1. RF Electronics Engineering
Spring
2014
RF Systems and Circuits
RF Electronics Engineering
Emad Hegazi
Professor, ECE
Communication Circuits Research Group

2. Spring
2014
RF Systems and Circuits
Resonance
Resonance represents the intrinsic rate of energy exchange in a second order system.
Friction forces oscillation to cease after a while.
Less friction means higher quality system

3. Circuit Analysis RF Systems and Circuits Why? If there is no loss
Spring
2014
RF Systems and Circuits
Circuit Analysis
If there is no loss
Why?
define

4. Spring
2014
RF Systems and Circuits
Resonance
Inductor and Capacitor exchange energy and loss resistance keeps burning energy
By the way, the parallel resistance is simply a model.

5. Susceptance @ Resonance
Spring
2014
RF Systems and Circuits
Resonance
R is the ONLY block that draws current from the source at resonance
The tank looks like a high impedance to the supply.

6. Quality The ratio of stored current to the source current at resonance
Spring
2014
RF Systems and Circuits
Quality
The ratio of stored current to the source current at resonance
R must be large for higher Q.

7. Spring
2014
RF Systems and Circuits
Series Resonance

8. Getting Real RF Systems and Circuits If the input source is constant
Spring
2014
RF Systems and Circuits
Getting Real
If the input source is constant

9. Spring
2014
RF Systems and Circuits
Resonance
Inductor and Capacitor exchange energy and loss resistance keeps burning energy
The impedance is at minimum when at resonance

10. Spring
2014
RF Systems and Circuits
Resonance
Q is the ratio between the voltage on the reactance to the source voltage.

11. Passive Amplification
Spring
2014
RF Systems and Circuits
Passive Amplification
QVm
-QVm
Maximum current flows in the circuit means L & C see maximum voltage at opposite polarities.
@ resonance, the circuit amplifies the source voltage by Q

12. Spring
2014
RF Systems and Circuits
Impedance Conversion

13. Spring
2014
RF Systems and Circuits
Impedance Conversion

14. Outline Friis Formula Merits of LNAs Common Gate LNA Common Source LNA
Spring
2014
RF Systems and Circuits
Outline
Friis Formula
Merits of LNAs
Common Gate LNA
Common Source LNA

15. Spring
2014
RF Systems and Circuits
Cascaded Noise Figure
In a line-up of receiver stages, use Friis equation
Gi is the power gain
Says that the noise factor ‘F’ is more influenced by earlier stages

16. LNA Merits Gain Low Noise (NF) High Linearity (IIP3)
Spring
2014
RF Systems and Circuits
LNA Merits
Gain
Low Noise (NF)
High Linearity (IIP3)
Low Reflection (S11)
High reverse isolation (S12)
High Stability (K)

17. Maximum Power Transfer
Spring
2014
RF Systems and Circuits
Maximum Power Transfer

18. Transistor Noise Thermal noise is referred to the input
Spring
2014
RF Systems and Circuits
Transistor Noise
Thermal noise is referred to the input
Physical
Circuit equivalent

19. Common Gate LNA Input impedance is resistive (except for parasitics)
Spring
2014
RF Systems and Circuits
Common Gate LNA
Input impedance is resistive (except for parasitics)
Offers good impedance match even at low frequencies

20. Spring
2014
RF Systems and Circuits
Common Gate LNA
tunes out transistor and board parasitics.
Channel resistance offers good reverse isolation

21. Common Gate LNA At matching condition, Zin = 1/gm
Spring
2014
RF Systems and Circuits
Common Gate LNA
At matching condition,
Zin = 1/gm

22. Impedance Transformers
Spring
2014
RF Systems and Circuits
Impedance Transformers

23. Impedance Matching Maximum power transfer Minimum noise figure
Spring
2014
RF Systems and Circuits
Impedance Matching
Maximum power transfer
Minimum noise figure
Optimized passives’ transfer functions
Minimum reflections

24. Impedance Matching Impedance mismatch is preserved at each port
Spring
2014
RF Systems and Circuits
Impedance Matching
Impedance mismatch is preserved at each port
We need a TRANSFORMER

25. Transformer Matching Transformers are bulky and lossy
Spring
2014
RF Systems and Circuits
Transformer Matching
Transformers are bulky and lossy
We don’t really need wideband matching in RF transceivers
Think of a narrow band equivalent of a transformer

26. Narrow Band Impedance Transformers
Spring
2014
RF Systems and Circuits
Narrow Band Impedance Transformers
Load resistance takes only a fraction of the input current
Looks like a higher resistance than it really is.
Problem:
Zin looks reactive

27. L-Match @resonance the C and Ls tune out and only Rs remains.
Spring
2014
RF Systems and Circuits
L-Match
@resonance the C and Ls tune out and only Rs remains.
LNA input is made with higher R to save power
LNA
Antenna

28. Common Gate LNA: Lowering Power II
Spring
2014
RF Systems and Circuits
Common Gate LNA: Lowering Power II
Narrowband impedance transformer (L Section) allows the LNA to have Zin>50W.
Transformer amplifies input signal by:

29. Common Gate LNA: Lowering Power II
Spring
2014
RF Systems and Circuits
Common Gate LNA: Lowering Power II
For same IIP3, Veff has to increase by
>1
Current is reduced by the same factor
Bias current is given by: gm

30. Common Gate LNA: Lowering Power III
Spring
2014
RF Systems and Circuits
Common Gate LNA: Lowering Power III gm

31. Common Source Amplifier
Spring
2014
RF Systems and Circuits
Common Source Amplifier
Input impedance is purely capacitive
Resistive part appears at high frequency
No input matching is possible

32. Common Source Amplifier
Spring
2014
RF Systems and Circuits
Common Source Amplifier
Rg is set to 50W => Input Matching
Miller Effect due to Cgd
=> Limited Bandwidth

33. Common Source Amplifier
Spring
2014
RF Systems and Circuits
Common Source Amplifier
Cascode reduces Miller Effect
Resistive Load limits linearity

34. Common Source Amplifier
Spring
2014
RF Systems and Circuits
Common Source Amplifier
Parallel Resonance at output boasts narrow band gain without impacting linearity
Rg produces a lot of Noise
NF>3 dB

35. Common Source Amplifier
Spring
2014
RF Systems and Circuits
Common Source Amplifier
Series resonance at input creates a resistive term
Iin= jw CgsVgs
Vin=Vgs+jwLs(Iin+gmVgs)
gmVgs
Iin

36. Common Source Amplifier
Spring
2014
RF Systems and Circuits
Common Source Amplifier
Series resonance at input creates a resistive term
@ RF, input is still capacitive because Ls is very small to give 50W with high wT

37. Common Source Amplifier
Spring
2014
RF Systems and Circuits
Common Source Amplifier
Gate inductance offers one more degree of freedom to allow matching and series resonance at the same time
Valid for

38. Spring
2014
RF Systems and Circuits
Parasitics
Ali Niknejad ECE142

39. Design Procedure for Common Source LNAs
Spring
2014
RF Systems and Circuits
Design Procedure for Common Source LNAs

40. Common Source Amplifier
Spring
2014
RF Systems and Circuits
Common Source Amplifier
Assume an equivalent resistive load Rd
@ resonance

41. Common Source Amplifier
Spring
2014
RF Systems and Circuits
Common Source Amplifier
Noise Figure (F) is given by
Source
Coils
Transistor
Use samll Ls
Decreases with wT

42. Optimization of CS LNA Assume @ Input matching condition
Spring
2014
RF Systems and Circuits
Optimization of CS LNA
Assume
@ Input matching condition

43. Optimization of CS LNA wT Increases Lg Noise dominates Higher power
Spring
2014
RF Systems and Circuits
Optimization of CS LNA
wT Increases
Lg Noise dominates
Higher power

44. Another Way to Look at It
Spring
2014
RF Systems and Circuits
Another Way to Look at It
If Q is input quality factor

45. Another Way to Look at It
Spring
2014
RF Systems and Circuits
Another Way to Look at It
The input is amplified by Q before it reaches the transistor
This reduces linearity

46. Other Losses: Inductor Losses
Spring
2014
RF Systems and Circuits
Other Losses: Inductor Losses
Typically Lg losses dominate
Adds in series to source noise
Independent of FET gain

47. Other Losses: Gate Resistance
Spring
2014
RF Systems and Circuits
Other Losses: Gate Resistance
Gate Resistance creates additional noise (uncorrelated with channel noise)
Use inter-digitated layout to reduce gate electrode resistance

48. Other Losses: Gate Induced Noise
Spring
2014
RF Systems and Circuits
Other Losses: Gate Induced Noise
Due to inversion layer resistance
Partly correlated with conventional thermal noise
Modeled as a resistance in series with gate

49. Other Losses: Gate Induced Noise
Spring
2014
RF Systems and Circuits
Other Losses: Gate Induced Noise
The effective Q is lowered by losses
Higher Q is achieved through lower Cgs
Smaller Cgs raises rinv and also gate resistance
There is an optimum W at each current

50. Other Losses: Substrate Coupling
Spring
2014
RF Systems and Circuits
Other Losses: Substrate Coupling
BSIM3V3 models do NOT capture Cgb
Gate to bulk capacitance is an additional path for noise

51. Other Losses: Substrate Coupling
Spring
2014
RF Systems and Circuits
Other Losses: Substrate Coupling
Hole distribution in the depletion layer are modulated by gate voltage
Same effect on electrons in the inversion layer which reflects back on depletion region