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Makel Engineering, Inc.

Chico, CA

Compare ↔
$1,932,254
Total funding
6
Grants

Funding over time

peak $1.3M · FY200720
$2M$1.5M$1M$500K$0
'07
'08
'09
'10
'11
'12
'13
'14
'15
'16
'17
'18
'19
'20

Funding mix

By agency

DOE$1,638,252 · 3
NSF$149,651 · 1
NASA$144,351 · 2

By mechanism

$1,932,254 · 6

Investigators at Makel Engineering, Inc.

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

SBIR-PHASE I NEW; INTEGRAL PACKAGING OF HIGH TEMPERATURE CHEMICAL SENSORS FOR IN-SITU MEASUREMENTS; SUSANA CARRANZA$1,296,000
· FY2012 · Department of Energy
NEW SBIR PHASE I 2009: STANDARDIZED SENSOR PACKAGING FOR HARSH ENVIRONMENT; PI - SUSANA CARRANZA$192,414
· FY2009 · Department of Energy
HIGH RESOLUTION FAST RESPONSE NOX SENSOR FOR HIGH FUEL EFFICIENCY VEHICLES$149,838
· FY2013 · Department of Energy
STTR Phase I: Solar Driven Electrochemical Manufacture of Hydrogen Peroxide using Microreactor Technology$149,651
· FY2007 · TIP
THIS PROJECT WILL DEVELOP SILICON CARBIDE (SIC) BASED ELECTRONICS CAPABLE OF OPERATION AT 500 DEGREES CELSIUS TO SUPPORT PREVIOUSLY DEMONSTRATED HIGH TEMPERATURE CHEMICAL SENSORS FOR USE IN HARSH ENVIRONMENTS SUCH AS VENUS SURFACE AND GAS GIANTS. THE VENUS CHEMICAL MICROSENSOR ARRAY (VCMA) WHICH HAS BEEN SEPARATELY DEVELOPED AND DEMONSTRATED UNDER A NASA PHASE II SBIR CONSISTS OF HIGHLY SELECTIVE SOLID STATE CHEMICAL MICROSENSORS (CO NO OCS SOX O2 H2O HF AND HCL) THAT CAN OPERATE AT AND ABOVE 500 DEGREES CELSIUS BUT RELIES ON SILICON-BASED SUPPORT ELECTRONICS LIMITED TO 125 DEGREES CELSIUS OPERATION. THE DEVELOPMENT OF SIC ELECTRONICS IS THE KEY TO ENABLE UNCOOLED LONG DURATION OPERATION AT THE SURFACE OF VENUS. WE WILL DESIGN AND FABRICATE APPLICATION SPECIFIC INTEGRATED CIRCUITS (ASICS) USING NASA DEMONSTRATED SIC TECHNOLOGY TO ENABLE LONG LIVED (100S OF DAYS) CHEMICAL SENSOR MEASUREMENTS ON VENUS SURFACE. THIS PROJECT WILL FOCUS ON THE DEVELOPMENT OF CORE SIC ELECTRONICS FOR AMPLIFICATION ANALOG CONTROL FEEDBACK AND ANALOG TO DIGITAL DATA CONVERSION REQUIRED FOR SENSOR OPERATION. DEVELOPMENT WILL BE BASED ON PREVIOUSLY DEMONSTRATED SIC COMPONENTS THAT HAVE NOT YET BEEN COMBINED INTO THE HIGH LEVEL INTEGRATED CIRCUITS NEEDED TO SUPPORT MANY TYPES OF INSTRUMENTS INCLUDING VCMA. MATURATION OF HIGH TEMPERATURE ELECTRONICS REDUCES RISK TO FUTURE INSTRUMENT DEVELOPMENT SUPPORTING OVERALL MISSION OBJECTIVES AND PROVIDING SCIENCE RELEVANT TO DECADAL AND VENUS EXPLORATION ANALYSIS GROUP (VEXAG) GOALS. MAKEL ENGINEERING INC. (MEI) WORKING ALONG WITH CO-PI S FROM NASA GRC AND NASA JPL WILL USE THE NASA GRC MICROFABRICATION FACILITIES FOR DEVELOPMENT OF THE SIC ELECTRONICS. MEI WILL PROVIDE THE EXPERTISE ON SPECIFIC CIRCUIT DESIGNS AND ASIC ARCHITECTURE FOR THE MICROSENSORS. NASA GRC WILL PROVIDE EXPERTISE ON CIRCUIT IMPLEMENTATION IN SIC AND DEVICE FABRICATION USING THE NASA GRC MICROSYSTEMS FABRICATION LABORATORY. DEMONSTRATION AND VALIDATION OF THE ELECTRONICS WILL BE CONDUCTED BY MEI AN JPL BY INCORPORATING THE SIC ELECTRONICS WITH THE VCMA INTO A SENSING PACKAGE FOR USE IN JPL S ONGOING TERRESTRIAL VOLCANIC TEST PROGRAM WHICH SERVES AS A HOT PLANETARY TESTBED. THE DECADAL SURVEY IDENTIFIES THE VENUS IN-SITU EXPLORER MISSION (VISE) FOR NEW FRONTIERS TO IN PART UNDERSTAND THE PROPERTIES OF VENUS S ATMOSPHERE DOWN TO THE SURFACE. NEAR/ON-SURFACE EXPLORATION REQUIRES HIGH TEMPERATURE SYSTEMS AND HIGH-TEMPERATURE SURVIVABILITY TECHNOLOGIES SUCH AS ELECTRONICS WILL ENABLE LONG-TERM IN SITU MISSIONS . THE VENUS EXPLORATION WORKING GROUP TECHNOLOGY PLAN SIMILARLY EMPHASIZES THAT DEVELOPMENT OF HIGH-TEMPERATURE ELECTRONICS SENSORS DESIGNED FOR OPERATING IN THE VENUS AMBIENT WOULD BE ENABLING FOR FUTURE MISSIONS . HOWEVER THE TECHNOLOGY FOR SUCH NEW FRONTIER EXPLORATION IS LIMITED AND MATURATION FOR FUTURE MISSIONS IS NEEDED. THIS PROPOSAL DIRECTLY ADDRESSES VISE S NEEDS FOR TECHNOLOGY OPERATIONAL FOR EXTENDED PERIODS AT THE SURFACE OF VENUS. THE DEVELOPMENT OF THE SIC ELECTRONICS AND THE DEMONSTRATION OF THE ELECTRONICS INTEGRATED WITH EXISTING HARSH ENVIRONMENTAL CHEMICAL SENSORS IN TERRESTRIAL SURROGATE ENVIRONMENTS WILL BRING THE TECHNOLOGY TO A HIGH MATURITY LEVEL.$130,299
· FY2020 · National Aeronautics and Space Administration
THIS PROJECT WILL DEVELOP SILICON CARBIDE (SIC) BASED ELECTRONICS CAPABLE OF OPERATION AT 500 DEGREES CELSIUS TO SUPPORT PREVIOUSLY DEMONSTRATED HIGH TEMPERATURE CHEMICAL SENSORS FOR USE IN HARSH ENVIRONMENTS SUCH AS VENUS SURFACE AND GAS GIANTS. THE VENUS CHEMICAL MICROSENSOR ARRAY (VCMA) WHICH HAS BEEN SEPARATELY DEVELOPED AND DEMONSTRATED UNDER A NASA PHASE II SBIR CONSISTS OF HIGHLY SELECTIVE SOLID STATE CHEMICAL MICROSENSORS (CO NO OCS SOX O2 H2O HF AND HCL) THAT CAN OPERATE AT AND ABOVE 500 DEGREES CELSIUS BUT RELIES ON SILICON-BASED SUPPORT ELECTRONICS LIMITED TO 125 DEGREES CELSIUS OPERATION. THE DEVELOPMENT OF SIC ELECTRONICS IS THE KEY TO ENABLE UNCOOLED LONG DURATION OPERATION AT THE SURFACE OF VENUS. WE WILL DESIGN AND FABRICATE APPLICATION SPECIFIC INTEGRATED CIRCUITS (ASICS) USING NASA DEMONSTRATED SIC TECHNOLOGY TO ENABLE LONG LIVED (100S OF DAYS) CHEMICAL SENSOR MEASUREMENTS ON VENUS SURFACE. THIS PROJECT WILL FOCUS ON THE DEVELOPMENT OF CORE SIC ELECTRONICS FOR AMPLIFICATION ANALOG CONTROL FEEDBACK AND ANALOG TO DIGITAL DATA CONVERSION REQUIRED FOR SENSOR OPERATION. DEVELOPMENT WILL BE BASED ON PREVIOUSLY DEMONSTRATED SIC COMPONENTS THAT HAVE NOT YET BEEN COMBINED INTO THE HIGH LEVEL INTEGRATED CIRCUITS NEEDED TO SUPPORT MANY TYPES OF INSTRUMENTS INCLUDING VCMA. MATURATION OF HIGH TEMPERATURE ELECTRONICS REDUCES RISK TO FUTURE INSTRUMENT DEVELOPMENT SUPPORTING OVERALL MISSION OBJECTIVES AND PROVIDING SCIENCE RELEVANT TO DECADAL AND VENUS EXPLORATION ANALYSIS GROUP (VEXAG) GOALS. MAKEL ENGINEERING INC. (MEI) WORKING ALONG WITH CO-PI S FROM NASA GRC AND NASA JPL WILL USE THE NASA GRC MICROFABRICATION FACILITIES FOR DEVELOPMENT OF THE SIC ELECTRONICS. MEI WILL PROVIDE THE EXPERTISE ON SPECIFIC CIRCUIT DESIGNS AND ASIC ARCHITECTURE FOR THE MICROSENSORS. NASA GRC WILL PROVIDE EXPERTISE ON CIRCUIT IMPLEMENTATION IN SIC AND DEVICE FABRICATION USING THE NASA GRC MICROSYSTEMS FABRICATION LABORATORY. DEMONSTRATION AND VALIDATION OF THE ELECTRONICS WILL BE CONDUCTED BY MEI AN JPL BY INCORPORATING THE SIC ELECTRONICS WITH THE VCMA INTO A SENSING PACKAGE FOR USE IN JPL S ONGOING TERRESTRIAL VOLCANIC TEST PROGRAM WHICH SERVES AS A HOT PLANETARY TESTBED. THE DECADAL SURVEY IDENTIFIES THE VENUS IN-SITU EXPLORER MISSION (VISE) FOR NEW FRONTIERS TO IN PART UNDERSTAND THE PROPERTIES OF VENUS S ATMOSPHERE DOWN TO THE SURFACE. NEAR/ON-SURFACE EXPLORATION REQUIRES HIGH TEMPERATURE SYSTEMS AND HIGH-TEMPERATURE SURVIVABILITY TECHNOLOGIES SUCH AS ELECTRONICS WILL ENABLE LONG-TERM IN SITU MISSIONS . THE VENUS EXPLORATION WORKING GROUP TECHNOLOGY PLAN SIMILARLY EMPHASIZES THAT DEVELOPMENT OF HIGH-TEMPERATURE ELECTRONICS SENSORS DESIGNED FOR OPERATING IN THE VENUS AMBIENT WOULD BE ENABLING FOR FUTURE MISSIONS . HOWEVER THE TECHNOLOGY FOR SUCH NEW FRONTIER EXPLORATION IS LIMITED AND MATURATION FOR FUTURE MISSIONS IS NEEDED. THIS PROPOSAL DIRECTLY ADDRESSES VISE S NEEDS FOR TECHNOLOGY OPERATIONAL FOR EXTENDED PERIODS AT THE SURFACE OF VENUS. THE DEVELOPMENT OF THE SIC ELECTRONICS AND THE DEMONSTRATION OF THE ELECTRONICS INTEGRATED WITH EXISTING HARSH ENVIRONMENTAL CHEMICAL SENSORS IN TERRESTRIAL SURROGATE ENVIRONMENTS WILL BRING THE TECHNOLOGY TO A HIGH MATURITY LEVEL.$14,052
· FY2017 · National Aeronautics and Space Administration