Design of LNA at 2.4 GHz Using 0.25 µm Technology
Marco Donadio
MSICT – RF Communication SoC
Paper
Design of LNA at 2.4 GHz Using 0.25 Design of LNA at 2.4 GHz Using 0.25 µm Technology:µm Technology:
by Xiaomin Yang, Thomas Wu and John McMacken
University of Central Florida, School of E.E.
implementation of 2.4 GHz CMOS low noise amplifier in a 0.25 µm technology
single ended configuration
fully integrated circuit, without off-chip components
trade-off Power-supply vs figure of merit
Introduction
What is an LNA?A circuit used to provide gain where preserving the signal-to-noise ratio is important
Where can I find one?In wireless/wireline receivers and sensor interfaces
Why ultra-low-power?Want a long battery life for portable/remote applications and implants
PAPER’S IMPLEMENTATION
Inductive degeneration topology is used to get better noise performance for the narrow band applications.
The amplifier has the commonly used cascode architecture wich provide a good isolation between the input and output stages. Ls and Lg are used to make impedence matching at the input, while the output impedence matching can be obtained by tuning the third inductor LD and the capacitor Cout.
Design Methodology
Common-Source
Problems with common-source- Low device output resistance low gain- Poor input/output isolation Instability
Cascode
RFoutLgRFin
Ls
M1Cm
VDD
Ld Ctune
VDD
LgRFin
RFout
Ld
Ls
VB
M1
M2
Cm
Ctune
Cascode Design: Lg, Ls, Ld, Cm, Ctune,
VB, VGS1, W1/L1, W2/L2
Paper’s Implementation
0.25 µm technology
3.3 V supply
gain about 15 dB
noise figure of 2.2 dB
power dissipation of 7.2 mW
LNA specification
S11 = -17 dB
S12 = -24 dB
S21 = 15 dB
S22 = -23 dB
IIP3 = 1.3 dBm
PAPER’S IMPLEMENTATION
DESIGN OF THE LNA
Both the input and the output impedence are required to be 50 Ω.
The first step is to determine the MOS transistor size in the input stage; the optimum device width for the authors is 200 µm to minimize noise figure.
INPUT MATCH
Input impedence is calculated as:
where R1 is the series resistance of the gate of inductor and Rg is the gate resistance of the NMOS transistor M1.
where R is the sheet resistance of the poly silicon, W is the total width of the device, L is the gate length and n is the number of gate fingers used to lay out the device
Ls is determined
PAPER’S IMPLEMENTATION
DESIGN OF THE LNA
At the central frequency 2.4 GHz, the imaginary term of Zin will be zero, wich gives:
From this equation, Lg is solved
MY IMPLEMENTATION
Step1: MOS transistor technology features
CTH technology (0.25 µm)
Cox 8.4 fF/um^2
L 0.25
Kn’ 3.75e-04 A/V^2
Vth 0.45
LD 1e-02 um
Cgdo 2.4e-16F/um
Gamma 0.9
Delta 6
C 0.395
Alpha 1.3
MY IMPLEMENTATION
Step2: Impedence matching (design Lg, Ls value to create a 50 Ω input impedence)
1. Choose a small value of Ls (1.4nH) because it can be realized as a integrated inductor.
2. Find the unity gain frequency gm/Cgs = ωT = 3.57e10 sec^-1 from the condition :
gs
smgs
gsin C
LgLLj
CjZ )(
1
50 sgs
smin R
C
LgZe
0)(1
gsgs
in LLC
Zm
Ls
Cgs1
LgRs
υRF
gmVgsVgs
Zin
+
-Cm
VDD
LgRFin
RFout
Ld
Ls
VB
M1
M2
Cm
Ctune
Small-signal model
MY IMPLEMENTATION
Step3: Optimal transistor size
3. Knowing transistor paramiters alpha, delta and gamma I found the parameter p = 2.253 and the optimal value of QL = 1.2 from:
4. Using the value of operating frequency ω0 I computed = 1.6nH
5. Finally I found the optimal value for the device width
where = 1.467e-12 F
MY IMPLEMENTATION
Considerations about optimal W
W = 840 µm
big transistor size, that means high power consumption
In the paper’s implementation
W = 200 µm
Transistor Sizing for Noise
NF of LNA improves with larger W However, power proportional to W Noise-power tradeoff
0
1
2
3
4
5
6
7
8
9
10
0 20 40 60 80 100 120
W [μm]
NF
[d
B]
Cascode NF
CS NF
W [μm]
NF
LNA [d
B] Cascode
Common-Source
MY IMPLEMENTATION
Final Design of LNA
Simulations and results
S12 S21 Parameters
Gain at 2.4 GHz is 21.5 dB
Reverse isolation gain is - 42.5 dB
Simulations and results
Input Matching S11 Parameter
Input matching at 2.4 GHz is -12 dB
The initial value for S11 was about 7 dB, playing with Lg value I provided 12 dB (optimizer tool).
Simulations and results
Output Matching S22 Parameter
This value of S22 is obtained adding buffer stage at to output; without this stage output matching value was too bad, about -3 dB.
Output matching at 2.4 GHz is <-14 dB
Simulations and results
Noise Figure Parameter
Noise Figure is very good (1 dB)
This is intuitive because high power consumption (big W value)!!!!!!!
Simulations and results
Intermodulation Distortion IIP3
Distortion is measured by applying two pure sinusoids with frequencies well within the bandwidth of the circuit (f1 and f2). The harmonics of these two frequencies would be outside the bandwidth of the circuit, however there are distortion products that fall at the frequencies 2f1 – f2, 2f2 – f1, 3f1 – 2f2, 3f2 – 2f1, etc.
Simulations and results
1dB Compression Point
1 dB compression point is the point at which the actual gain is 1 dB below the ideal linear gain
Simulations and results
Power Consumption
23 mW
ConclusionsComparison between paper and our implementation:
Input matching
• my S11= -15 dB vs paper’s S11 = -17 dB acceptable Output matching
• my S22= -14.7 dB vs paper’s S11 = -23 dB Bad
Gain and revers isolation
• my S21= -21.5 dB vs paper’s S21 = -15 dB GOOD
• my S12 = -42.5 dB vs paper’s S12 = -24 dB acceptable
Noise figure
• my NF = 1 dB vs paper’s NF = 2.2 dB GOOD
Power Consumption
• my PC = 23 mW vs paper’s PC = 7.2 mW TOO BAD !!!
Future Improvements
Output Matching:Output Matching:
- Implement a new output matching network in order to achieve the S22 required.
Power Consumption:Power Consumption:
-Implement a new LNA with a 1.8 power supply.
-Use of capacitors in parallel to cascode stage to minimize width of transistors.
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