1. Talk at the American University of Beirut
Wireless Networking and Communications Group
Radio Frequency Interference Sensing and Mitigation in Wireless Receivers
Prof. Brian L. Evans
Lead Graduate Students
Aditya Chopra, Kapil Gulati and Marcel Nassar
In collaboration with Eddie Xintian Lin, Chaitanya Sreerama, Keith R. Tinsley and Jorge Aguilar Torrentera at Intel Labs
23 June 2009
Talk at the American University of Beirut

2. Outline Problem definition Single carrier single antenna systems2
Problem definition
Single carrier single antenna systems
Radio frequency interference modeling
Estimation of interference model parameters
Filtering/detection
Multi-input multi-output (MIMO) single carrier systems
Co-channel interference modeling (submitted)
Conclusions
Future work
Wireless Networking and Communications Group

3. Radio Frequency Interference
RFI limits wireless communication performance
Applications of RFI modeling
Sense and mitigate strategies for coexistence of wireless networks and services
Sense and avoid strategies for cognitive radio
We focuses on sense and mitigate strategies for wireless receivers embedded in notebooks
Platform noise from user’s computer subsystems
Co-channel interference from other in-band wireless networks and services

4. We will use noise and interference interchangeably
Problem Definition 4
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Within computing platforms, wireless transceivers experience radio frequency interference from clocks and busses
Objectives
Develop offline methods to improve communication performance in presence of computer platform RFI
Develop adaptive online algorithms for these methods
Approach
Statistical modeling of RFI
Filtering/detection based on estimated model parameters
We will use noise and interference interchangeably
Wireless Networking and Communications Group

5. Impact of RFI 5
Impact of LCD noise on throughput for an IEEE g embedded wireless receiver [Shi, Bettner, Chinn, Slattery & Dong, 2006]
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Wireless Networking and Communications Group

6. Statistical Modeling of RFI6
Radio Frequency Interference (RFI)
Sum of independent radiation events
Predominantly non-Gaussian impulsive statistics
Key Statistical-Physical Models
Middleton Class A, B, C models
Independent of physical conditions (Canonical)
Sum of independent Gaussian and Poisson interference
Model non-linear phenomenon governing RFI
Symmetric Alpha Stable models
Approximation of Middleton Class B model
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Wireless Networking and Communications Group

7. Assumptions for RFI Modeling7
Key Assumptions for Middleton and Alpha Stable Models [Middleton, 1977][Furutsu & Ishida, 1961]
Infinitely many potential interfering sources with same effective radiation power
Power law propagation loss
Poisson field of interferers with uniform intensity l
Pr(number of interferers = M |area R) ~ Poisson(M; lR)
Uniformly distributed emission times
Temporally independent (at each sample time)
Limitations
Alpha Stable models do not include thermal noise
Temporal dependence may exist
Wireless Networking and Communications Group

8. Our Contributions 8
Mitigation of computational platform noise in single carrier, single antenna systems [Nassar, Gulati, DeYoung, Evans & Tinsley, ICASSP 2008, JSPS 2009]
Computer Platform Noise Modelling
Evaluate fit of measured RFI data to noise models
Middleton Class A model
Symmetric Alpha Stable
Parameter Estimation
Evaluate estimation accuracy vs complexity tradeoffs
Filtering / Detection
Evaluate communication performance vs complexity tradeoffs
Middleton Class A: Correlation receiver, Wiener filtering, and Bayesian detector
Symmetric Alpha Stable: Myriad filtering, hole punching, and Bayesian detector
Wireless Networking and Communications Group

9. Middleton Class A model9
Probability Density Function
PDF for A = 0.15, = 0.8
Parameter
Description
Range
Overlap Index. Product of average number of emissions per second and mean duration of typical emission
A  [10-2, 1]
Gaussian Factor. Ratio of second-order moment of Gaussian component to that of non-Gaussian component
Γ  [10-6, 1]
Wireless Networking and Communications Group

10. Symmetric Alpha Stable Model
1010
Characteristic Function
Closed-form PDF expression only for α = 1 (Cauchy), α = 2 (Gaussian), α = 1/2 (Levy), α = 0 (not very useful)
Approximate PDF using inverse transform of power series expansion
Second-order moments do not exist for α < 2
Generally, moments of order > α do not exist
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PDF for  = 1.5,  = 0,  = 10
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Parameter
Description
Range
Characteristic Exponent. Amount of impulsiveness
Localization. Analogous to mean
Dispersion. Analogous to variance
Wireless Networking and Communications Group

11. Example Power Spectral Densities
Middleton Class A
Symmetric Alpha Stable
Overlap Index (A) = 0.15
Gaussian Factor (G) = 0.1
Characteristic Exponent (a) = 1.5
Localization (d) = 0
Dispersion (g) = 10

12. Estimation of Noise Model Parameters12
Middleton Class A model
Expectation Maximization (EM) [Zabin & Poor, 1991]
Find roots of second and fourth order polynomials at each iteration
Advantage: Small sample size is required (~1000 samples)
Disadvantage: Iterative algorithm, computationally intensive
Symmetric Alpha Stable Model
Based on Extreme Order Statistics [Tsihrintzis & Nikias, 1996]
Parameter estimators require computations similar to mean and standard deviation computations
Advantage: Fast / computationally efficient (non-iterative)
Disadvantage: Requires large set of data samples (~10000 samples)
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Wireless Networking and Communications Group

13. Results on Measured RFI Data13 13
25 radiated computer platform RFI data sets from Intel
50,000 samples taken at 100 MSPS
Estimated Parameters for Data Set #18
Symmetric Alpha Stable Model
Localization (δ)
0.0065
KL Divergence
0.0308
Characteristic exp. (α)
1.4329
Dispersion (γ)
0.2701
Middleton Class A Model
Overlap Index (A)
0.0854
0.0494
Gaussian Factor (Γ)
0.6231
Gaussian Model
Mean (µ)
0.1577
Variance (σ2) 1
KL Divergence: Kullback-Leibler divergence
Wireless Networking and Communications Group

14. Results on Measured RFI Data14
Best fit for 25 data sets under different platform RFI conditions
KL divergence plotted for three candidate distributions vs. data set number
Smaller KL value means closer fit
Gaussian
Class A
Alpha Stable

15. Video over Impulsive Channels15
Video demonstration for MPEG II video stream
10.2 MB compressed stream from camera (142 MB uncompressed)
Compressed file sent over additive impulsive noise channel
Binary phase shift keying Raised cosine pulse 10 samples/symbol 10 symbols/pulse length
Composite of transmitted and received MPEG II video streams
9dB_correlation.wmv
Shows degradation of video quality over impulsive channels with standard receivers (based on Gaussian noise assumption)
Additive Class A Noise
Value
Overlap index (A)
0.35
Gaussian factor (G)
0.001
SNR
19 dB
Wireless Networking and Communications Group

16. Filtering and Detection
Assumption
Multiple samples of the received signal are available
N Path Diversity [Miller, 1972]
Oversampling by N [Middleton, 1977] 16
Impulsive Noise
Pulse
Shaping
Pre-Filtering
Matched Filter
Detection Rule
Middleton Class A noise
Symmetric Alpha Stable noise
Filtering
Wiener Filtering (Linear)
Detection
Correlation Receiver (Linear)
Bayesian Detector [Spaulding & Middleton, 1977]
Small Signal Approximation to Bayesian detector [Spaulding & Middleton, 1977]
Filtering
Myriad Filtering
Optimal Myriad [Gonzalez & Arce, 2001]
Selection Myriad
Hole Punching [Ambike et al., 1994]
Detection
Correlation Receiver (Linear)
MAP approximation [Kuruoglu, 1998]
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Wireless Networking and Communications Group

17. Results: Class A Detection17
Communication Performance
Binary Phase Shift Keying
Pulse shape Raised cosine 10 samples per symbol 10 symbols per pulse
Channel A = 0.35  = 0.5 × 10-3 Memoryless
Method
Comp. Complexity
Detection Perform.
Correl.
Low
Wiener
Medium
Bayesian S.S. Approx.
High
Bayesian
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Wireless Networking and Communications Group

18. Results: Alpha Stable Detection18
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Communication Performance
Same transmitter settings as previous slide
Method
Comp. Complexity
Detection Perform.
Hole Punching
Low
Medium
Selection Myriad
MAP Approx.
High
Optimal Myriad
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Use dispersion parameter g in place of noise variance to generalize SNR
Wireless Networking and Communications Group

19. Video over Impulsive Channels #219
Video demonstration for MPEG II video stream revisited
5.9 MB compressed stream from camera (124 MB uncompressed)
Compressed file sent over additive impulsive noise channel
Binary phase shift keying Raised cosine pulse 10 samples/symbol 10 symbols/pulse length
Composite of transmitted video stream, video stream from a correlation receiver based on Gaussian noise assumption, and video stream for a Bayesian receiver tuned to impulsive noise
9dB.wmv
Additive Class A Noise
Value
Overlap index (A)
0.35
Gaussian factor (G)
0.001
SNR
19 dB
Wireless Networking and Communications Group

20. Video over Impulsive Channels #2
Structural similarity measure (SSIM) to assess video quality
Score is [0,1] where higher means better video quality
Bit error rates for ~80 million bits sent:
6 x 10-6 for correlation receiver
0 for RFI mitigating receiver (Bayesian)
Frame number

21. Extensions to MIMO systems21
Radio Frequency Interference Modeling and Receiver Design for MIMO systems
RFI Model
Spatial Corr.
Physical Model
Comments
Middleton Class A No
Yes
Uni-variate model
Assume independent or uncorrelated noise for multiple antennas
Receiver design:
[Gao & Tepedelenlioglu, 2007] Space-Time Coding [Li, Wang & Zhou, 2004] Performance degradation in receivers
Weighted Mixture of Gaussian Densities
Not derived based on physical principles
Receiver design: [Blum et al., 1997] Adaptive Receiver Design
Bivariate Middleton Class A [McDonald & Blum, 1997]
Extensions of Class A model to two-antenna systems
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Wireless Networking and Communications Group

22. Our Contributions 22
2 x 2 MIMO receiver design in the presence of RFI [Gulati, Chopra, Heath, Evans, Tinsley & Lin, Globecom 2008]
RFI Modeling
Evaluated fit of measured RFI data to the bivariate Middleton Class A model [McDonald & Blum, 1997]
Includes noise correlation between two antennas
Parameter Estimation
Derived parameter estimation algorithm based on the method of moments (sixth order moments)
Performance Analysis
Demonstrated communication performance degradation of conventional receivers in presence of RFI
Bounds on communication performance [Chopra , Gulati, Evans, Tinsley, and Sreerama, ICASSP 2009]
Receiver Design
Derived Maximum Likelihood (ML) receiver
Derived two sub-optimal ML receivers with reduced complexity
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Wireless Networking and Communications Group

23. Results: RFI Mitigation in 2 x 2 MIMO23
Improvement in communication performance over conventional Gaussian ML receiver at symbol error rate of 10-2 A
Noise Characteristic
Improve-ment
0.01
Highly Impulsive
~15 dB
0.1
Moderately Impulsive
~8 dB 1
Nearly Gaussian
~0.5 dB
Communication Performance (A = 0.1, 1= 0.01, 2= 0.1, k = 0.4)
Wireless Networking and Communications Group

24. Results: RFI Mitigation in 2 x 2 MIMO24
Complexity Analysis for decoding M-level QAM modulated signal
Receiver
Quadratic Forms
Exponential
Comparisons
Gaussian ML M2
Optimal ML
2M2
Sub-optimal ML (Four-Piece)
Sub-optimal ML (Two-Piece)
Complexity Analysis
Communication Performance (A = 0.1, 1= 0.01, 2= 0.1, k = 0.4)
Wireless Networking and Communications Group

25. Co-Channel Interference Modeling25
Alpha Stable and Middleton Class A distributions applicable
Region of interferer locations determines interference model
Symmetric Alpha Stable
Middleton Class A
Wireless Networking and Communications Group

26. Co-Channel Interference Modeling26
Propose unified framework to derive narrowband interference models for ad-hoc and cellular network environments
Key Result: Tail Probabilities
Case 1: Ad-hoc network
Case 2-a: Cellular network (Base Station)
Interference threshold (a)
Interference threshold (a)
Wireless Networking and Communications Group

27. Conclusions Radio Frequency Interference from computing platform27
Radio Frequency Interference from computing platform
Affects wireless data communication transceivers
Models include Middleton and alpha stable distributions
RFI mitigation can improve communication performance
Single carrier, single antenna systems
Linear and non-linear filtering/detection methods explored
Single carrier, multiple antenna systems
Optimal and sub-optimal receivers designed
Bounds on communication performance in presence of RFI
Results extend to co-channel interference modeling
Wireless Networking and Communications Group

28. RFI Mitigation Toolbox28
Provides a simulation environment for
RFI generation
Parameter estimation algorithms
Filtering and detection methods
Demos for communication performance analysis
Latest Toolbox Release
Version 1.2, Feb 7th 2009
Snapshot of a demo
Wireless Networking and Communications Group

29. Other Contributions Publications Project Website [Journal Articles]29
Publications
[Journal Articles]
M. Nassar, K. Gulati, M. R. DeYoung, B. L. Evans and K. R. Tinsley, “Mitigating Near-Field Interference in Laptop Embedded Wireless Transceivers”, Journal of Signal Processing Systems, invited paper.
[Conference Papers]
M. Nassar, K. Gulati, A. K. Sujeeth, N. Aghasadeghi, B. L. Evans and K. R. Tinsley, “Mitigating Near-field Interference in Laptop Embedded Wireless Transceivers”, Proc. IEEE Int. Conf. on Acoustics, Speech, and Signal Proc., Mar. 30-Apr. 4, 2008, Las Vegas, NV USA.
K. Gulati, A. Chopra, R. W. Heath Jr., B. L. Evans, K. R. Tinsley, and X. E. Lin, “MIMO Receiver Design in the Presence of Radio Frequency Interference”, Proc. IEEE Int. Global Communications Conf., Nov. 30-Dec. 4th, 2008, New Orleans, LA USA.
A. Chopra, K. Gulati, B. L. Evans, K. R. Tinsley, and C. Sreerama, “Performance Bounds of MIMO Receivers in the Presence of Radio Frequency Interference”, Proc. IEEE Int. Conf. on Acoustics, Speech, and Signal Proc., Apr , 2009, Taipei, Taiwan, accepted.
Project Website
Wireless Networking and Communications Group

30. Future Work Extend RFI modeling for30
Extend RFI modeling for
Adjacent channel interference
Multi-antenna systems
Temporally correlated interference
Multi-input multi-output (MIMO) single carrier systems
RFI modeling and receiver design
Multicarrier communication systems
Coding schemes resilient to RFI
System level techniques to reduce computational platform generated RFI
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Wireless Networking and Communications Group

31. 31
Thank You. Questions ?
Wireless Networking and Communications Group

32. References RFI Modeling Parameter Estimation32
RFI Modeling
[1] D. Middleton, “Non-Gaussian noise models in signal processing for telecommunications: New methods and results for Class A and Class B noise models”, IEEE Trans. Info. Theory, vol. 45, no. 4, pp , May 1999.
[2] K.F. McDonald and R.S. Blum. “A physically-based impulsive noise model for array observations”, Proc. IEEE Asilomar Conference on Signals, Systems& Computers, vol 1, 2-5 Nov
[3] K. Furutsu and T. Ishida, “On the theory of amplitude distributions of impulsive random noise,” J. Appl. Phys., vol. 32, no. 7, pp. 1206–1221, 1961.
[4] J. Ilow and D . Hatzinakos, “Analytic alpha-stable noise modeling in a Poisson field of interferers or scatterers”,  IEEE transactions on signal processing, vol. 46, no. 6, pp , 1998.
Parameter Estimation
[5] S. M. Zabin and H. V. Poor, “Efficient estimation of Class A noise parameters via the EM [Expectation-Maximization] algorithms”, IEEE Trans. Info. Theory, vol. 37, no. 1, pp , Jan
[6] G. A. Tsihrintzis and C. L. Nikias, "Fast estimation of the parameters of alpha-stable impulsive interference", IEEE Trans. Signal Proc., vol. 44, Issue 6, pp , Jun. 1996
RFI Measurements and Impact
[7] J. Shi, A. Bettner, G. Chinn, K. Slattery and X. Dong, "A study of platform EMI from LCD panels - impact on wireless, root causes and mitigation methods,“ IEEE International Symposium on Electromagnetic Compatibility, vol.3, no., pp , Aug. 2006
Wireless Networking and Communications Group

33. References (cont…) Filtering and Detection33
Filtering and Detection
[8] A. Spaulding and D. Middleton, “Optimum Reception in an Impulsive Interference Environment- Part I: Coherent Detection”, IEEE Trans. Comm., vol. 25, no. 9, Sep. 1977
[9] A. Spaulding and D. Middleton, “Optimum Reception in an Impulsive Interference Environment Part II: Incoherent Detection”, IEEE Trans. Comm., vol. 25, no. 9, Sep. 1977
[10] J.G. Gonzalez and G.R. Arce, “Optimality of the Myriad Filter in Practical Impulsive-Noise Environments”, IEEE Trans. on Signal Processing, vol 49, no. 2, Feb 2001
[11] S. Ambike, J. Ilow, and D. Hatzinakos, “Detection for binary transmission in a mixture of Gaussian noise and impulsive noise modelled as an alpha-stable process,” IEEE Signal Processing Letters, vol. 1, pp. 55–57, Mar
[12] J. G. Gonzalez and G. R. Arce, “Optimality of the myriad filter in practical impulsive-noise environments,” IEEE Trans. on Signal Proc, vol. 49, no. 2, pp. 438–441, Feb 2001.
[13] E. Kuruoglu, “Signal Processing In Alpha Stable Environments: A Least Lp Approach,” Ph.D. dissertation, University of Cambridge, 1998.
[14] J. Haring and A.J. Han Vick, “Iterative Decoding of Codes Over Complex Numbers for Impulsive Noise Channels”, IEEE Trans. On Info. Theory, vol 49, no. 5, May 2003
[15] Ping Gao and C. Tepedelenlioglu. “Space-time coding over mimo channels with impulsive noise”, IEEE Trans. on Wireless Comm., 6(1):220–229, January 2007.
Wireless Networking and Communications Group

34. Backup Slides Most backup slides are linked to the main slides34
Most backup slides are linked to the main slides
Miscellaneous topics not covered in main slides
Performance bounds for single carrier single antenna system in presence of RFI
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Wireless Networking and Communications Group

35. Common Spectral Occupancy35
Return
Standard
Carrier (GHz)
Wireless Networking
Interfering Clocks and Busses
Bluetooth
2.4
Personal Area Network
Gigabit Ethernet, PCI Express Bus, LCD clock harmonics
IEEE b/g/n
Wireless LAN (Wi-Fi)
IEEE e
2.5– –3.8
5.725–5.85
Mobile Broadband (Wi-Max)
PCI Express Bus, LCD clock harmonics
IEEE a
5.2
Wireless Networking and Communications Group

36. Impact of RFI Calculated in terms of desensitization (“desense”)36
Calculated in terms of desensitization (“desense”)
Interference raises noise floor
Receiver sensitivity will degrade to maintain SNR
Desensitization levels can exceed 10 dB for a/b/g due to computational platform noise [J. Shi et al., 2006]
Case Sudy: b, Channel 2, desense of 11dB
More than 50% loss in range
Throughput loss up to ~3.5 Mbps for very low receive signal strengths (~ -80 dbm)
Return
Wireless Networking and Communications Group

37. Just outside Ch. 11. Impact minor
Impact of LCD clock on g 37
Pixel clock 65 MHz
LCD Interferers and g center frequencies
Return
LCD Interferers
802.11g Channel
Center Frequency
Difference of Interference from Center Frequencies
Impact
2.410 GHz
Channel 1
2.412 GHz
~2 MHz
Significant
2.442 GHz
Channel 7
~0 MHz
Severe
2.475 GHz
Channel 11
2.462 GHz
~13 MHz
Just outside Ch. 11. Impact minor
Wireless Networking and Communications Group

38. Middleton Class A, B and C Models38
[Middleton, 1999]
Return
Class A Narrowband interference (“coherent” reception) Uniquely represented by 2 parameters
Class B Broadband interference (“incoherent” reception) Uniquely represented by six parameters
Class C Sum of Class A and Class B (approx. Class B)
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Wireless Networking and Communications Group

39. Middleton Class B Model39
Envelope statistics
Envelope exceedence probability density (APD), which is 1 – cumulative distribution function (CDF)
Return
Wireless Networking and Communications Group

40. Middleton Class B Model (cont…)40
Middleton Class B envelope statistics
Return
Wireless Networking and Communications Group

41. Middleton Class B Model (cont…)41
Parameters for Middleton Class B model
Return
Parameters
Description
Typical Range
Impulsive Index
AB  [10-2, 1]
Ratio of Gaussian to non-Gaussian intensity
ΓB  [10-6, 1]
Scaling Factor
NI  [10-1, 102]
Spatial density parameter
α  [0, 4]
Effective impulsive index dependent on α
A α  [10-2, 1]
Inflection point (empirically determined)‏
εB > 0
Wireless Networking and Communications Group

42. Accuracy of Middleton Noise Models42
Return
Magnetic Field Strength, H (dB relative to
microamp per meter rms)‏
ε0 (dB > εrms)‏
Percentage of Time Ordinate is Exceeded
P(ε > ε0)‏
Soviet high power over-the-horizon radar interference [Middleton, 1999]
Fluorescent lights in mine shop office interference [Middleton, 1999]
Wireless Networking and Communications Group

43. Symmetric Alpha Stable PDF43
Closed form expression does not exist in general
Power series expansions can be derived in some cases
Standard symmetric alpha stable model for localization parameter  = 0
Return
Wireless Networking and Communications Group

44. Symmetric Alpha Stable Model44
Heavy tailed distribution
Return
Density functions for symmetric alpha stable distributions for different values of characteristic exponent alpha: a) overall density and b) the tails of densities
Wireless Networking and Communications Group

45. Parameter Estimation: Middleton Class A45
Expectation Maximization (EM)
E Step: Calculate log-likelihood function \w current parameter values
M Step: Find parameter set that maximizes log-likelihood function
EM Estimator for Class A parameters [Zabin & Poor, 1991]
Express envelope statistics as sum of weighted PDFs
Maximization step is iterative
Given A, maximize K (= AG). Root 2nd order polynomial.
Given K, maximize A. Root 4th order polynomial
Return
Backup
Results
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Wireless Networking and Communications Group

46. Expectation Maximization Overview46
Return
Wireless Networking and Communications Group

47. Results: EM Estimator for Class A47
Return
Normalized Mean-Squared Error in A
Iterations for Parameter A to Converge
K = A G
PDFs with 11 summation terms
50 simulation runs per setting
1000 data samples
Convergence criterion:
Wireless Networking and Communications Group

48. Results: EM Estimator for Class A48
Return
For convergence for A  [10-2, 1], worst-case number of iterations for A = 1
Estimation accuracy vs. number of iterations tradeoff
Wireless Networking and Communications Group

49. Parameter Estimation: Symmetric Alpha Stable49
Based on extreme order statistics [Tsihrintzis & Nikias, 1996]
PDFs of max and min of sequence of i.i.d. data samples
PDF of maximum
PDF of minimum
Extreme order statistics of Symmetric Alpha Stable PDF approach Frechet’s distribution as N goes to infinity
Parameter Estimators then based on simple order statistics
Advantage: Fast/computationally efficient (non-iterative)
Disadvantage: Requires large set of data samples (N~10,000)
Return
Results
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Wireless Networking and Communications Group

50. Parameter Est.: Symmetric Alpha Stable Results50
Return
Data length (N) of 10,000 samples
Results averaged over 100 simulation runs
Estimate α and “mean” g directly from data
Estimate “variance” g from α and δ estimates
Mean squared error in estimate of characteristic exponent α
Wireless Networking and Communications Group

51. Parameter Est.: Symmetric Alpha Stable Results51
Return
Mean squared error in estimate of localization (“mean”) 
Mean squared error in estimate of dispersion (“variance”) 
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52. Extreme Order Statistics52
Return
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53. Parameter Estimators for Alpha Stable53
Return
0 < p < α
Wireless Networking and Communications Group

54. Filtering and Detection54
System model
Assumptions
Multiple samples of the received signal are available
N Path Diversity [Miller, 1972]
Oversampling by N [Middleton, 1977]
Multiple samples increase gains vs. Gaussian case
Impulses are isolated events over symbol period
Impulsive Noise
Pulse
Shaping
Pre-Filtering
Matched Filter
Detection Rule
N samples per symbol
Wireless Networking and Communications Group

55. Wiener Filtering 55
Optimal in mean squared error sense in presence of Gaussian noise
Return
Model
d(n)‏
z(n)‏ ^
w(n)‏
x(n)‏ ^
d(n): desired signal d(n): filtered signal e(n): error w(n): Wiener filter x(n): corrupted signal z(n): noise
Design
w(n)‏
x(n)‏
d(n)‏ ^
e(n)‏
Minimize Mean-Squared Error E { |e(n)|2 }
Wireless Networking and Communications Group

56. Wiener Filter Design Infinite Impulse Response (IIR)56
Infinite Impulse Response (IIR)
Finite Impulse Response (FIR)
Weiner-Hopf equations for order p-1
Return
desired signal: d(n) power spectrum: (e j ) correlation of d and x: rdx(n) autocorrelation of x: rx(n) Wiener FIR Filter: w(n) corrupted signal: x(n) noise: z(n)‏
Wireless Networking and Communications Group

57. Results: Wiener Filtering57
100-tap FIR Filter
Return
Pulse shape 10 samples per symbol 10 symbols per pulse
Raised Cosine Pulse Shape
Transmitted waveform corrupted by Class A interference
Received waveform filtered by Wiener filter n
Channel A =  = 0.5 × SNR = -10 dB Memoryless
Wireless Networking and Communications Group

58. MAP Detection for Class A58
Hard decision
Bayesian formulation [Spaulding & Middleton, 1977]
Equally probable source
Return
Wireless Networking and Communications Group

59. MAP Detection for Class A: Small Signal Approx.59
Expand noise PDF pZ(z) by Taylor series about Sj = 0 (j=1,2)‏
Approximate MAP detection rule
Logarithmic non-linearity + correlation receiver
Near-optimal for small amplitude signals
Return
We use 100 terms of the series expansion for d/dxi ln pZ(xi) in simulations
Correlation Receiver
Wireless Networking and Communications Group

60. Incoherent Detection 60
Bayesian formulation [Spaulding & Middleton, 1997, pt. II]
Small signal approximation
Return
Correlation receiver
Wireless Networking and Communications Group

61. Filtering for Alpha Stable Noise61
Myriad filtering
Sliding window algorithm outputs myriad of a sample window
Myriad of order k for samples x1,x2,…,xN [Gonzalez & Arce, 2001]
As k decreases, less impulsive noise passes through the myriad filter
As k→0, filter tends to mode filter (output value with highest frequency)
Empirical Choice of k [Gonzalez & Arce, 2001]
Developed for images corrupted by symmetric alpha stable impulsive noise
Return
Wireless Networking and Communications Group

62. Filtering for Alpha Stable Noise (Cont..)62
Myriad filter implementation
Given a window of samples, x1,…,xN, find β  [xmin, xmax]
Optimal Myriad algorithm
Differentiate objective function polynomial p(β) with respect to β
Find roots and retain real roots
Evaluate p(β) at real roots and extreme points
Output β that gives smallest value of p(β)
Selection Myriad (reduced complexity)
Use x1, …, xN as the possible values of β
Pick value that minimizes objective function p(β)
Return
Wireless Networking and Communications Group

63. Filtering for Alpha Stable Noise (Cont..)63
Hole punching (blanking) filters
Set sample to 0 when sample exceeds threshold [Ambike, 1994]
Large values are impulses and true values can be recovered
Replacing large values with zero will not bias (correlation) receiver for two-level constellation
If additive noise were purely Gaussian, then the larger the threshold, the lower the detrimental effect on bit error rate
Communication performance degrades as constellation size (i.e., number of bits per symbol) increases beyond two
Return
Wireless Networking and Communications Group

64. MAP Detection for Alpha Stable: PDF Approx.64
SαS random variable Z with parameters a , d, g can be written Z = X Y½ [Kuruoglu, 1998]
X is zero-mean Gaussian with variance 2 g
Y is positive stable random variable with parameters depending on a
PDF of Z can be written as a mixture model of N Gaussians [Kuruoglu, 1998]
Mean d can be added back in
Obtain fY(.) by taking inverse FFT of characteristic function & normalizing
Number of mixtures (N) and values of sampling points (vi) are tunable parameters
Return
Wireless Networking and Communications Group

65. Results: Alpha Stable Detection65
Return
Wireless Networking and Communications Group

66. Complexity Analysis for Alpha Stable Detection66
Return
Method
Complexity per symbol
Analysis
Hole Puncher + Correlation Receiver
O(N+S)
A decision needs to be made about each sample.
Optimal Myriad + Correlation Receiver
O(NW3+S)
Due to polynomial rooting which is equivalent to Eigen-value decomposition.
Selection Myriad + Correlation Receiver
O(NW2+S)
Evaluation of the myriad function and comparing it.
MAP Approximation
O(MNS)
Evaluating approximate pdf (M is number of Gaussians in mixture)
Wireless Networking and Communications Group

67. Bivariate Middleton Class A Model67
Joint spatial distribution
Return
Parameter
Description
Typical Range
Overlap Index. Product of average number of emissions per second and mean duration of typical emission
Ratio of Gaussian to non-Gaussian component intensity at each of the two antennas
Correlation coefficient between antenna observations
Wireless Networking and Communications Group

68. Results on Measured RFI Data68
Return
50,000 baseband noise samples represent broadband interference
Estimated Parameters
Bivariate Middleton Class A
Overlap Index (A)
0.313
2D- KL Divergence 1.004
Gaussian Factor (G1)
0.105
Gaussian Factor (G2)
0.101
Correlation (k)
-0.085
Bivariate Gaussian
Mean (µ)
2D- KL Divergence
Variance (s1) 1
Variance (s2)
Marginal PDFs of measured data compared with estimated model densities
Wireless Networking and Communications Group

69. Sub-optimal ML Receivers
System Model 69
Return
2 x 2 MIMO System
Maximum Likelihood (ML) receiver
Log-likelihood function
Sub-optimal ML Receivers
approximate
Wireless Networking and Communications Group

70. Sub-Optimal ML Receivers70
Two-piece linear approximation
Four-piece linear approximation
Return
Approximation of
chosen to minimize
Wireless Networking and Communications Group

71. Results: Performance Degradation71
Performance degradation in receivers designed assuming additive Gaussian noise in the presence of RFI
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Simulation Parameters
4-QAM for Spatial Multiplexing (SM) transmission mode
16-QAM for Alamouti transmission strategy
Noise Parameters: A = 0.1, 1= 0.01, 2= 0.1, k = 0.4
Severe degradation in communication performance in high-SNR regimes
Wireless Networking and Communications Group

72. Performance Bounds (Single Antenna)72
Channel capacity
Return
System Model
Case I
Shannon Capacity in presence of additive white Gaussian noise
Case II
(Upper Bound) Capacity in the presence of Class A noise
Assumes that there exists an input distribution which makes output distribution Gaussian (good approximation in high SNR regimes)
Case III
(Practical Case) Capacity in presence of Class A noise
Assumes input has Gaussian distribution (e.g. bit interleaved coded modulation (BICM) or OFDM modulation [Haring, 2003])
Wireless Networking and Communications Group

73. Performance Bounds (Single Antenna)73
Channel capacity in presence of RFI
Return
System Model
Capacity
Parameters A = 0.1, Γ = 10-3
Wireless Networking and Communications Group

74. Performance Bounds (Single Antenna)74
Probability of error for uncoded transmissions
Return
[Haring & Vinck, 2002]
BPSK uncoded transmission
One sample per symbol
A = 0.1, Γ = 10-3
Wireless Networking and Communications Group

75. Performance Bounds (Single Antenna)75
Chernoff factors for coded transmissions
Return
PEP: Pairwise error probability
N: Size of the codeword
Chernoff factor:
Equally likely transmission for symbols
Wireless Networking and Communications Group

76. System Model 76
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Wireless Networking and Communications Group

77. Performance Bounds (2x2 MIMO)77
Channel capacity
Return
System Model
Case I
Shannon Capacity in presence of additive white Gaussian noise
Case II
(Upper Bound) Capacity in presence of bivariate Middleton Class A noise. Assumes that there exists an input distribution which makes output distribution Gaussian for all SNRs.
Case III
(Practical Case) Capacity in presence of bivariate Middleton Class A noise
Assumes input has Gaussian distribution
Wireless Networking and Communications Group

78. Performance Bounds (2x2 MIMO)78
Channel capacity in presence of RFI for 2x2 MIMO
Return
System Model
Capacity
Parameters: A = 0.1, G1 = 0.01, G2 = 0.1, k = 0.4
Wireless Networking and Communications Group

79. Performance Bounds (2x2 MIMO)79
Probability of symbol error for uncoded transmissions
Return
Pe: Probability of symbol error
S: Transmitted code vector
D(S): Decision regions for MAP detector
Equally likely transmission for symbols
Parameters: A = 0.1, G1 = 0.01, G2 = 0.1, k = 0.4
Wireless Networking and Communications Group

80. Performance Bounds (2x2 MIMO)80
Chernoff factors for coded transmissions
Return
PEP: Pairwise error probability N: Size of the codeword Chernoff factor: Equally likely transmission for symbols
Parameters: G1 = 0.01, G2 = 0.1, k = 0.4
Wireless Networking and Communications Group

81. Performance Bounds (2x2 MIMO)81
Cutoff rates for coded transmissions
Similar measure as channel capacity
Relates transmission rate (R) to Pe for a length T codes
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82. Performance Bounds (2x2 MIMO)82
Cutoff rate
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Wireless Networking and Communications Group

83. Extensions to Multicarrier Systems83
Impulse noise with impulse event followed by “flat” region
Coding may improve communication performance
In multicarrier modulation, impulsive event in time domain spreads over all subcarriers, reducing effect of impulse
Complex number (CN) codes [Lang, 1963]
Unitary transformations
Gaussian noise is unaffected (no change in 2-norm Distance)
Orthogonal frequency division multiplexing (OFDM) is a special case: Inverse Fourier Transform
As number of subcarriers increase, impulsive noise case approaches the Gaussian noise case [Haring 2003]
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Wireless Networking and Communications Group