Understanding MIMO and Spatial Multiplexing in Wireless Networks

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Graphical intuition and physical modeling of SIMO and MIMO channels, addressing the problem of wireless interference and leveraging multiple antennas for improved reception. Exploring concepts like zero-forcing receivers and spatial multiplexing for increased capacity and rate speed-up in wireless communication.


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  1. MIMO II: Physical Channel Modeling, Spatial Multiplexing COS 463: Wireless Networks Lecture 17 Kyle Jamieson

  2. Today 1. Graphical intuition in the I-Q plane 2. Physical modeling of the SIMO channel 3. Physical modeling of the MIMO channel 2

  3. The problem of wireless interference User A Channel Access Point (AP) I-Q plot: A send Channel AP receive AP can estimate the channel, so can decode User A s signal ( ) 3

  4. The problem of wireless interference User B I-Q plot: B send Channel AP receive AP can estimate the channel, so can decode User B s signal ( ) 4

  5. The problem of wireless interference User B User A I-Q plot: AP receive from A alone AP receive from B alone AP receive (A + B) 5

  6. Leveraging Multiple Antennas Now, the AP hears two received signals, one on each antenna: 2 Antenna 1 User A Access Point User A Antenna 2 Send Antenna 1 6

  7. Leveraging Multiple Antennas User B Antenna 1 User A 2 Mixture of A and B User B User A A2 Antenna 2 A2 = + A1 A1 Antenna 1 7

  8. Intuition: Zero-Forcing Receiver MIMO zero-forcing receiver 1. Rotateone antenna s signal ( ) 2. Sumthe two antennas signals together ( + ) User B User A Sum Sum A2 A2 A1 A1 Rotate Rotate 8

  9. Spatial Multiplexing: More Streams Send multiple streams of informationover each of the spatial paths between sender and receiver This is called spatial multiplexing Potential for increased capacity by a factor of N (minimum number of send or receive antennas): ( )bits/s/Hz C=BNlog 1+SNR Potential for a multiplicative rate speed-up 9

  10. Today 1. Graphical intuition in the I-Q plane 2. Physical modeling of the SIMO channel 3. Physical modeling of the MIMO channel 10

  11. Physical Modeling of Multi-Antenna Channels Gain intuition as to how the RF channel (ambient environment) impacts capacity Many physical antenna arrangement geometries possible Limit discussion today to linear antenna arrays, half- wavelength antenna spacing Details vary with more sophisticated antenna arrangements, but concepts do not 11

  12. Line-of-Sight SIMO Channel: A Second Look ? ? ? ?/2 antenna separation 1 Sendx 2 3 Receivey1, y2,y3 ?1 ?2 ?3 Vector notation for the system: = ? = ? + ? ???2??1 ???2??2 ???2??3 Wireless channel is now a three-tuple vector: = 12

  13. Line-of-Sight SIMO Channel: A Second Look ? ? ? ?/2 antenna separation 1 Sendx 2 3 Receivey1, y2,y3 ???2??1/ ???2??2/ ???2??3/ Wireless channel is now a three-tuple vector: = Wireless channel: Antenna separations: Assume ?1= ? ?2 ? +1 ?3 ? +?cos? 1 = ???2??/? ??? cos ? ??2? cos ? 2?cos? 13

  14. Line-of-Sight SIMO Channel: Spatial Signature ? ? ? ?/2 antenna separation 1 Sendx 2 3 Receivey1, y2,y3 The wireless channel decomposes into two components: 1 = ???2??/? ??? cos ? ??2? cos ? Path component Spatial Signature The angle of arrivalof the sender s signal at the receive array determines the spatial signature 14

  15. Line-of-Sight SIMO Channel: Maximal Ratio Combining (Review) ? ? ? ?/2 antenna separation 1 Sendx 2 3 Receivey1, y2,y3 Maximal ratio combining projects the received signals ?onto the receive spatial signature: ? = ? Reverses the phases in the spatial signature to aligneach antenna s component of the above sum SNR improvement but no multiplexing 15

  16. Today 1. Graphical intuition in the I-Q plane 2. Physical modeling of the SIMO channel 3. Physical modeling of the MIMO channel Line-of-Sight MIMO Channel Geographically-Separated Transmit Antennas Geographically-Separated Receive Antennas MIMO Link in Multipath 16

  17. The Line-of-Sight MIMO Channel Sendx1, x2, x3 1 2 3 ? 1 ?/2 antenna separation ?/2 2 3 ? ? ? Receivey1, y2,y3 ?1 ?2 ?3 Want to transmit three symbols per symbol time: ? = ???: channel between k th receive and lth transmit antenna 11 21 31 12 22 32 11 11 11 ? = H H ?, where H H = is the MIMO channel matrix 17

  18. The Line-of-Sight MIMO Channel: Channel Matrix Sendx1, x2, x3 1 2 3 ? 1 ?/2 antenna separation ?/2 2 3 ? ? ? Receivey1, y2,y3 ???: channel between k threceive and lthtransmit antenna Suppose as before, ?11= ? Then ???= ? +1 2? 1 cos? +1 2? 1 cos? Tx 2: Tx 3: Tx 1: ??? ??? ? ??? (cos?+cos?) ??? (2cos?+cos?) ??? 2cos? ??? (cos?+2cos?) ??? (2cos?+2cos?) 1 Channel matrix ? = ???2??/? ??? cos? ??2? cos? 18

  19. The Line-of-Sight MIMO Channel: Identical Spatial Signatures Sendx1, x2, x3 1 2 3 ? 1 ?/2 antenna separation ?/2 2 3 ? ? ? Receivey1, y2,y3 Tx 3: Tx 2: Tx 1: ??? ??? ? ??? (cos?+cos?) ??? (2cos?+cos?) ??? 2cos? ??? (cos?+2cos?) ??? (2cos?+2cos?) 1 Channel matrix ? = ???2??/? ??? cos? ??2? cos? Transmit antenna 2 s channel and spatial signature: 12 22 32 1 = ???2?? ?+cos? ??? cos? ??2? cos? 19

  20. The Line-of-Sight MIMO Channel: Takeaways Spatial signature: How to phase-shift received signals to align them Spatial signature of Transmit antenna 1 Equals spatial signature of Tx antenna 2, Tx antenna 3 So any receiver attempt to align signal from Transmit antenna 1 Also aligns transmit antennas 2 and 3 Result is interference between x1, x2, x3 Can send same single symbol x on all transmit antennas Results in same power gain as MRC 20

  21. Today 1. Graphical intuition in the I-Q plane 2. Physical modeling of the SIMO channel 3. Physical modeling of the MIMO channel Line-of-Sight MIMO Channel Geographically-Separated Transmit Antennas Geographically-Separated Receive Antennas MIMO Link in Multipath 21

  22. Geographically-Separated Transmit Antennas: Space-Division Multiple Access (SDMA) Sendx1, x2 1 1 ?/2 antenna separation ? ?2 2 ?1 2 Receivey1, y2 Tx 1: Tx 2: 1 1 Channel matrix ? = ???2??/? ??? cos ?1 ??? cos ?2 Sig. 2 Sig. 1 Different spatial signatures for Transmit Antenna 1,2 22

  23. Spatial Signature = Series of Phase Differences Tx 1: Tx 2: 1 1 Channel matrix ? = ???2??/? ??? cos ?1 ??? cos ?2 Sig. 2, ??? Sig. 1, ??? From Transmit Antenna 2: From Transmit Antenna 1: At Receive Antenna 1 At Receive Antenna 1 + Sig. 1 Sig. 2 At Receive Antenna 2 At Receive Antenna 2 23

  24. The Zero-Forcing Receiver (via Spatial Signatures) Suppose want to receive from Transmit Antenna 1 (Recall:) Rotate Receive Antenna 2 s signal so that Signature 2 cancels itself From Transmit Antenna 2: From Transmit Antenna 1: At Receive Antenna 1 At Receive Antenna 1 + Sig. 1 Sig. 2 At Receive Antenna 2 At Receive Antenna 2 24

  25. The Zero-Forcing Receiver (via Spatial Signatures) ??? ? One spatial signature = One direction Zero forcing Antenna 2 is projection Onto subspace to ??? ??? From Transmit Antenna 2: From Transmit Antenna 1: At Receive Antenna 1 At Receive Antenna 1 + Sig. 1 Sig. 2 At Receive Antenna 2 At Receive Antenna 2 25

  26. MIMO Separability: Discussion Transmit antenna separation Spatial signature separation Better projection, Better performance ??? ? ??? MIMO antenna array without multipath No transmit antenna separation No spatial signature separation Cancel Tx Ant 2: cancels Tx Ant 1 No spatial multiplexing ??? ? ??? 26

  27. Today 1. Graphical intuition in the I-Q plane 2. Physical modeling of the SIMO channel 3. Physical modeling of the MIMO channel Line-of-Sight MIMO Channel Geographically-Separated Transmit Antennas Geographically-Separated Receive Antennas MIMO Link in Multipath 27

  28. Geographically-Separated Receive Antennas: SDMA Downlink Different spatial signatures for Receive Antennas 1,2 Rows, instead of columns in the MIMO matrix 28

  29. MIMO in Multipath 1 Antenna 1 2 d1 Transmitter Antenna 2 Receiver Antenna 1 1 d2 Antenna 2 2 Tx antenna 2: Tx antenna 1: ?1??2??1 ?+cos?1+cos?1+?2??2??2 ?+cos?1+?2??2??2 ?+cos?2 ?1??2??1/?+?2??2??2/? ?1??2??1 H H = ?+cos?1+?2??2??2 ?1??2??1 ?+cos?2 ?+cos?2+cos?2 Neither column is a multiple of the other So H has two different transmit antenna spatial signatures 29

  30. Different Spatial Signatures: Intuition 1 Antenna 1 2 d1 Transmitter Antenna 2 A Receiver Antenna 1 1 d2 Antenna 2 2 B Channel matrix H has two different spatial signatures Imagine perfect signal relays A, B This H is the product of: Geographically-separated receive antenna channel Geographically-separated transmit antenna channel 30

  31. Poorly-Conditioned MIMO channels Receiver !1 Antenna 1 !2 Transmitter Antenna 2 Only reflectors near receiver: 1 2 Antenna 1 "1 Antenna 2 "2 !1 Antenna 1 !2 Transmitter Antenna 2 Only reflectors near transmitter: 1 2 Receiver Antenna 1 "1 Antenna 2 "2 h1 h2 When channel is poorly conditioned, spatial signatures are closer aligned 31

  32. How Many Streams are Possible? Received signals live in an nr-dimensional vector space e.g.nr = 3 receive antennas 3-D vector space: Cancel by projection. Therefore, at most nr streams possible 32

  33. How Many Streams are Possible? One spatial signature per transmit antenna e.g.nr = 3 receive, nt = 2 transmit antennas: h2 h1 Therefore, at most nt streams possible 33

  34. How Many Streams are Possible? Need enough strong physical paths in the wireless channel e.g.nr = 3, nt= 3buttwo physical paths confines { hi} to a plane h2 h3 h1 At most # physical paths possible streams 34

  35. How Many Streams are Possible? Need enough strong physical paths in the wireless channel e.g.nr = 3, nt= 3 and three physical paths h1 Proj Proj ?2,?3?1 h2 h3 h1 At most # physical paths possible streams 35

  36. Degrees of Freedom The figure of merit that summarizes the number of streams possible is called the number of degrees of freedom of H h1 h2 h3 Degrees of freedom = min { nt , nr , # strong paths } 36

  37. Summary Spatial multiplexing requires either: Spatially-separated receivers / transmitters (SDMA), or Multiple antennas at both ends of a link (MIMO), and Enough physical channel propagation paths Degrees of freedom quantify spatial multiplexing potential 37

  38. Tuesday Topic: MIMO III: Channel Capacity, Interference Alignment 38

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