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MSICT – RF Communication SoC
POWER OPTIMIZED LCVCO & MIXER CO-DESIGN
Daniel Götz, Milosz Sroka
June 20th, 2006
INTRODUCTION
PAPER’S IMPLEMENTATION OUR IMPLEMENTATION RESULTS CONCLUSION
Power Optimized LC VCO & Mixer Co-design:
by Byunghoo Jung, Shubha Bommalingaiahnapallya, and Ramesh Harjani University of Minnesota, Dept. of ECE
Capacitively source degenerated buffer used as a negative resistance cell
No need of cross-coupled scheme
Reduced power consumption
Mixer input capacitance incorporated into the degeneration capacitor
PAPER’S IMPLEMENTATION
INTRO OUR IMPLEMENTATION RESULTS CONCLUSION
General implementation steps (1):
LC Tank-based VCO Design
Parallel LC oscillator model
Tank design for oscillation frequency
Buffer sizing and parameters calculation
Requirements of negative resistance
Design of the VCO complete structure
Parallel LC oscillator model
Requirements of negative resistance
Buffer sizing and parameters calculation
Tank design for oscillation frequency
PAPER’S IMPLEMENTATION
INTRO OUR IMPLEMENTATION RESULTS CONCLUSION
General implementation steps (2):
Mixer Design
Standard Gilbert cell design
Reduced noise figure, maximized conversion gain
Input impedance characteristics
VCO-Mixer Co-Design
Incorporation of the mixer input impedance to the VCO structure.
Other linkage effects
OUR IMPLEMENTATION
INTRO PAPER’S IMPLEMENTATION RESULTS
Step 1/6: Tank design
Estimation of the oscillation frequency L, C
Calculation of the parasitic resistance of L
Graphically:
Approximation:
Required negative resistancefor compensation Req
CONCLUSION
LCw
10
4000
Q
LwRp
370Rp
OUR IMPLEMENTATION
INTRO PAPER’S IMPLEMENTATION RESULTS
Step 2/6: “Degenerated Negative Resistance Cell”
Dimensioning of the degenerating cell Cs, width, Ibias, VDD
CONCLUSION
OUR IMPLEMENTATION
INTRO PAPER’S IMPLEMENTATION RESULTS
Step 3/6: Tank Re-design
Calculation of the Ceq of the cell
Re-design
CONCLUSION
OUR IMPLEMENTATION
INTRO PAPER’S IMPLEMENTATION RESULTS
Step 4/6: Oscillation structure
Tank biasing
Pulse generation
CONCLUSION
OUR IMPLEMENTATION
INTRO PAPER’S IMPLEMENTATION RESULTS
Step 5/6: Mixer design
Standard Gilbert cell
Transistor dimensioning
R load
I bias
Input impedance
R in series with C
CONCLUSION
OUR IMPLEMENTATION
INTRO PAPER’S IMPLEMENTATION RESULTS
Step 6/6: Co-design
Linkage
Mixer input impedance
Tank tuning (not necessary)
Linkage capacitance to eliminate DC offset
CONCLUSION
RESULTS
INTRO PAPER’S IMPLEMENTATION OUR IMPLEMENTATION
VCO Transient analysis:
Single ended Differential output
CONCLUSION
CONCLUSION
INTRO PAPER’S IMPLEMENTATION OUR IMPLEMENTATION RESULTS
Comparison between paper and our implementation:
Low power design could not be achieved because of,
• Different Technology (paper = 0.18µm, used = 0.35µm)
• Not sufficient good inductors (Q, parasitic resistance)
comparable PSS results
Phase noise was realized not that good as in the paper. At 1GHz paper = -107dBc/Hz; our implementation = -52dBc/Hz
Discovered Bottleneck of this design:
Inductors; because provide mainly the parasitic resistance which should be compensated with the Buffer-Transistors.
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