A CMOS UWB Camera with 7x7 Simultaneous Active Pixels
1
A CMOS UWB Camera with 7x7 Simultaneous Active Pixels
Ta-Shun Chu and Hossein Hashemi University of Southern California, Los Angeles, CA
2
Outline • Introduction • Multi-Beam Architectures for Antenna Array • A CMOS UWB Camera • UWB Camera Measurement Results • Conclusion
3
Motivation Optical Camera
RF Camera Light Sensor
Light Beam
Optical Lens
Microwave Electromagnetic Lens Beams Antenna Array
Detector Array
•RF Camera can reconstruct images by using active or passive sensing. •RF Camera allows for imaging through optically opaque objects.
4
Antenna Array Principle
RFout
Small Instantaneous BW
Constant Group delay
Constant Phase Shift
τ
Frequency
Frequency Group Delay
τ
Phase
τ
Large Instantaneous BW
Group Delay
RFin
Phased Array
Phase
τ
Timed Array
Frequency
Frequency
Note: Broadband phased array is not equal to broadband timed array.
5
Scanning and Multi-Beam Antenna Arrays Multi-Beam Staring Array
B 5
RFin2
4
RFin1
ea m
τ
τ
RFin4
Beam 3
τ
RFin3
1
2
RFin2
RFin1
am
am Be
Be
am Be
Scanning Antenna Array
RFin3
RFin4
τ Multi-Beam Matrix
RFout
RFout1 RFout2 RFout3 RFout4 RFout5
Multi-beam staring array reduces the image capture time significantly.
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Outline • Introduction • Multi-Beam Architectures for Antenna Array • A CMOS UWB Camera • UWB Camera Measurement Results • Conclusion
7
Microwave Lens Multi-Beam Structure 1D Array B e am 3
1
Beam 2
am Be
Outer Lens
RF Cable
Inner Lens
Parallel Plate Focal Arc
I/O 3
I/O 2
I/O 1
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Microwave Lens Multi-Beam Structure 1D Array
2D Array B e am
3
1
Beam 2
am Be
Outer Lens
RF Cable
Inner Lens
Parallel Plate Focal Arc
I/O 3
I/O 2
I/O 1 z
x
y
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Conventional Circuit Multi-Beam Matrix 1D Array
I/O 1
τ
3
1
τ
B e am
Beam 2
am Be
2τ
τ
I/O 2
τ
I/O 3
2τ
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Conventional Circuit Multi-Beam Matrix 1D Array
I/O 1
τ
3
1
τ
B e am
Beam 2
am Be
2τ
τ
I/O 2
2D Array
τ
2τ
I/O 3
z
x
y
9
Blass Multi-Beam Matrix 1D Array B e am 3
1
Beam 2
am Be
#2
#1
I/O 1
τ τ
2τ 2τ 2τ
3τ I/O 2 3τ I/O 3
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Blass Multi-Beam Matrix 1D Array
2D Array B e am
3
1
Beam 2
am Be
#2
#1
I/O 1
τ τ
2τ 2τ 2τ
3τ I/O 2 3τ I/O 3
z
x
y
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The Proposed Multi-Beam Matrix 1D Array B e am
Beam 2
3
am Be 1
#1
#2
τ
τ
I/O 3
τ
I/O 2
τ
I/O 1
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The Proposed Multi-Beam Matrix 1D Array
2D Array B e am
Beam 2
3
am Be 1
#1
#2
τ
τ
I/O 3
τ
I/O 2
τ
I/O 1
z
x
y
11
Comparison of Multi-Beam Arrays Conventional Multi-beam Matrix
Blass Multi-beam Matrix
The Proposed Multi-beam Matrix
2 inputs 3 outputs
8τ
7τ
2τ
4 inputs 5 outputs
56τ
70τ
27τ
2X2 inputs 3X3 outputs
40τ
35τ
10τ
4X4 inputs 5X5 outputs
504τ
630τ
243τ
Complexity of 2D Array
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Outline • Introduction • Multi-Beam Architectures for Antenna Array • A CMOS UWB Camera • UWB Camera Measurement Results • Conclusion
13
Proposed UWB Camera
Antenna LNA
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Proposed UWB Camera
Antenna LNA
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Proposed UWB Camera
Antenna LNA
Transconductance Amplifier
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Proposed UWB Camera
Antenna LNA Unit Delay Cell ( τ )
Transconductance Amplifier Delay Line Termination
13
Proposed UWB Camera
Antenna LNA Unit Delay Cell ( τ )
Transconductance Amplifier Detector Driver (RF Buffer)
Delay Line Termination
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Proposed UWB Camera
Antenna LNA Unit Delay Cell ( τ )
Transconductance Amplifier Detector Driver (RF Buffer) Detector Array (7X7 Pixels)
Delay Line Termination
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Proposed UWB Camera
Electromagnetic Beams (7X7 Directions) Antenna LNA Unit Delay Cell ( τ )
Transconductance Amplifier Detector Driver (RF Buffer) Detector Array (7X7 Pixels)
Delay Line Termination
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Signal Flow for Pixel 44
X-direction
Y-direction
Delay In11 Æ Out44 = 4τ + 4τ = 8τ Delay In12 Æ Out44 = 4τ + 4τ = 8τ 4τ
RFin11
Delay In21 Æ Out44 = 4τ + 4τ = 8τ Delay In22 Æ Out44 = 4τ + 4τ = 8τ
4τ Z
RFin12
RFin21
X
4τ
RFin22 4τ
Y
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Signal Flow for Pixel 52
X-direction
Y-direction
Delay In11 Æ Out52 = 5τ + 2τ = 7τ Delay In12 Æ Out52 = 5τ + 6τ = 11τ 5τ
RFin11
Delay In21 Æ Out52 = 3τ + 2τ = 5τ Delay In22 Æ Out52 = 3τ + 6τ = 9τ
3τ Z
RFin12
RFin21
X
2τ RFin22 6τ
Y
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UWB Camera Block Diagram RFin12
RFin11 LNA
Bias Circuit
VGA Transconductance Amplifier
Detector Driver (RF Buffer) Energy Detector
Digital Controller
RFin21
RFin22
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Embedded Equalizer Optimal-Embedded Equalizer
Original-Embedded Equalizer
Gain
Gain Frequency
Array Gain
Frequency
Frequency
Group Delay
Group Delay
Group Delay
Frequency
Group Delay
Gain
Gain Frequency
Frequency
Array Gain
Array Gain
Array Gain
Frequency
Frequency
Embedded equalizer maintains the same array gain for all directions.
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UWB Front-end Design Vdd
Mf
Lsp
Pad
50Ω
M1 M2
Delay Line
Ls Vb2
Lg Vb1 Pad Vin+
Vb3
Vb4
Vin-
UWB LNA
3-Stage UWB VGA
-3dB bandwidth Power gain |S11| (1GHz-15GHz) Noise figure 1 dB Compression Point (input power) Current Consumption
17GHz 19dB
A CMOS UWB Camera with 7x7 Simultaneous Active Pixels
Ta-Shun Chu and Hossein Hashemi University of Southern California, Los Angeles, CA
2
Outline • Introduction • Multi-Beam Architectures for Antenna Array • A CMOS UWB Camera • UWB Camera Measurement Results • Conclusion
3
Motivation Optical Camera
RF Camera Light Sensor
Light Beam
Optical Lens
Microwave Electromagnetic Lens Beams Antenna Array
Detector Array
•RF Camera can reconstruct images by using active or passive sensing. •RF Camera allows for imaging through optically opaque objects.
4
Antenna Array Principle
RFout
Small Instantaneous BW
Constant Group delay
Constant Phase Shift
τ
Frequency
Frequency Group Delay
τ
Phase
τ
Large Instantaneous BW
Group Delay
RFin
Phased Array
Phase
τ
Timed Array
Frequency
Frequency
Note: Broadband phased array is not equal to broadband timed array.
5
Scanning and Multi-Beam Antenna Arrays Multi-Beam Staring Array
B 5
RFin2
4
RFin1
ea m
τ
τ
RFin4
Beam 3
τ
RFin3
1
2
RFin2
RFin1
am
am Be
Be
am Be
Scanning Antenna Array
RFin3
RFin4
τ Multi-Beam Matrix
RFout
RFout1 RFout2 RFout3 RFout4 RFout5
Multi-beam staring array reduces the image capture time significantly.
6
Outline • Introduction • Multi-Beam Architectures for Antenna Array • A CMOS UWB Camera • UWB Camera Measurement Results • Conclusion
7
Microwave Lens Multi-Beam Structure 1D Array B e am 3
1
Beam 2
am Be
Outer Lens
RF Cable
Inner Lens
Parallel Plate Focal Arc
I/O 3
I/O 2
I/O 1
7
Microwave Lens Multi-Beam Structure 1D Array
2D Array B e am
3
1
Beam 2
am Be
Outer Lens
RF Cable
Inner Lens
Parallel Plate Focal Arc
I/O 3
I/O 2
I/O 1 z
x
y
8
Conventional Circuit Multi-Beam Matrix 1D Array
I/O 1
τ
3
1
τ
B e am
Beam 2
am Be
2τ
τ
I/O 2
τ
I/O 3
2τ
8
Conventional Circuit Multi-Beam Matrix 1D Array
I/O 1
τ
3
1
τ
B e am
Beam 2
am Be
2τ
τ
I/O 2
2D Array
τ
2τ
I/O 3
z
x
y
9
Blass Multi-Beam Matrix 1D Array B e am 3
1
Beam 2
am Be
#2
#1
I/O 1
τ τ
2τ 2τ 2τ
3τ I/O 2 3τ I/O 3
9
Blass Multi-Beam Matrix 1D Array
2D Array B e am
3
1
Beam 2
am Be
#2
#1
I/O 1
τ τ
2τ 2τ 2τ
3τ I/O 2 3τ I/O 3
z
x
y
10
The Proposed Multi-Beam Matrix 1D Array B e am
Beam 2
3
am Be 1
#1
#2
τ
τ
I/O 3
τ
I/O 2
τ
I/O 1
10
The Proposed Multi-Beam Matrix 1D Array
2D Array B e am
Beam 2
3
am Be 1
#1
#2
τ
τ
I/O 3
τ
I/O 2
τ
I/O 1
z
x
y
11
Comparison of Multi-Beam Arrays Conventional Multi-beam Matrix
Blass Multi-beam Matrix
The Proposed Multi-beam Matrix
2 inputs 3 outputs
8τ
7τ
2τ
4 inputs 5 outputs
56τ
70τ
27τ
2X2 inputs 3X3 outputs
40τ
35τ
10τ
4X4 inputs 5X5 outputs
504τ
630τ
243τ
Complexity of 2D Array
12
Outline • Introduction • Multi-Beam Architectures for Antenna Array • A CMOS UWB Camera • UWB Camera Measurement Results • Conclusion
13
Proposed UWB Camera
Antenna LNA
13
Proposed UWB Camera
Antenna LNA
13
Proposed UWB Camera
Antenna LNA
Transconductance Amplifier
13
Proposed UWB Camera
Antenna LNA Unit Delay Cell ( τ )
Transconductance Amplifier Delay Line Termination
13
Proposed UWB Camera
Antenna LNA Unit Delay Cell ( τ )
Transconductance Amplifier Detector Driver (RF Buffer)
Delay Line Termination
13
Proposed UWB Camera
Antenna LNA Unit Delay Cell ( τ )
Transconductance Amplifier Detector Driver (RF Buffer) Detector Array (7X7 Pixels)
Delay Line Termination
13
Proposed UWB Camera
Electromagnetic Beams (7X7 Directions) Antenna LNA Unit Delay Cell ( τ )
Transconductance Amplifier Detector Driver (RF Buffer) Detector Array (7X7 Pixels)
Delay Line Termination
14
Signal Flow for Pixel 44
X-direction
Y-direction
Delay In11 Æ Out44 = 4τ + 4τ = 8τ Delay In12 Æ Out44 = 4τ + 4τ = 8τ 4τ
RFin11
Delay In21 Æ Out44 = 4τ + 4τ = 8τ Delay In22 Æ Out44 = 4τ + 4τ = 8τ
4τ Z
RFin12
RFin21
X
4τ
RFin22 4τ
Y
15
Signal Flow for Pixel 52
X-direction
Y-direction
Delay In11 Æ Out52 = 5τ + 2τ = 7τ Delay In12 Æ Out52 = 5τ + 6τ = 11τ 5τ
RFin11
Delay In21 Æ Out52 = 3τ + 2τ = 5τ Delay In22 Æ Out52 = 3τ + 6τ = 9τ
3τ Z
RFin12
RFin21
X
2τ RFin22 6τ
Y
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UWB Camera Block Diagram RFin12
RFin11 LNA
Bias Circuit
VGA Transconductance Amplifier
Detector Driver (RF Buffer) Energy Detector
Digital Controller
RFin21
RFin22
17
Embedded Equalizer Optimal-Embedded Equalizer
Original-Embedded Equalizer
Gain
Gain Frequency
Array Gain
Frequency
Frequency
Group Delay
Group Delay
Group Delay
Frequency
Group Delay
Gain
Gain Frequency
Frequency
Array Gain
Array Gain
Array Gain
Frequency
Frequency
Embedded equalizer maintains the same array gain for all directions.
18
UWB Front-end Design Vdd
Mf
Lsp
Pad
50Ω
M1 M2
Delay Line
Ls Vb2
Lg Vb1 Pad Vin+
Vb3
Vb4
Vin-
UWB LNA
3-Stage UWB VGA
-3dB bandwidth Power gain |S11| (1GHz-15GHz) Noise figure 1 dB Compression Point (input power) Current Consumption
17GHz 19dB
