← LeaderboardsInvestigatorsiAttributed = a PI's even-split share of each grant — a $1M grant with 2 PIs counts $500K each.
Phoebus Optoelectronics Llc
Ithaca, NY
$2,466,336
Total funding
4
Grants
Funding over time
peak $2.1M · FY2006–20$2.5M$1.9M$1.3M$625K$0
'06
'07
'08
'09
'10
'11
'12
'13
'14
'15
'16
'17
'18
'19
'20
Funding mix
By agency
NASA$2,116,714 · 1
NSF$349,622 · 3
By mechanism
—$2,466,336 · 4
Investigators at Phoebus Optoelectronics Llc
InvestigatorsiAttributed = a PI's even-split share of each grant — a $1M grant with 2 PIs counts $500K each.
Exposure= the full size of every grant they're on ($1M each).
Rising Stars
First grant in the last 5 yrs
Not enough data
Emerging Leaders
6–10 yrs in
Not enough data
All-Time
Most funded here, all years
Not enough data
Largest grants
(A) PHOEBUS OPTOELECTRONICS' PRIMARY OBJECTIVE IS TO DEVELOP A HYPERSPECTRAL IMAGING TECHNOLOGY THE METAMATERIAL SPECTROMETER (MS) WHICH MINIMIZES THE TRADEOFFS BETWEEN PERFORMANCE AND THE SIZE WEIGHT AND POWER (SWAP). OUR MS TECHNOLOGY PROVIDES A COMPETITIVE ADVANTAGE OVER CONVENTIONAL OPTICAL SYSTEMS BY ENABLING THE SENSOR TO BE MORE NARROWLY TARGETED THE SPECTRAL BANDS OF INTEREST FOR MEASURING TRACE GASES AND AEROSOLS IN THE EARTH'S ATMOSPHERE. ADDITIONAL OBJECTIVES THAT WILL BE MET ARE: DEMONSTRATE A SWAP REDUCTION RELATIVE TO CURRENT HYPERSPECTRAL SYSTEMS. DEMONSTRATE IMPROVED SPECTROSCOPIC PERFORMANCE RELATIVE TO CURRENT SYSTEMS. PRODUCE SENSOR DATASETS TO QUANTIFY ATMOSPHERIC CONSTITUENTS OR SPECTRAL INDICES FOR LAND AND VEGETATION CHARACTERIZATION. PRODUCE SENSOR DATASETS OF GASES RELEVANT TO EARTH SCIENCE MEASUREMENTS OF THE ATMOSPHERE. MINIMIZE THE TOTAL COST OF THE HYPERSPECTRAL SENSING SYSTEM WHILE MAINTAINING STATE-OF-THE-ART PERFORMANCE. DEMONSTRATE REDUCTION IN DATA PROCESSING TIMES AS A RESULT OF SPECTRAL CHANNEL OPTIMIZATION AND BANDWIDTH PERFORMANCE OF THE METAMATERIAL. PROVIDE A FRAMEWORK AND TESTING PLATFORM TO TAILOR FUTURE ITERATIONS OF THE TECHNOLOGY TO SPECIFIC SENSING MISSIONS. DEVELOP THE FUNDAMENTAL CONCEPTS OF THE TECHNOLOGY TO EXPAND IT TO OTHER SPECTRAL BANDS FROM THE VISIBLE TO THE LWIR. THE ANTICIPATED BENEFITS OF THE PROPOSED TECHNOLOGY ARE: INCORPORATING MANY PIXEL-SCALE FILTERS ELIMINATES THE NEED FOR A DISPERSIVE ELEMENT WITHIN THE SYSTEM. SELECTABLE CHANNELS WITH VARYING PASSBANDS MEASURE ONLY DESIRED CHANNELS SHRINKING DETECTOR ELECTRONICS AND DATA RATE NEEDS. COMPATIBILITY WITH FAST OPTICAL SYSTEMS MAKES BEST USE OF AVAILABLE SIGNAL MINIMIZING APERTURE SIZE FOR A GIVEN MEASUREMENT PERFORMANCE. ENABLE HYPERSPECTRAL FILTERING TECHNOLOGY TO BE USED WITH MINIATURE SPACE PLATFORMS SUCH AS CUBESATS. PROVIDE A FLEXIBLE AND COST-MINDED HYPERSPECTRAL IMAGING PLATFORM FOR A VARIETY OF SPECTRAL BANDS. EXTEND THE MS TECHNOLOGY FOR USE IN SPACE-BASED APPLICATIONS SUCH AS LONG-RANGE LASER COMMUNICATION. (B) THE OUTLINE FOR THE PROPOSED WORK AND METHODOLOGY IS AS FOLLOWS: SIMULATE THE MS FILTER DESIGN FROM THE UNIT CELL TO THE FINITE SCALE STRUCTURES USING INDUSTRY STANDARD ELECTROMAGNETIC SIMULATION SOFTWARE TO OPTIMIZE IN-BAND TRANSMISSION AND OUT-OF-BAND REJECTION. FABRICATE OPTIMIZED DESIGNS USING STANDARD CMOS MICRO-FABRICATION TECHNOLOGIES. OPTICALLY CHARACTERIZE FABRICATED TEST STRUCTURES AND COMPARE PERFORMANCE TO SIMULATED PREDICTIONS. USE OPTICAL CHARACTERIZATION DATA TO REFINE SIMULATIONS OPTIMIZE DESIGNS FABRICATE IMPROVED TEST STRUCTURES AND REPEAT OPTICAL TESTS. ITERATE STEP 4 UNTIL TEST STRUCTURES DEMONSTRATE PERFORMANCE REQUIRED FOR A PROTOTYPE LEVEL DEVICE. FABRICATE AND OPTICALLY CHARACTERIZE THE FULL PROTOTYPE FILTER AS A STANDALONE DEVICE. INTEGRATE THE MS FILTER INTO A COMPLETE OPTICAL SYSTEM FOR MORE IN-DEPTH SYSTEM-LEVEL TESTING (TO BE PERFORMED BY OUR INDUSTRY PARTNER.) QUANTIFY RELEVANT PERFORMANCE DATA OF THE PROTOTYPE SYSTEM AND ESTIMATE THE IMPROVEMENT TO EARTH SCIENCE MEASUREMENTS. (C) PERIOD OF PERFORMANCE: 3 YEARS (D) ENTRY TRL 2 EXIT TRL 5$2,116,714
· FY2020 · National Aeronautics and Space Administration
SBIR Phase I: A Hybrid Metamaterial for Solar Methanol Production$150,000
· FY2010 · TIP
SBIR Phase I: Light-channeling Metamaterials for Polarimetric Sensing$99,872
· FY2009 · TIP
SBIR Phase I: Advanced Silicon-based Photodetectors Using Light Localization and Channeling$99,750
· FY2006 · TIP