abhinav end sem presentation software defined radio
TRANSCRIPT
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Presented By Abhinav Kumar Tyagi
M.Tech II YearIIT Kharagpur
Under the Guidance ofProf R V Raja Kumar
E&ECE Department, IIT Kharagpur
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CONTENTS
Introduction to Software Defined Radio
Ideal Architecture
Problems with Ideal Architecture implementation
Existing Software Defined Radio
Objective
Motivation
Work Done
Future Work
References
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Introduction to SDR
First introduced by J.Mitola in 1991
Refers to a technique in which all the processing is done in software
The processing mentioned include mixing, filtering, demodulation etc
The software can be used to implement different demodulation scheme
and different standards can be implemented in the same device.
The software can be updated so the device doesn’t become obsolete
with time.
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SDR EXPLAINED
Software Defined RadioHardware Radio
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IDEAL SDR
Low Pass Filter
Analog to Digital Converter
Digital Signal Processor
Antenna
Block Diagram of Ideal SDR Receiver
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IDEAL SDR
High Frequency
Requires High Sampling Rate ADC
Costly, Power Hungry
High Speed Processor to Process High Sample Rate
Much Costly, Huge Power Consumption
Thus a non feasible solution for commercial applications!
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PRACTICAL SDR ARCHITECTURE
Analog RF Front-End still required:Digital-analog conversion, DAC/ADC RF, IF FilteringMixing IF RFAmplificationAntennas
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EXISTING SDRs
TMDSSFFSDR, from Texas Instruments in 360-960 MHz range.
SDR-1000 from Flex-Radio System ; a commercial SDR; useful for
amateur radio operators; 12KHz to 60MHz.
SDR-3000 & SDR-4000 from FlexComm , useful for tactical military
communication system.
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MULTI MODE RADIO
GSMChipset
CDMAchipset
Processor
Software
Hardware
Most of Mobile phone that work in more than one standards are based on this principle
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OBJECTIVE OF THE PROJECT
To develop a ‘Single Wideband’ RF Front end from 400MHz to 3.4 GHz.
This will cover all the existing/future standards like
GSM 850/900/1800, IS95, IS136, UMTS, WiFi, Wimax etc.
The design should have low cost and power efficient
Targets on reconfigurability and reusability.
No Single Wideband solution been reported till now!
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MotivationThe project involves development of complete system as a whole.
SDR is an emerging technology
It is very promising. SDR aims at
Providing multifunctionality to same device.
It supports Global Mobility
Ensures Compactness and Power Efficiency
Upgrades are easy with update of software
Evolution of new standards doesn’t make the device obsolete when
compared to conventional multimode radios.
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WORK DONE
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Architecture of RF Front End
Digital to Analog Converter
DAC5687
Ba
seb
an
d
Pro
cess
or
Ba
seb
an
d
Pro
cess
or
Analog to Digital Converter
ADC08200
ADC08200
ADC8369
ADC8369 AD 8347MGA665P8
TRF3761 FREQUENCY SYNTHESIZER
I/Q MODULATOR
TRF3703 MwT-17Q3
RF Front End
Baseband Section
Architecture of RF Front End
Tx Ant
Rx Ant
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WORK DONE …
Study of basic receiver architecturesStudy of TRF3761 Frequency Synthesizer ChipCalculation of data words for programming TRF3761 Filter Design for Phased Lock Loop Frequency Synthesizer PCB designed Design of hardware required to program the chip Testing of frequency synthesizer and reference oscillator Non Linear modeling of LNA and Mixer
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Receiver Architectures
The basic receiver architectures are
Hetrodyne ReceiverDirect Conversion ReceiverLow IF Receiver
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Direct Conversion Receiver
LO frequency is equal to RF carrier frequency
Converts RF signal to Zero frequency and hence called as Zero IF Receiver
Simple Low Pass filter is used
Image reject filter is not required
Well suited for integration whole receiver ON-CHIP.
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Low IF receiver
LO frequency is slightly different from RF carrier frequency.
Converts RF Signal to a very low IF frequency near to dc.
Have advantages of both Zero IF and Hetrodyne architectures but requires image reject mixer which is quite challenging for wideband applications
Less popular compared to Zero IF Architecture.
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Superhetrodyne Receiver
Converts RF signal to lower IF signal
Requires additional intermediate stages such as IF filter
Consumes more power
High Q IF filter are bulky compared to simple LPF for direct conversion type
Least popular architecture for On Chip solution
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Study of TRF3761 Frequency Synthesizer
Block Diagram
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Application Schematic
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Layout
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Assembled Board
Top and Bottom Side of Frequency synthesizer
board with components mounted
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Output
Output of 20 MHz Reference Oscillator
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Frequency Synthesizer Output
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Modeling of LNA and Mixer
Non Linear models of LNA and Mixer developed for the calculation of Intermodulation Products arising due to Simultaneous transmissions of two carriers.
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LNA Modeling
The current can be expressed as
I (v) = c0 + c1V + c2V2 +c3V
3
Where V=A (Cos (w1t) + Cos (w2t)) represents input signal
DC and fundamental terms amplitude is given by
[c0 + c2A2]+ [ c1A + (9/4)c3A
3] [Cos (w1t) + Cos (w2t)] … (E1)
Third order intermodulation terms are given as
(3/4 c3A3) [Cos (w1+2w2) t + Cos (w1-2w2) t
+ Cos (2w1+w2) t + Cos (2w1-w2) t] …. (E2) _
Since w1 and w2 are closer, 2w1-w2 and 2w2-w1 lies closer to w1 and w2
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Equation E1 Shows gain compression with increase in level of input signal and is characterized by 1 dB compression point.
Equation E2 shows that 3rd order distortion increases as cube of amplitude of the applied signal or 3 times in dB. The amplitude of input signal where IMD and Desired signal are equal is known as IIP3 or Input referred third order intercept point.
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using IIP3 and P1dB data, the model is extracted for MGA665P8 from Avago Technologies.
y = 5.3088 Vin-16.882 V3; The model is implemented in Matlab
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Modeling of MixerThe mixer is a non linear device and can be represented by a non linear
polynomial of fourth degree to consider up to 3rd order IMD
The coefficients ci for above can be calculated by analyzing the output for known signal. The parameters taken into consideration to compute the model include LO to IF leakage, RF to IF leakage, Third order intercept point IIP3 and Conversion Loss.
The values of c1, c2, c3, c4 are respectively 0.15263, 0.9142, -0.6, 0.0077 The mixer is implemented in Matlab.LNA and Mixer stages are cascaded and the output at each stage is shown.
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Output Obtained from Non Linear Models of LNA & Mixer
Considering two transmissions received at 935, 935.2 MHz with -25 dBm level of each signal
Input S ignalf1 = 9 3 5 M H zf2 = 9 3 5 .2 M H z
f L O = 1 G H z
O utput S ignalf1 o = 1 9 3 5 M H zf2 o = 1 9 3 5 .2 M H z
+Inte rm o dulat io n
P ro duc ts
L N A
M ixe r
f1 ,f2+
Ine rm o dulat io nP ro duc ts
L O
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LNA Input
Two Signals at 935 & 935.2 MHZ, -25 dBm each.
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Output of LNA
The Intermodulation products are observed at 934.8 and 935.2 MHz
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Output of Mixer
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Considering GSM and WiFi transmission from 1805-1890 MHz and 2400-2420 MHz , the signal at different stages is shown in figure
F(MHz)
P,d
Bm
)
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LNA Output
F(MHz)
P,d
Bm
)
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LNA Output (expanded)
F(MHZ) F(MHZ)
P,dB
m)
P,dB
m)
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Mixer Output1 Down converted
GSM Signal
2 Down converted
WiFi Signal
12
3 Third Order Intermodulation Products of WiFi and LO
3
4 Third order intermodulation product of LO and GSM signal along with RF to IF leakage
4
5 RF to IF leakage of WiFi
5
6,7 Upconverted GSM and WiFi Signals
6
7
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Future Work
The RF band from 400 MHz to 3.4 GHz is to be partitioned into different sub bands to avoid intermodulation products arising from mixing. Major concern is third order intermodulation products.
Types of filters to be used: Wideband RF filter or narrowband tunable filters is to be examined for suitability and compact size implementation.
RF switches used for switching modules for the above mentioned bands is to be done.
The frequency synthesizer hardware is to be finalized.Wideband matching of LNA is to be done over whole band.Analysis and implementation of other subsystems of the receiver and
finally combining all the modules for final receiver system.
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References
[1] J Mitola, "The Software Radio," IEEE National Telesystems Conference, 1992.
[2]Shruti Shrivastava, “Design of a Wideband RF Front–End for Software Defined Radio,” M Tech Thesis, 2008, E&ECE Department, IIT Kharagpur.
[3]J.J. Spilker, “Digital Communication by satellite”, Prentice Hall Inc., Englewood cliffs, New Jersey.
[4] T.H. Lee, “The Design of CMOS RF Integrated Circuits”, Cambridge University Press, 1998
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Contd…
[5]TRF3761 Datasheet, Integer-N PLL with integrated VCO, Texas Instruments Inc.
[6] ADL5350 Datasheet, LF to 4GHz High Linearity Mixer, Analog Devices Inc.
[7] MGA665P8 Low noise amplifier Data Sheet, Avago Technologies.
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THANKS