of Detect/Intercept
- Spread spectrum technique can overlay
- Cost of frequency synthesizer increases with hop
rate - Must use error correction to compensate for
erasures due to fading and collisions. - Applications
- Military (army)
- Part of original 802.11 standard
- Enhancement to GSM
- Bluetooth
481.
491. 2.
501. 2.
511. 2.
52Inventor of Frequency-Hopping
53Bluetooth A Global Specification for Wireless
Connectivity
- Wireless Personal Area Network (WPAN).
- Provides wireless voice and data over short-range
radio links via low-cost, low-power radios
(wireless cable). - Initiated by a consortium of companies (IBM,
Ericsson, Nokia, Intel) - Standard has been developed (IEEE 802.15.1 ).
54Bluetooth Specifications
- Allows small portable devices to communicate
together in an ad-hoc piconet (up to eight
connected devices). - Frequency-hopped spread-spectrum in the 2.4 GHz
UNII band. - 1600 hops/sec over 79 channels (1 MHz channels)
- Range set at 10m.
- Gross data rate of 1 Mbps (TDD).
- 64 kbps voice channels
- Interferes with 802.11b/g
- Second generation (Bluetooth 2.0) supports rates
up to 3 Mbps.Competes with Wireless USB.
55The Multiple Access Problem
How can multiple mobiles access (communicate
with) the same base station?
- Frequency-Division (AMPS)
- Time-Division (IS-136, GSM)
- Code-Division (IS-95, 3G)Direct
Sequence/Frequency-Hopped - Orthogonal Frequency Division Multiple Access
(OFDMA) (WiMax, LTE) - Random Access (Wireless Data)
56Orthogonal Frequency Division Multiplexing (OFDM)
substream 1
substream 2
source bits
substream M
OFDM Signal
57OFDM Spectrum
Total available bandwidth
Data spectrum for a single carrier
Power
f4
f1
f5
f6
f3
f2
frequency
? 0
subchannels
58OFDM vs OFDMA
- OFDM is a modulation technique for a particular
user. - OFDMA is a multiple access scheme (allows many
users to access a single receiver). - Can OFDM be combined other multiple access
techniques?
59OFDM vs OFDMA
- OFDM is a modulation technique for a particular
user. - OFDMA is a multiple access scheme (allows many
users to access a single receiver). - Can OFDM be combined other multiple access
techniques? - Yes, e.g., FDMA and TDMA.
- OFDMA is different
60OFDM vs OFDMA
61OFDM vs OFDMA
62Each color represents a different user, which is
assigned particular time slots.
OFDM/TDMA
subchannels
Different sub-carriers can be assigned to
different users.
time slot
- Each user can be assigned a time/frequency slice.
- Requires a time/frequency scheduler.
63WiMax OFDMA Frame Structure (TDD example)
(downlink)
(uplink)
64Adaptive Rate Control
channel gain
large channel gain ? higher data rate
small channel gain ? lower data rate
f1
f2
frequency
65Adaptive Rate Control
channel gain
large channel gain ? higher data rate
small channel gain ? lower data rate
f1
f2
frequency