CU-Boulder AeroSpace Ventures...University of Colorado Boulder CU-Boulder is one of the nation’s...
Transcript of CU-Boulder AeroSpace Ventures...University of Colorado Boulder CU-Boulder is one of the nation’s...
University of ColoradoBoulder
CU-Boulder AeroSpace Ventures Dr. Dan Baker Director, LASP April 17, 2014
University of ColoradoBoulder
CU-Boulder is one of the nation’s leading aerospace universities •! Over a dozen aerospace-related units on campus
•! #1 public university recipient of NASA awards
•! Over $100M in aerospace-related research expenditures
www.colorado.edu/aerospace/cu-aerospace-ventures
University of ColoradoBoulder
CU-Boulder AeroSpace Ventures Crossing the boundaries between
science and engineering & academia and industry
CU AeroSpace Ventures is a collaboration among aerospace-related departments, institutes, centers, government laboratories and industry partners to create knowledge and develop new technologies specifically focusing on:
•! Unmanned and autonomous aircraft •! Small satellites •! Earth and space sensors
University of ColoradoBoulder
CU-Boulder AeroSpace Ventures Through CU-Boulder AeroSpace Ventures, these partnerships will:
•! Accelerate discoveries in Earth and space science
•! Broadly educate tomorrow’s highly-skilled workforce
•! Develop technologies that create new commercial opportunities
•! Create collaborations that help industry grow
University of ColoradoBoulder
CU-Boulder AeroSpace Ventures…
…In Education –! Hands-on learning; student projects targeted at corporate
needs; multidisciplinary teams; professionally-prepared students
…In Research –! Space situational awareness; severe weather and
climate; global water cycle; space exploration …In Industry
–! Create new innovations & technologies for new products; bring new funding into Colorado through joint research with industry; distance learning for working professionals
University of ColoradoBoulder
Industrial Partnerships with CU-Boulder Industrial relationships are important components of CU-Boulder’s aerospace research and education programs. Through CU AeroSpace Ventures, there are numerous opportunities to form partnerships with campus activities for mutually beneficial outcomes.
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University of ColoradoBoulder
CU-Boulder AeroSpace Ventures Founding Corporate Partners
*Featured on CU-ASV website.
LOC HE D
SIERRA NEVADA
Space svstems SATE ITE TECH OLOGY US
CU-Boulder Engineering Overview Vision for Excellence:
•! World leader in engineering research and education
•! Engineering for global society •! Active, discovery-based learning
I hear . . . I forget I see . . . I remember I do . . . I understand
Confucius, c 500BC
Presentation by Dean Robert H. Davis at the CU-Boulder AeroSpace Ventures Day 4/17/2014
•! Inclusive excellence
University of Colorado Boulder
CU-Boulder is the flagship campus of a four-campus system
•! Founded 1876 (Engineering started 1893)
•! Seven Schools & Colleges !! Arts & Sciences !! Business !! Education !! Engineering & Applied Science
•! Dynamic Community of Scholars !! 25,000 undergraduates !! 5,000 graduate students !! 5 Nobel Prize winners !! 6 federal research labs (NCAR, NIST,
NOAA, NREL, USBR, USGS) !! Strong corporate partners
!! Graduate School !! Law !! Music
CU Engineering by the Numbers – Fall 2013 6 Departments
16 degree subjects
3657 Undergraduates +25% in past 6 years
875 Female undergraduates +56% in past 6 years
421 URM undergraduates +87% in past 6 years
33 Boettcher scholars & semifinalists (among current freshmen)
1623 Graduate students +35% in past 6 years
$72M Research grant awards +80% in past 6 years
Top-ranked program in Mountain Time Zone
CU Engineering by the Numbers – Fall 2013
Ways to Engage
Thank you, and enjoy AeroSpace Ventures Day!
Ways to Engage !! Educational partnerships: Senior projects,
innovative programs
!! Research partnerships: Cooperative grants, research center membership
!! Employment opportunities: Internships, co-ops, permanent jobs
!! Volunteer service: Advisory committees, guest lectures, alumni events, mentoring
!! Philanthropy: Scholarships, fellowships, student societies, programs, facilities, named faculty positions
co-ops, permanent jobs
!
!
University of ColoradoBoulder
CU-Boulder AeroSpace Ventures Faculty Presentations April 17, 2014
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•! Demonstrate principal element of ~30 member 3U CubeSat constellation for weather forecasting and polar monitoring: –! Sounding and sea ice edge detection in polar regions through clouds –! Hydrometric tracking and forecasting of rapidly varying mesoscale
convection and hurricanes –! Radiance assimilation of thermodynamic variables for up to 7-day
forecasting •! Achieve NRC Decadal Survey PATH objectives at a fraction of cost of
geostationary microwave sensors •! Exceed JPSS/ATMS spatial resolution (2x) and repeat time (25x) •! Develop NIST SI traceable calibration in mass production •! Robust inexpensive 3-axis stabilized bus (CU ALL-STAR) with cross-
track scanning mirror (16 km nadir resolution) •! 8-channel 118.75 GHz O2 temperature imager/sounder with potential
for 118/183 GHz payload •! Entire bus and payload designed and fabricated by CU student team
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•! NASA ELaNa launch awarded (launch –ready mid 2015) •! USAF University Nanosat Program Phase I award
–! PDR August 2013 –! CDR February 2014 –! EDR Summer 2014 –! FCR/Engineering unit Dec 2014
•! ALL-STAR/THEIA launch (bus S/N 001) April 2014 •! Future S/C builds to focus on:
–! Downlink communications and latency –! Additional bands (50-57, 183, 325, 670 GHz) –! Deployable antennas
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•! NASA Phase II SBIR awarded March 2014 to BST •! Lobe Differencing Correlation Radiometer (LDCR) fabricated
and under testing, NDVI sensor developed •! CoCo antenna integration into Tempest UAS underway •! 250 MS/s TB solid state recorder and FPGA digital correlators
in development •! New RFI mitigation and signal detection algorithms under
development •! NASA SMAP mission validation and spatial scaling studies
planned for early-mid 2015 •! Proposed for use in future NASA Aquarius coastal validation studies in 2015-16
•! Remote aerial mapping of soil moisture and NDVI for –!Agriculture –!Drought monitoring –!Trafficability assessment –!Flood runoff prediction –!NASA SMAP Satellite algorithm validation/SM scaling studies
•! Achieve unprecedented spatial resolution (15 m) and local area coverage (1 ha/hr) determined by altitude
•! Based on NASA WMAP radiometer architecture •! Use cell-phone manufacturing technologies to achieve
unprecedented SWAP reduction •! Secondary application to coastal salinity mapping Joint project between CU/ECEE Center for Environmental Technology (CET) and Black Swift Technologies
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•!NSF and NASA has funded development of the GPS reflection technique; it is operational for a network of ~400 sites in the western United States.
•!Daily results: http://xenon.colorado.edu/portal . •!Can be extended world-wide. •!Next: GPS reflections on UAS platforms or from
satellites.
•!Measurements of soil moisture, vegetation water content, and snow depth (and snow water equivalent) are needed for climate studies and to predict/mitigate effects of drought/flooding.
•!Reflected GPS signals are sensitive to these environmental parameters. Existing GPS sites (installed by geoscientists and surveyors) can be used to simultaneously measure location, timing, and reflection quantities.
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•!ATOC faculty join forces with AE faculty to test UAS for collecting the required data
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Increase the interactions between industry and CU-Boulder for the benefit of the companies, students, the economy, and CU. •! Support industry partners interested in connecting to
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Provide GPS-based position and time solutions: •! Without continuous tracking or nav data decoding •! Instantaneous with < 10 ms of antenna exposure •! Robust to interference by enforcing consistency
among contributions from multiple transmitters •! Ability to incorporate new GNSS and SBAS signals •! Determine solution by direct search in the position
and time domain, rather than acquiring and tracking •! Use predicted orbit & clock models from the internet
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•!%:);"6)=%E,0&%•!%:);"6)=%=$)670/7\);%^,%g%E,%•!%F03%D)%)b#)3;);%#'%3)(%=7130/=%'C%'$$'*#"37#8%•!%:'D"=#%='/"<'3=%73%6@0//)31731%)3>7*'3B)3#=%
e)>)*01)%?3'(/);1)%C*'B%'#@)*%=)3='*=%03;%>70%0/#)*30#)%6'BB"3760<'3=%/73?=%#'%H3;%B'=#%/7?)/8%/'60<'3%"=731%0//%0>07/0D/)%c&E%=7130/=%;7*)6#/8N%
•! Algorithms coded in MATLAB demonstrated using simulated and live sample data recordings.
•! Currently in SBIR Phase 1 for small satellites •! Next - leverage DSP and efficient search algorithms to
reduce memory usage and increase speed •! Customize approach for new application scenarios &
requirements
!"#$%&'$()-,6)B$(%/94&+,)
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36'-,%$6)I9>0.-&+,)-,6)B$(9L,)+E)1,(7/0>$,7(A))B/C)D0/7)T-07$)F3<IG)
•!Hyperdust –!Completed initial design. Developing novel shape and topology
optimization tools to achieve low structural mass, large target area, better mass resolution, and improved trajectory resolution.
•!CULPIS –!Completed analysis of local aircraft structural behavior due to
static inertial and dynamic aero loads on instrument package. •! Flow Sensor
–!Developed fully-coupled 3-D fluid-structure interaction FE model of instrument for exploration of low Reynolds number flows.
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Analysis and Design of Complex Engineering Systems via High-Fidelity Numerical Simulation and Optimization. •! Hyperdust
–!Detailed design of instrument for in-situ analysis of cosmic dust for mass, velocity, charge, and composition.
•! CULPIS –! Perform structural analysis for flight safety of sea ice observation
platform for US Coast Guard C-130 flights over arctic waters.
•! Flow Sensor –!Analysis of complex fluid-structure interaction behavior in Coriolis-
effect flow sensors
!"#$%&'$()-,6)B$(%/94&+,)
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•! Over 8800 HDTV towers broadcast with enough power to be easily received at the Moon or beyond.
•! These signals may be converted into navigation data for spacecraft, from Earth orbit out to the Moon.
•! One tower is sufficient, but we can uniquely identify dozens of towers at any given time.
•! Objective of research: to demonstrate autonomous spacecraft navigation using these Signals of Opportunity (SoOps).
•! Working with Loctronix’s ASR-2300 radio, which can pick up any HDTV tower transmissions, GNSS, and even S-Band.
•! Demonstrating SoOps navigation on the ground. •! Preparing to demo SoOps on an aircraft (July). •! Preparing to demo SoOps on a high-altitude balloon. •! This work will support a 6U-cubesat mission to be
deployed on Orion’s EM-1 mission to the Moon in 2017.
Colorado Center for Astrodynamics Research
•! Low-Cost Navigation: HDTV transmissions can be received using COTS hardware and omni-antennae.
•! Autonomous Spacecraft Navigation: SoOps navigation does not require active ground tracking.
•! Improved Navigation Accuracy: There is an immense amount of free tracking data available to be used stand-alone or to supplement ground tracking.
•! Applications: GPS updates, GEO navigation, autonomous operations, Orion navigation.
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2&+&3)*+,-*400/1+%5 6,-3)&/7*4008'%+&'1,• Research has led to 137 conference !
and 91 journal papers • Graduate researchers have received 16 !
national fellowships, plus numerous awards • Internationally recognized program for:
• spacecraft control developments • hardware-in-the-loop simulations • complex dynamic simulations • experimental research on space actuation and
sensing
Injected Electrostatic Force Field
GEO-DebrisGLiDeR
Electrostatic Tractor
Active Electrostatic Force Field
Inertial Thrusting
Dr. Schaub’s Research Group!Autonomous Vehicle Systems (AVS)Lab
• Spacecraft formation flying and !rendezvous and docking
• Nonlinear dynamics and control • Attitude dynamics and control • Fault tolerant, autonomous control • Space debris mitigation and remediation • Visual relative motion control • Touchless despinning of passive space objects • Gossamer structure dynamics such as tethered
tugging or charged membrane structures
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• 738*%5$32(+*5$5#*9"2*""-":3$2*%32#$.*"-8$241"-1%251%"#1.2
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• >1#5$D"1#E:$2413$.-%&23:$2"12(+*5$5#*9"25'*#&-%&
Schaub Research Highlights, [email protected], September 23, 2013
Electrostatically Inflated Membrane Structures (EIMS)
!6
- Studying how charged membranes behave.
- Suitable for shape-changing HAMR modeling
- EIMS provide light-weight deployable structures
!"#$%&'($)*+,-*.$)%/'0&'1,
Autonomous Vehicle Systems (AVS)Lab
Spacecraft formation flying and
Nonlinear dynamics and control Attitude dynamics and control Fault tolerant, autonomous control
Schaub Research Highlights, [email protected], September 23, 2013
Electrostatically Inflated Membrane Structures (EIMS)
!6
- Studying how charged membranes behave.
- Suitable for shape-changing HAMR modeling
- EIMS provide light-weight deployable structures
national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards Graduate researchers have received 16Graduate researchers have received 16national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards national fellowships, plus numerous awards Graduate researchers have received 16Graduate researchers have received 16Graduate researchers have received 16Graduate researchers have received 16Graduate researchers have received 16Graduate researchers have received 16Graduate researchers have received 16Graduate researchers have received 16Graduate researchers have received 16Graduate researchers have received 16Graduate researchers have received 16Graduate researchers have received 16
Touchless Detumbling Research Overview – March 12, 2014
Laboratory Experiments
!6
Uncontrolled SpinSettles in about 14
seconds
Settles in about 14 seconds
Takes minutes to settle
Aerospace Engineering SciencesUniversity of Colorado, Boulder
!"#$%&'$()-,6)B$(%/94&+,)
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>4%5%"#79&?%<-053#"/-0&-#&@#"29*7A&
•!Full success reqs: 120/90 days of ops/science •!Currently: 564/356 days of ops/science •!Still operational
•! Major challenges include low budget, student turnover, and student inexperience
•! Approach: thorough design, analysis, and documentation with a keep-it-simple paradigm
•!Design, build, and operate a 3U CubeSat to investigate harmful electrons and protons in near-Earth space
•!Student led with advisement from professionals from the Laboratory for Atmospheric and Space Physics (LASP) and AES
•!Over 60 students involved •! Launched from Atlas V-401 (NRO-L36)
September 13th, 2012 •! Funded by NSF for < $1M
Strengths Capability
•! Inexpensive space weather monitor
•! Low budget, yet robust and reliable
•! Provides valuable science data
•! Accurate measurements of harmful particles
•!Exceeding expectations •! Nearly 5x nominal mission lifetime Nearly 5x nominal
!"#$%&'$()-,6)B$(%/94&+,)
I7-70()-,6)344/+-%5) 1,60(7/8)344.9%-&+,)•! Device performance is reaching commercially viable
levels for several applications.
!/L-,9%)<.$%7/+,9%()E+/)Z9L57@$9L57)?5+7+'+.7-9%()-,6)U/-,(9(7+/)B$'9%$(A))B/C)I$-,)I5-5$$,)
B0&%C"<2$%&-;&39%&<%79"0*7"$&2#-2%#/%5&-;&"0&.$3#"D$*:93E%*:93&-#:"0*7&29-3-F-$3"*7&+%F*7%G&
•! Organic, aka “plastic”, electronics (OEs) are emerging as an innovative technology that is complimentary to conventional electronics in many ways.
•! Current devices being researched or commercially manufactured include OPVs, OLEDs, and OFETs.
•! The aim of OEs is to take advantages of their low-cost, fast design-to-fabrication cycle, and desirable mechanical properties.
E#*)31#@=% F0$0D7/7#8%•!%!&.%'3%"/#*0#@73%="D=#*0#)%)b@7D7#=%#@)%@71@)=#%$'()*W#'W()71@#%*0<'%+LP%,V1-%'C%038%&.%#)6@3'/'18N%%•!%!X4[=%@0>)%;)B'3=#*0#);%)b6)//)3#%*0;70<'3%@0*;3)==%'C%@"3;*);=%'C%?*0;KN%
•!%[@)%E@0@))3%1*'"$%@0=%60$0D7/7<)=%#'%;)=713Z%D"7/;Z%03;%#)=#%!4=%C'*%0%>0*7)#8%'C%0$$/760<'3=N%
jLk%U/#*0#@73%03;%/71@#()71@#%'*10376%='/0*%6)//=%(7#@%@71@%f)b7D7/7#8Z%YN%l0/#)3D*"33)*%)#%0/NZ%C)0.(3LJ.28-)=42+&gZ%QQP%+KPLK-N%jKk%mW*08%7**0;70<'3%)_)6#=%73%#'$%6'3#06#Z%$)3#06)3)%D0=);%H)/;%)_)6#%#*03=7=#'*=%C'*%=$06)%*)/0#);%0$$/760<'3=Z%:NINaN%G)>73)Z%)#%0/NZ%9::/B&D61+B&E3FB%hhZ%LRLSPQ%+KPPn-N%
!"#$%&'$()-,6)B$(%/94&+,)
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<=%9$,7)I>-..)I%-.$)?/+40.(9+,A)B/C)H8-,)I7-/X$8)F3<IG)
8.#)-H%3&I0:*0%5&
•!Develop the next generation of efficient small scale propulsion systems for use in: –!Unmanned aircraft –!Gliders (take-off/sustainer propulsion) –!Decoy and missile systems –!Research aircraft
•!Enables new systems due to advanced capabilities compared to state-of-the-art: –!2X efficiency, >20X time-between-overhaul
E#*)31#@=% F0$0D7/7#8%
%%%%%^71@%[@*"=#%%%%%%^71@)=#%X")/%4567)368%+oKm-%%%%%%4b$03;);%!$)*0D7/7#8%%%%%%%%%%%%40=)%'C%=#0*<31%%%%%%E#'*0D7/7#8Z%:)/70D7/7#8%%%%%%%e71@#%,)71@#%%%%%%e'(%F'=#%
KPPh%/DC%PNQ%/DBV+/DC%@*-%MPh%?]Z%LPPPh%B$@Z%%%%%LPPPh%@*=%[a!%,73;WY7//731%T'%'7/V$8*'%=8=#)B=%%p%LM%/D=%[aG%
•!Eliminate lubrication and starter systems –!Advanced bearings and overall engine design
•!Reduce system part count •! Improve component design/interoperability •! Improved compression and combustion •!Unique capabilities include: articulating nozzle,
afterburner, power generation, thrust vectoring
%%%%%^71@%[@*"=#%%%%%%^71@)=#%X")/%4567)368%+oKm-%%%%%%4b$03;);%!$)*0D7/7#8%%%%%%%%%%%%40=)%'C%=#0*<31%%%%%%E#'*0D7/7#8Z%:)/70D7/7#8%
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!"#$%&'$()-,6)B$(%/94&+,)
I7-70()-,6)344/+-%5) 1,60(7/8)344.9%-&+,)
W9L5;I4$$6):,>-,,$6)39/%/-dA)B/C)H8-,)I7-/X$8)F3<IG)
,.2%#5-0*7&B*#7#"J&•!Develop technology for low cost, unmanned
aircraft for high-speed flight testing: –!Novel configurations/control systems –!Sonic boom reduction –!Hurricane penetration –!Transonic/supersonic testing –!Missile, ISR applications –!Advanced engine testing (combined-cycles) –!Component testing/qualification in relevant
environments
E#*)31#@=% F0$0D7/7#8%^71@%E$));%e'(%F'=#%e71@#%,)71@#%^71@%[@*"=#W#'W,)71@#%EB0//%=60/)%e'31%*031)%%
Y06@%LNM%+oLPPP%B$@-%qRPZPPP%LPP%/D=%K%+>)*<60/%#0?)W'_r-%n%]%/'31%b%R%]%=$03%oKPP%B7/)=%s%YtLNM%RPPh%B7/)=%s%YtPNS%
•!All major components designed, built, verified •! Integration beginning Spring 2014 •!Low-speed flight testing (250 mph) Fall 2014 at
New Mexico UAS Flight Test Center •!Data to be used to finalize supersonic design
Spring 2015 •!Supersonic flight testing Fall 2015
,.2%#5-0*7&B*#7#"J&
!"#$%&'$()-,6)B$(%/94&+,)
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3%&'$)H$>+7$)I$,(9,L)Z-"A))2+'$.)Z96-/)U$%5,9[0$()))B/C)]$e)U5-8$/)
•! Field deployed lidar systems in Kangerlussuaq and Summit Camp, Greenland
•! Prototype INPHAMIS lidar bathymetry system with demonstrated ability to measure shallow water regimes with 1-cm depth accuracy and 4-mm precision –!Patent-pending technology –!Exclusive license agreement with ASTRALiTe Inc. –!Developing a portable system for deployments in the field
•! Develop new lidar techniques based on fundamental scattering processes for broad applications –!Rayleigh, Mie, Raman, Resonance, Polarization
•! Applied to atmospheric and ocean remote sensing –!Tropospheric water vapor –!Cloud thermodynamic phase and ice particle orientation –!Aerosol detection and shape estimation –!Meteoric Alkali metal resonance –!Shallow water lidar bathymetry
•! Innovative use of polarization to isolate intrapulse phase modification induced by scattering (INPHAMIS)
E#*)31#@=% F0$0D7/7#8%•!%43@036);%:031)%:)='/"<'3%•!%&*)67=)%Y)0="*)B)3#%•!%T'%F'3#06#%(7#@%Y);70%•!%G7=#036)%E0B$/731%•!%e'(%F'=#%E'/"<'3%•!%I66"*0#)%03;%E60/0D/)%•!%G7_)*)3<0/%Y)0="*)B)3#%3'#%%%%%%%%%%*)A"7*731%$/0u'*B%$'=7<'3%
•!%E@0//'(%(0#)*%;)$#@=%•!%,0#)*%f''*%#'$'1*0$@8%B0$=%•!%E"DB)*1);%'Dv)6#%;)#)6<'3%•!%E)B7#*03=$0*)3#%B);70%%%%%%%%%%#@76?3)==%B)0="*)B)3#%•!%E"*C06)%*'"1@3)==%%%%%%%%%%%6@0*06#)*7\0<'3%
2T&^IY2E%
!"#$%&'$()-,6)B$(%/94&+,)
I7-70()-,6)344/+-%5) 1,60(7/8)344.9%-&+,)
*8"$/;458(9%-.)T-7$/9-.(A)B/C)29X+.-0()*+//$..)F*IG)
•! Multiple approaches to stiffness change –!Sheet jamming –! Low melting point metal/polymers
•! High-bandwidth sensing –!Real-time spectral analysis of sensor input within the material –!High-frequency NDE
•! Standardized hardware infrastructure, nation-wide collaborations on materials and NDE
•! Novel class of composite materials that tightly embed –!Sensing –!Actuation –!Computation
•! Applications –!Non-destructive evaluation –!Morphing capabilities –!Appearance change
E#*)31#@=% F0$0D7/7#8%•!236*)0=);%*)/70D7/7#8%03;%*);"6);%;'(3<B)%;")%#'%73W=7#"%B)0="*)B)3#=%•!236*)0=);%$)*C'*B036)%03;%)567)368%;")%#'%0;0$<>)%=@0$)%6@031)%
F&Y=%)30D/)%@71@WD03;(7;#@%=)3=731%82+8'3&063&-45:4+803Z%C*'B%?^\%#'%c^\%03;%06<>)%6'3#*'/%'C%$'/8B)*%$*'$)*<)=%0#%@71@%*)='/"<'3N%
Y0#)*70/%E67)36)%43173))*731%V%F'B$"#)*%E67)36)%
!"#$%&'$()-,6)B$(%/94&+,)
I7-70()-,6)344/+-%5) 1,60(7/8)344.9%-&+,)
D-/X)3L$()H-69+)<c4.+/$/)FB3H<GA)B/C)3"59/04)B-a-)
•!Mission will be proposed for the upcoming SMEX opportunity (end of 2014)
•!Extensive Laboratory Tests to demonstrate the feasibility of high dynamic range (! !""## ) calibration.
•!Engineering Prototype testing to demonstrate the integrated instrument is at TRL 6.
•!Demonstrate that the effect of RF Interference and the Ionosphere will be severe limitations for a DARE-like experiment from the ground.
•!The science objectives of DARE include formation of first stars, first accreting black holes, beginning of reionization and end of the Dark Ages.
•!Measure the sky-averaged 21-cm signal using a single radiometer between 40-120 MHz (z=11-35).
•!DARE will orbit the Moon for $% years and take data only above the lunar far side, where it is shielded from the Earth’s intense RF Interference.
•!Absence of Ionosphere will help to achieve the !!""## dynamic range to detect the faint cosmic signal.
E#*)31#@=% F0$0D7/7#8%
•!%Unique science case & wavelength for a SMEX mission.
•! Efficient, low cost, high science return mission
Low-risk instrument design that can achieve 1 ppm calibration High heritage space-craft (BALL), launch innovation (secondary payload).
!! The Turbulence and Energy Systems Laboratory (TESLa) focuses on numerical simulations of turbulent flows!
!! The simulations are used for fundamental flow studies, model development, design optimization, and performance analysis!
!! There are three core areas of research at TELSa:!1.! Turbulence modeling (e.g. vorticity dynamics
and nonequilibrium modeling, panel a)!2.! Geophysical turbulence (e.g. upper ocean
dynamics, panel b)!3.! Reacting flows and combustion (e.g. flame-
turbulence interactions, panel c)!!! Applied research topics are examined at the
intersections of the three core areas:!1.! Wind and ocean renewable energy (e.g. ocean
and wind current turbines, panels d and e)!2.! Ocean carbon cycle and contaminant
transport (e.g. chemical species, plankton, oil)!3.! Propulsion and transportation (e.g. rotating
detonation engines, panel f)!!! Funding from NSF, NREL, AFOSR!!! Contact: Prof. Peter Hamlington at
[email protected] or 303-492-0555.!
a! b!
d!
e! f!
c!
!"#$"%&'(&)*'+),'&#-.)/.01&20)3*$4#*14#.5)6#7)8&1&#)9*2%:'-14');<,=)
Aerospace and Defense Industry Leading Colorado To The Next Level
AeroSpace Ventures
Jay Lindell CO Aerospace & Defense Industry Champion; 17 Apr 2014
Ecosystem Catalyst
2
CO Champions
Industry
State, Federal
Delegation EDC’s
Military
R&D
Academia Technologist
Capital Investor
Media General Public
Non-profits
Trade Associations
“Intensify Cluster Dynamics”
“Amplify”
“Build Trusting Partnerships”
“Complement”
Colorado Aerospace Economy
• 400 + companies provide space-related products, services; most small business tier 2/3 suppliers
• 1st in nation per capita in aerospace employment; 24,990 employees; $3B payroll
• Colorado 3rd in nation in private aerospace direct employment - 170,000 + in related jobs (telecomm, IT) - 17.3% CO aerospace growth in past 10 years
(6.1% nationally) • Colorado 3rd in nation in science &
technology investments • Anchored in government R&D & procurement programs
3
“The space economy is an outsized driver of Colorado’s economy” Brookings Institute, Launch Report , Feb 2013
Aerospace Small Business Avior Control Technologies
4
Eddy Current Adapter
Actuator for NASA Lunar Robotic Mission
Solar Array Deployment Actuator
Rotary Switch for NASA Lunar Robotic Mission
Small Business
5
GPS – Key Enabling Technology
6
Unmanned Aerial Systems
7
8
Unmanned Aerial Systems
Unmanned Aerial Systems
9
Unmanned Aerial Systems
10
Unmanned Aerial Systems
11
CU RECUV
12
Research and Engineering Center for Unmanned
Vehicles
Additive Manufacturing
13
Additive Manufacturing
14
Leading CO To The Next Level
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“Colorado is 1 of 10 States poised to create new jobs & see an economic boom in 5 to 10 years.” National Chamber Foundation, 2012