Post on 22-Apr-2020
EMC Near-Field Scanning
Searching for Root Causes
Nov. 01, 2018Proprietary Information - Do not duplicate or distribute without written permission from Amber Precision Instruments (API).
© 2018 Amber Precision Instruments, Inc. (API)
EMC Compliance
1* https://twitter.com/elonmusk/status/998409778316496896
Outline
• Susceptibility Scanning
– Conducted susceptibility: where does ESD current go?
– Near-field effects of electrostatic discharge events
• Emission Scanning
– Sniffer probes are smarter than they look
– Electromagnetic lens: from near-field to far-field
2
ESD Susceptibility Scanning
3
Electrostatic Discharge (ESD)
4
DUT
Human Body Model
(HBM)
R = 1500 Ω
C = 100 pF
DUT
Human Metal Model
(HMM)
R = 330 Ω
C = 150 pF
HBM Waveform
5* ANSI/ESDA/JEDEC JS-001-2010, MIL-STD-883J Method 3015.9
** https://www.thermofisher.com/order/catalog/product/CUSPID0000019
HMM Waveform
6* IEC 61000-4-2, ISO 10605, MIL-STD-461G CS118, ANSI/ESD SP5.6-2009
ESD Current Spreading Scanning
7
Robot
DUT
TLP
Scope
Pro
be
PC
Results
* IEC TS 61967-3
ANSI/ESD SP14.5-2015
12
From ESDA:
For Electrostatic Discharge Sensitivity Testing –
Near-Field Immunity Scanning –
Component/Module/PCB Level
An American National Standard
Approved September 14, 2015
ESD scanning technology is widely accepted as a powerful tool for root cause
analysis and screening high immunity components, modules and systems
* ANSI/ESD SP14.5-2015
ESD Immunity Scanning
13
Robot
TLP
PC
DUTP
robe
Results
FD
* ANSI/ESD SP14.5-2015, IEC 61000-4-2, ISO 10605, MIL-STD-461G CS118, ANSI/ESD SP5.6-2009
TLP Waveform
14
VTLP = 2 kV
Tr = 500 ps
Tf = 33 ns
Current Waveforms:
HBM vs HMM vs TLP
15
Simulated discharge current
waveform on 2 Ω load
* IEC 61000-4-2
HMM vs ANSI/ESD SP14.5-2015
Simple Structure
16
?
50 ohms microstrip (3 mm wide trace)
Board dimension: 100 x 100 mm2
Board elevation from HCP: 1 mm
ESD generator distance to board: 10 mm
ESD generator setting: 2 kV CD
50 ohms microstrip (3 mm wide trace)
Board dimension: 100 x 100 mm2
Probe: 2 mm or 5 mm loop H-field
Mechanical probe height from trace: 0 mm
TLP setting: 2 kV
Field Coupling to Microstrip
17
H-Field E-Field
Surface Current Density
Field Coupling to Microstrip
18
H-Field E-Field
Surface Current Density
Field Attenuation from ESD
19
HMM vs Near-Field Injection
20
What Does Happen during Discharge?
21
Enclosure
PCB
PCB
Flex cable
ESD Generator
Connector
ICFAILED!
FAILED!
Near-Field Probe Reproduces HMM Results
22
FAILED!
-5 0 5 10 15 20 25 30 35 400
500
1000
1500
2000
2500
3000
3500
Time [ns]
Vo
ltag
e [V
]
TLP
Electromagnetic field is coupling to traces or IC
FAILED!
Electromagnetic field is coupling to flex cable and induces current
TLPWaveform
Near-FieldProbe
Effect of PCB Layout on
Susceptibility
23
PCB Layout 1* PCB Layout 2*
Hx
Hy
* Two functionally identical boards with different PCB layouts. Layout 1 fails at higher voltages during gun test.
Effect of IC Fab on Susceptibility
24
White Paper 3 Part II specifically covers in detail an overview of system ESD stress application methods, system diagnostic techniques to detect hard or soft failures, and the application of tools for susceptibility scanning. For example, as illustratedin Figure 2, these types of advanced tools can be used to differentiate thecharacteristics of products and enable proper system protection methodology*.
Figure 2: Susceptibility scanning using pulse techniques on Product A (left) and Product B (right) (Courtesy of Amber Precision Instruments)
* From the ESDA White paper 3, Part II, page 18.
** Product A and Product B are functionally identical ICs from different vendors.
Susceptibility Scanning: Conclusion
• Conducted susceptibility to an ESD event can be
analyzed by measuring and visualizing scanned
surface current density on the DUT.
• Susceptibility to near-field effects of an ESD
event can be emulated with near-field injection.
• Near-field injection per ANSI/ESD SP14.5-2015
reproduces same failures as IEC 61000-4-2.
25
Electromagnetic Compatibility (EMC)
26
Aggressor Victim
Conducted
Emission
Conducted
Susceptibility
Radiated
Susceptibility
Radiated
Emission
27
Emission Scanning
Sniffer Probe
28* Hand-made
EMI Near-Field Probe
29
Probes:- Up to 40 GHz- Down to 20 kHz
Optional EMI Probes;Choose:- Size- Frequency range- Field Component
* EMI Hx 2 mm
EMI Near-Field Scanning
30
Robot
DUTP
robe
PC
SA
Results
* IEC TS 61967-3
Phase Measurement Scanning
31
Robot
DUTP
robe
PC
VNAor
Scope
ResultsRef Probe
* IEC TS 61967-3
Applications of Phase Measurement
32
Applications
of Phase
Measurement
Near-Field to
Far-Field
Emission Source
Microscopy (ESM)
RFI and Source
Modeling
Source
Localization
Applications of ESM:
- High speed data communication
- Data centers, servers, routers, cloud
- 5G mobile network, IoT
- Radar systems
- Phased arrays
- Electrically large, automotive, aerospace
Co-Design:
Measurement and Simulation
33
History of ESM:
Synthetic Aperture Radar (SAR)
34
Measuring instrument
Antenna
SUT
Scanning plane
Use of imaging algorithm on
measured data
Applications of SAR:
- Airborne radar
- Medical imaging
- Concealed object detection
- Non-destructive testing
- Antenna diagnosis
* Wikipedia, P.L. Ransom et al (1971), J.J Lee et al (1988), M. Soumekh (1991), D.M. Sheen et al (2001), B. Janice (2011), H. Kajbaf et al (2013)
MR
I
Angio
gra
phy
Venus
Magellan Probe2.385 GHz, 12.6 cm
Symmetric Differential Microstrip
35
Full-wave simulation
Differential microstrip line
Differentially driven @ 10 GHzEx @ Z=1 mm (λ/30)
Ex @ Z=30 mm (λ)Ex @ Z=7.5 mm (λ/4)
Non-I
nvert
ing
Invert
ing
Load
Asymmetric Differential Microstrip
36
Non-I
nvert
ing
Invert
ing
Load
GND
Asymmetric differential microstrip
12 mil gap between GND & line
Differentially driven @ 10 GHzEx @ Z=1 mm (λ/30)
Ex @ Z=30 mm (λ)Ex @ Z=7.5 mm (λ/4)
Wave Propagation
37* Asymmetric differential microstrip @ 10 GHz
Ez
Ex Ey
|E|
Wave Propagation
38* Asymmetric differential microstrip @ 10 GHz
Ez
Ex Ey
|E|
Wave Propagation
39
Max Ex Max Ey
Max Ez Max |E|
* Asymmetric differential microstrip @ 10 GHz
Z=1 mm (λ/30)
Z=7.5 mm (λ/4)
Z=30 mm (λ)
Z=60 mm (2λ)
Wave Propagation
40
Max Ex Max Ey
Max Ez Max |E|
Z=1 mm (λ/30)
Z=7.5 mm (λ/4)
Z=30 mm (λ)
Z=60 mm (2λ)
* Symmetric differential microstrip @ 10 GHz
Emission Source Microscopy (ESM)
41
Measure at Radiative
Near-Field
(~1-2λ away from
DUT)
Back-Calculate to
DUT Location
(Phase Adjustment)*
Localize Sources
Contributing to
Far-Field
Optional:
Calculate TRP
Optional:
Calculate Far-Field
Pattern𝑓 𝑥, 𝑦 = 𝐹2𝐷
−1 𝐹2𝐷 𝑠 𝑥, 𝑦 𝑒−𝑗𝑘𝑧𝑧0 𝑘𝑧 = 𝑘2 − 𝑘𝑥2 − 𝑘𝑦
2
* Using Range Migration Algorithm (RMA) or Synthetic Aperture Radar (SAR)
k-Space and Propagating Wave
42
𝑓 𝑥, 𝑦 = 𝐹2𝐷−1 𝐹2𝐷 𝑠 𝑥, 𝑦 𝑒−𝑗𝑘𝑧𝑧0
* Asymmetric differential microstrip @ 10 GHz, Z=30mm (λ)
Scanned |Ex| k-Space Focused |Ex|
Scanned ∡ Ex ∡ k-Space Focused ∡ Ex
𝐹2𝐷 𝐹2𝐷−1
𝑒−𝑗𝑘𝑧𝑧0
𝑘𝑧 = 𝑘2 − 𝑘𝑥2 − 𝑘𝑦
2
k-Space and Evanescent Wave
43* Asymmetric differential microstrip @ 10 GHz, Z=1mm (λ/30)
Scanned |Ex| k-Space Focused |Ex|
Scanned ∡ Ex ∡ k-Space Focused ∡ Ex
𝐹2𝐷 𝐹2𝐷−1
𝑒−𝑗𝑘𝑧𝑧0
Resolution
• Numerical aperture is given as,
where 𝑛 = refractive index of medium
𝜃 = half of angular aperture
• Resolution is given as,
• Theoretically, highest resolution is ~ 𝜆/2
44
𝑁𝐴 = 𝑛 ∗ sin 𝜃
Scanning plane
Source plane
h
d
𝑅 =𝜆
2 ∗ 𝑁𝐴
Ideal Dipole
45
Two dipoles are placed
Dipole 1 at (-100,0,0) mm,
Dipole 2 at (100,0,100) mm
E fields components
Frequency = 10 GHz
Grid spacing = 0.5 mm
Distance = 2.5λ
Resolution ~ 15 mm
Electric
dipoles
Interference pattern on
scanning plane
2.5 λ
Focusing Lens at Different Distances
46
Correct location of dipoles is determinedDipole 2 at
(100,0,100) mm
Dipole 1 at
(-100,0,0) mm
Applications of ESM
47
Measurement Setup:
- The measurement is performed
at 8.2 GHz and at 5 cm away
from DUT.
- Using VNA and open-ended
waveguide used.
5 cm Away from DUT Focused Image
ESM Application of Synthetic Aperture Antenna (SAR) to EMC
- Identification of emission source
- FF estimation
- Total radiated power calculation
Applications of ESM
48
10.3123 10.3124 10.3125 10.3126 10.3127-110
-108
-106
-104
-102
-100
-98
-96
-94
-92
-90
Frequency(GHz)
Radia
ted (
dB
m)
Radiation
Open cover without absorber Scanning height = 7 cm Freq = 10.312509 GHz
Scanned Ex @ 7 cm Focused Ex @ 0 cmNear-Field Hx @ 2 mm
Applications of ESM
49
Without absorbing material With absorbing material
below ASICWith absorbing material
around PHY and below ASIC
With absorbing material
around PHY
TRP from
R-Chamber
Calculated
From ESM
Reduction in TRP 0-1 dB 0-1 dB
TRP from
R-Chamber
Calculated
From ESM
Reduction in TRP 4-5 dB 4-5 dB
Emission Scanning: Conclusion
• EMI scanning is a powerful tool for identifying near-field sources.
• The scanned data can be exported to industry standard format IEC 61967-1-1, and can be imported to full-wave simulation tools.
• Measuring the phase distribution, in addition to magnitude, helps with identifying sources that contribute to far-field using ESM.
• Near-field to far-field transformation and total radiated power estimation are useful applications of phase measurement.
50
51
Thank You!
Questions?
Contact us: amberpi@amberpi.com
www.amberpi.com
References
• Download papers from [Link]
• Application of Emission Source Microscopy Technique to EMI Source Localization above 5 GHz [Link]
• Emission Source Microscopy Technique for EMI Source Localization [Link]
• EMI Mitigation with Lossy Material at 10 GHz [Link]
• Compressed Sensing for SAR-Based Wideband Three-Dimensional Microwave Imaging System Using Non-Uniform Fast Fourier Transform [Link]
• Introduction to Fourier Optics [Link]
• Synthetic Aperture Radar Signal Processing with MATLAB Algorithms [Link]
• Wikipedia: Synthetic Aperture Radar [Link]
• Characterization of Human Metal Model ESD Based on Radiated Susceptibility [Link]
• Modeling Electromagnetic Field Coupling form an ESD Gun to an IC [Link]
• Finding the Root Cause of an ESD Upset Event [Link]
• A Measurement Technique for ESD Current Spreading on A PCB using Near Field Scanning [Link]
• Near Field Probe for Detecting Resonances in EMC Application [Link]
52* http://amberpi.com/library_papers.php