Enabling Next Generation Radar, Communications and Electronic Warfare with GaN Technology
Richardson RFPD
IMS June 2012
Eric Higham [email protected]
Advanced Defense Systems (ADS) Service
Agenda
• Introduction
• Evaluating platforms, key systems and components
• Trends in EW, radar and communications
• Enabling Technologies – the role of GaN
• Conclusions
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3
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System Contract Analysis
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Designed to Meet the Needs of Defense Market Planners
Agenda
• Introduction
• Evaluating platforms, key systems and components
• Trends in EW, radar and communications
• Enabling Technologies – the role of GaN
• Conclusions
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Projecting Defense Platform Opportunities
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Assessing Opportunities in Key Systems
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ADS
RADAR
EW
Sensors
Smart Weapons
Comms
Computers
Translating into Component Opportunities
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Si
GaAs GaN
Other
By Function By Technology
Agenda
• Introduction
• Evaluating platforms, key systems and components
• Trends in EW, radar and communications
• Enabling Technologies – the role of GaN
• Conclusions
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Enabling the First Line of Defense
Radar
Comms Electronic Warfare
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Overview of Electronic Warfare
Electronic Warfare
Electronic Attack
Electronic Protection
Electronic Warfare Support
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EW Systems Trends
Wideband
Sensitivity
Power
Selectivity
Processing
Receive Channel
Receive Channel
Digital Processing
Transmit Channel
Transmit Channel
Wideband Receiver
Digital Processing ADC RF in
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High Profile Examples
F-35
AN/APG-81 Northrop Grumman
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“Teen Series”
F-15 • APG-63(V)3 • Raytheon
F-16 • APG-80 • SABR • Northrop
Grumman • RACR • Raytheon
F/A-18 • APG-79 • RACR • Raytheon
Naval Platforms – TRS-4D
Cassidian launched the TRS-4D surveillance and target multifunction naval radar
AESA radar combined with mechanical rotation in azimuth
Using GaN transmit modules
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Land-Based Platforms – G/ATOR
Short Range Air Defense
Air Defense Counterfire
Target Acquisition
Air Traffic Control
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AN/TPS-80
Northrop Grumman
Communications Systems Trends
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Battlespace netcentricity
Multi-mode
Multi-band
SDR and cognitive
Data
Future Trends for Defense Technologies
• Budgets and systems – SWaP-C
– Emphasis on cheaper, faster, better
– Upgrading capabilities
• Common requirements from electronics systems – Broadband
– Power
– Linearity
– Digitization
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Agenda
• Introduction
• Evaluating platforms, key systems and components
• Trends in EW, radar and communications
• Enabling Technologies – the role of GaN
• Conclusions
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GaAs Power Device Thermal Limit
InP Power Device Theoretical Limit
GaN Power Device Theoretical Limit
Vacuum Tube Regime
GaN Power Device Thermal Limit
?
Enabling Technologies
SiGe Power Device Theoretical Limit
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Technology Overview: Current and Emerging
• Wide bandgap (3.4eV), high breakdown voltage, extremely high power density, and high gain
• Thermal conductivity further improved when producing devices on SiC
Source: GaAs, GaN Microelectronics Market Update 2009-2014, published Apr’10
~2.0 4.9 --- --- 0.5 1.5 Thermal
conductivity (W/cmK)
>30 10 0.3 --- 0.5 0.2 Power density
(W/mm)
150 20 50 300 150 20 Ft (GHz) FET
3.4 3.3 (4H) 0.7-1.1 1.3 1.4 1.1 Eg bandgap (eV)
1500 900 3000 10000 8000 1350 e-mobility (cm2/Vs)
2.5 x 107 2 x 107 --- 2.2 x 107 0.8 x 107 1 x 107 Saturation
velocity (cm/s)
3.2 3.1 5.5 5.9 5.7 5.4 Lattice constant
(Å)
GaN SiC SiGe InP GaAs Si Metric
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Production Military Markets for GaN
Electronic Warfare • Uses broadband and high-power microwave emission • Disrupt and jam RF signals used to detonate IEDs
AESA Radar • Arrays rely on hundreds or thousands of T/R modules that can be phase shifted to form
and steer the beam • So many modules place a premium on size, weight, power efficiency and high power
performance
Tactical Radio Communications • “Network-centric” battle philosophy demands agile, broadband communications
channels • Radios may have to operate over a frequency range of 30-3000 MHz at power levels up
to 100W, while accommodating portable, manpack and vehicle mount form factors
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GaN Market Forecast
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Military applications will account for >66% of GaN revenue in 2015
Agenda
• Introduction
• Evaluating platforms, key systems and components
• Trends in EW, radar and communications
• Enabling Technologies – the role of GaN
• Conclusions
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Conclusions
• Compound semiconductor technologies have enabled defense systems.
• Future generations of radar, communications and EW systems will continue to drive demand for compound semiconductor capabilities.
• Strategy Analytics forecasts that GaN will become a pivotal technology leveraging high power, wideband and high frequency attributes.
• Military applications will account for more than 2/3 of GaN revenue in 2015
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Thank you for your attention!
Q&A
For further details on this analysis or other research areas, see http://sa-link.cc/ADS
Or contact;
> Michael McMurray, Director Business Development, +1 617 614 0725, [email protected]
> Eric Higham, Director (North America) ADS Service, +1 617 614 0721, [email protected]
> Asif Anwar, Director Strategic Technologies Practice, +44 1908 423635, [email protected]
Advanced Defense Systems (ADS) Service
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