Snow blankets 30% of Earth's land surface (60% of northern hemisphere land) in midwinter, dramatically changing our planet's land surface and affecting our weather for months. Seasonal snow is critically important to society for the management of water resources, natural hazards, water security, and in many economic sectors. The only practical way to estimate the quantity of snow on a global scale is through satellites. Despite 4 decades of satellite observations, the highly variable nature of snow still presents significant challenges toward achieving this goal. For example, current space-based techniques underestimate snow water equivalent (SWE) by as much as 50%, and model-based estimates can differ greatly versus estimates based on remotely-sensed observations. Snow community consensus is that a multi-sensor approach is needed to adequately address global snow, combined with modeling and data assimilation to fill the gaps in space and time. What remains, then, is how best to combine and use the various sensors under different types of snow conditions and confounding factors. NASA's multi-year SnowEx airborne campaign is designed to collect measurements needed to enable algorithm development and to guide those mission trade studies. Year 1 (2017) focused on the distribution of snow-water equivalent (SWE) and the snow energy balance in a forested environment. This paper will discuss the various remote sensing options for snow, the challenging factors, and describe the recently-completed first year of SnowEx in Colorado, USA. Ground-based remote sensing and in situ data collection involved nearly 100 participants over three weeks. The airborne campaign included nine sensors on five aircraft. We will conclude by discussing options for a future snow satellite mission

Gatebe, Charles K.

Hall, Dorothy K.

Kang, Do Hyuk

Kim, Edward J.

NASA Technical Reports Server

NASA’S SNOWEX CAMPAIGN AND 
MEASURING GLOBAL SNOW FROM SPACE 
Supported by the Terrestrial Hydrology Program
Edward Kim, Charles Gatebe, Dorothy Hall, Do Hyuk Kang
NASA Goddard Space Flight Center
https://ntrs.nasa.gov/search.jsp?R=20180005187 2019-08-31T14:43:36+00:00Z
Outline
• Importance of snow
• Overarching SnowEx/snow science questions
• Global snow measurement options
• Why SnowEx?
• SnowEx Year 1
• What’s next?
• A global snow mission
• Summary
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NASA HQ 3
Why is seasonal snow important
scientifically?
• Largest areal extent of any component of the cryosphere.  
• Over 60% of the northern hemisphere land surface (30% of Earth’s 
total land surface) has snow cover in midwinter.  
• Plays a strong role in Earth’s Water, Energy, & Carbon Cycles
• Important storage element of the Water Cycle
• Dramatically changes land surface thermal regime & atmospheric 
boundary conditions for months
• Changes planetary albedo for months
• A major survival factor for flora and fauna
• Spatial scales are global & regional
• Temporal scales are seasonal to decadal to even longer
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Four major societal impacts: 
1. water resources
2. natural hazards
3. water security
4. weather/climate
These societal impacts express themselves at 
spatial scales that are local, regional, & global.
The temporal scales are often shorter than for  
science.
Why is seasonal snow important
societally?
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WANTED: Snow Water Equivalent
Snow Water Equivalent (SWE)
– melted height of a column 
of snow over a unit area
SWE = snow depth x density
– Can sense SWE directly, or
– Sense depth and estimate 
density to get SWE
Snow Covered Area (SCA)
– Binary snow mask
– Accurate products already 
exist
snow
Liquid
water
• Improving global SWE estimates is 
the main goal of a snow mission
• Some global SWE products already 
exist, but large uncertainties 
remain due to its inherently-
variable nature, and confounding 
factors like forests & terrain
• SWE is consistently identified as a 
key variable needing improvement 
in an integrated global 
measurement system, which is the 
top priority of the Decadal Survey 
Water Panel
• How does SnowEx help?
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SnowEx Guiding Questions
• Overarching SnowEx/Snow Science Questions: 
How much water is stored in Earth's terrestrial snow-covered 
regions? And how & why is it changing?
• SnowEx Year 1 Fundamental Questions
– Q1 – What is the distribution of snow-water equivalent 
(SWE), and the snow energy balance, in different canopy 
types and densities, and terrain?
– Q2 – What is the sensitivity and accuracy of different SWE 
sensing techniques for different canopy types, canopy 
density, and terrain?
• Thus, SnowEx Year 1’s focus was snow in forested areas
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The Forest Snow Issue
Half the snow covered world is forested & measuring snow in forests is challenging.
A snow mission concept has to consider sensing snow in forests.
Forest
cover
Snow 
& ice
cover
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So far, lidar is the only technique proven to see through forests.
• Many sensing techniques are sensitive to snow variables
– SWE: passive microwave, SAR, InSAR, active-passive microwave
– Snow depth: lidar, passive microwave, InSAR, Structure-from-Motion
– SCA: VIS/IR, passive microwave, multispectral, hyperspectral
– Albedo: VIS/IR, multispectral, hyperspectral
• Each has strengths and issues when faced with the challenges of snow sensing
– Forests & vegetation
– Wet snow
– Complex terrain
– Deep snow & shallow snow
– Layering inside snowpacks
– Clouds, atmospheric propagation
– Needing density to convert depth to SWE
– Dirty snow
– Retrievals that need ancillary data on snow grain size, soil moisture, soil roughness, etc
Sensing Techniques for Global Snow
No single sensing technique works across all types of snow and confounding factors
Detailed list in backup
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Why SnowEx? and what we need from it
• Therefore, a global snow 
mission requires a multi-sensor 
approach
• Trade studies will be key to 
evaluate potential concepts
• The trade studies require 
multi-sensor field data 
(airborne + ground): SnowEx 
will provide
• The trade space should span 
the sensors, snow types, & 
confounding factors
• SnowEx Year 1 focused on one 
confounding factor: forests Forest density
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SnowEx Year 1 Expected Outcome 
Sensor B
Sensor A
Sensor A+B
SnowEx is how we obtain input data for mission concept trade studies
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Airborne
Remote Sensing
SnowEx Year 1 Location
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SnowEx year 1
Location:
Colorado, USA
Primary site: Grand Mesa, CO
Black rectangle:
9 x 32 km airborne
observation box
Green = forest
Increasing to the East
(SWE also increases)
EAST
Areas of
main ground truth
Grand Mesa was an ideal site for the forest objectives of Year 1
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CORE SENSORS
• SnowSAR:  X & Ku-band radar (ESA)
• CAR: BRDF & multispectral imager  (GSFC)
• AESMIR (passive mw, from GSFC) 18 & 36 GHz (did not fly)
• Thermal IR/video suite
• Imager (GSFC)
• High-accuracy non-imaging (KT.15, from U.Washington)
• Video camera (GSFC)
• ASO suite (JPL)
• Lidar
• Hyperspectral imager
EXPERIMENTAL ALGORITHMS
• UAVSAR: L-band InSAR (JPL)
• GLISTIN-A: Ka-band InSAR (JPL)
Prototype sensor
• WISM: active & passive microwave (Harris Corp IIP)
Year 1 Airborne Sensors & Aircraft
NRL P-3  (6)
King Air (5)
Two NASA G-IIIs (4,3) 
Twin Otter (3)
Aircraft
(flight days)
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SnowSAR (X/Ku SAR)
• Core sensor: dual frequency SAR      
(X & Ku bands)
• Developed by ESA for CoReH20 
effort; Operated by MetaSensing
• Multiple campaigns on different 
aircraft between 2011-2014
• First time installation on a P-3
• Best data set on 21st Feb
• Processing/calibration ongoing
• Pros: volume scattering retrieval, 
sensitive to SWE & melt, high res, 
topography OK, sees through 
clouds, no sun needed
• Questions: accuracy, saturation, 
wet snow, forest, vegetation, soil
X-band
Ku-band
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• Thermal IR Sensor Suite (IRSS) 
consists of two instruments 
and a camera
– QWIP infrared imager (GSFC)
– KT-15 infrared thermometer 
(U. Washington)
– HD visual video camera
• IRSS Instruments were cross-
calibrated with ground team 
field IR targets before 
deployment
• IRSS Instruments calibrated 
with handheld target 
before/after each flight 
Thermal IR Sensor Suite
Example QWIP thermal IR image showing 
trees ~same temperature as snow in clearings 
[significant snow is intercepted by trees].
Shadow areas are much colder.
These data are critical for energy balance 
modeling studies.
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ASO
Senator Beck Feb 8, 2017
DSM
Lidar
• Core sensor for SnowEx Year 1
• Fills spatial gaps in ground truth
• Airborne Snow Observatory (JPL)
• COTS sensor; mature installation
• Pros: high res, topography OK, 
wet snow OK, good forest 
penetration, wide swath 
(airborne), no sun needed, 
altimetry portion TRL 9
• Questions: requires density to 
get SWE (not TRL 9), snow depth 
resolution only ok for deep snow, 
clouds, swath width for 
spaceborne
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GLISTIN-A (Ka-band InSAR)
• Experimental technique
• Measures snow depth via 
InSAR altimetry
• Single-pass InSAR
• Pros: less cloud impact vs 
lidar, wet snow ok, 
topography OK
• Questions: penetration into 
snow, depth resolution, 
requires density to get SWE, 
accuracy, forest, vegetation, 
atmospheric correction, 
revisit timer, swath width, 
SWOT?
Grand
Mesa
Scale in meters
Depth change Feb 20-21
2/26/18 NASA HQ 17
UAVSAR (L-band InSAR)
• Experimental technique
• Measures SWE via phase 
change
• repeat-pass InSAR
• Pros: little/no cloud impact; 
directly senses SWE, 
topography OK, sunlight 
not required
• Questions: accuracy, SWE 
range & precision, forest, 
vegetation, swath width, 
coherence & repeat 
interval, wet snow
2/26/18 NASA HQ 18
Ground Truth
Ground Truth-the measurements
Additional measurements:
Snow penetrometer
Spectral reflectance
Snow casts
Soil bulk density
Veg biomass
Veg structure photos
Precip (solid + liquid)
(not a complete list)
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Ground Truth
165
Transects
~ 16,500 depth 
measurements
154 snow pits
~4500 density 
measurements
Snowpack
internal 
layers
Unusually deep snow by Feb
And very warm  wet
Wet layers
impact 
sensing 
techniques
3 weeks
40-50 people/wk
~100 people total
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Ground Truth & Community Building
Mandatory safety training
Time lapse cameras
Community
Training
trench
Typical
snow pit
Community building
was a major component
of Year 1
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Ground Based
Remote Sensing
(GBRS)
Key part of Year 1 experiment design
• Similar sensors as on aircraft
• Other complementary sensors 
• more bands, different geometry, time series
• Enhanced ground truth
• Opportunities to test prototypes
Ground-base remote sensors on…
A boom truck
(U.Michigan)
Sled towed 
by 
snowmobile
(U. de 
Sherbrooke)
A scissors lift
Canadian
Ground-based radar
(U.Waterloo)
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GBRS Example: Terrestrial Lidar Systems
Scans in September and February
4.72 m
1.53 m 1.08 m
• High Res snow depth for ground truth and to answer process questions
• High Res geometry data to understand how remote sensing works in forests
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Engaging the Snow Community
The offer: 
folks who could 
commit a week of 
time were welcome 
to participate.
The response:
40-50 people 
x 3 weeks; total
100 participants
(13 international)
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Modeling
& 
Analysis
Role of Models in a Snow Mission
• Year 1 was designed to 
enable modeling & analysis 
• Different combinations of 
sensors & models are 
available for 
• Example: all high-res sensors 
have gaps between swaths
• Sensors-of-opportunity will 
come and go over the years
• Models are needed to fill 
gaps in space & time Forest density
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Snow Mission Tradespace Example
Sensor A+C
+ Model 1
Sensor A+B
+ Model 1
Again, trade studies will be key to evaluate potential combinations of observations + models.
An international combination of sensors will be essential to a global snow mission.
Sensor A+B
+ Model 2
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Key Trade Study Models/Tools
• OSSE (Observing System 
Simulation Experiment)
– Computer model to test 
different mission design 
concepts, and to 
estimate their 
performance
– Provides a consistent 
evaluation tool
• A trade study effort is 
underway using NASA 
Goddard’s LIS land 
model + other tools
• Functional components:
– “truth data” of snow
– Land surface model(s) 
including snowpack
– Sensor physics models
– Satellite orbit models
– Forward radiance 
models
– SWE, depth, density, & 
SCA algorithms 
(assimilation, direct 
inversion, etc)
– Evaluation tools
2/26/18 NASA HQ 29
Future Snow-related Missions
• IceSat2 (NASA)
– Global lidar, Polar orbit
• GEDI (NASA)
– Lidar to fly on Int’l Space Station
• WCOM (China)
– Designed for snow & soil moisture
– active & passive microwave sensors
• EE10 snow proposal (ESA)
– Dual-freq SAR (13, 17 GHz)
– Active-passive retrieval w/Metop
2/26/18 NASA HQ 30
Thoughts on a global snow mission
• Global SWE products already exist, but uncertainty is high in many 
regions, & current sensor mix is limited 
• A broader suite of multiple sensors are required for global snow
• High resolution is desirable in some areas
– Options: SAR & lidar, both have important limitations
– Lidar is so far the only technique that sees through forests
• In addition, leverage existing/planned sensors
– Passive VIS/IR from MODIS/VIIRS (for albedo)
• Cannot afford it all; international partnerships are required
– Passive microwave from Japan’s AMSR2/3, China’s WCOM; Europe’s METOP-
SG MWI; scatterometers from WCOM; SAR from Europe’s Sentinel/Copernicus
• Fill gaps in space & time with models
• Already-planned international missions plus launching 1 or 2 key 
missing sensors could give us a global multi-sensor snow mission 
2/26/18 NASA HQ 31
Summary
• Snow has enormous scientific and societal impacts 
• The multi-sensor + model approach needed for a global snow 
mission requires careful trade studies
• The SnowEx campaigns are how we will collect data for those trade 
studies
• SnowEx Year 1 began this using forests to challenge multiple 
sensing techniques
– 5 aircraft flew 9 sensors, plus 100 participants collected ground truth and 
>35 GBRS activities collected data at 2 sites in Colorado in February 2017
– A unique legacy dataset was collected
• Future years of SnowEx will target science & mission concept gaps
• A global snow mission tradespace framework is being used to 
evaluate concept with different sensor + model combinations
• International partnerships will be essential for a snow mission
2/26/18 NASA HQ 32
Resources
snow.nasa.gov
• NASA Terrestrial Hydrology Program Manager
– Dr. Jared Entin, Jared.K.Entin@nasa.gov
• SnowEx year 1 organizing team contacts
– Dr. Edward Kim, ed.kim@nasa.gov
– Dr. Charles Gatebe, charles.k.gatebe@nasa.gov
– Dr. Do-Hyuk Kang, dk.kang@nasa.gov
• THP Snow Program Office Lead
– Dr. Dorothy Hall, dorothy.k.hall@nasa.gov
• Int’l Snow Remote Sensing Working Group (ISWGR)
– http://nasasnowremotesensing.gi.alaska.edu/
2/26/18 NASA HQ 33
BACKUP
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Sensing Techniques for Global Snow
Strengths:
• Lidar (altimetry): snow depth (can get SWE with density), precision OK for moderate to deep 
snow, very high res, forests OK, topography OK, wet snow  OK, altimetry is TRL9 from space
• Ku-band SAR (volume scattering): senses SWE & melt, high res, topography OK, clouds OK, no 
sun needed
• L-band InSAR (phase change): senses SWE & melt, high res, topography OK, clouds OK, no 
sun needed, little atmospheric correction
• Ka-band InSAR (altimetry): senses depth (can get SWE with density), high res, topography OK, 
no sun needed, wet snow  OK
• Passive microwave: senses SWE & melt, global daily coverage exists, clouds OK, no sun 
needed, very long record, TRL9 from space
• Multispectral: MODIS/VIIRS products exist, fSCA, albedo, grain size, moderate spatial res
• Hyperspectral: fSCA, albedo, surf grain size, mod/high spatial res
• Structure-from-Motion: extremely high res, multiple commercial satellites exist, moderate 
TRL
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Issues:
• Lidar (altimetry): clouds, depth precision not good for shallow snow, swath width (coverage), 
accuracy of density estimate to get SWE (not TRL 9), forests
• Ku-band SAR (volume scattering): algorithm maturity, coverage, saturation?, forests, needs 
ancillary data on soil, may need active-passive joint constraints, wet snow
• L-band InSAR (phase change): algorithm maturity, coverage, SWE range & precision, forest, 
vegetation, swath width, coherence & repeat interval, wet snow
• Ka-band InSAR (altimetry): algorithm maturity, coverage, atmospheric correction, penetration 
into snow, requires density to get SWE, accuracy, forest, vegetation, atmospheric correction, 
revisit time, swath width, SWOT?
• Passive microwave : resolution, saturation, forests, topography, future satellite gap
• Multispectral: needs sun, clouds, forests, surface only, moderate res
• Hyperspectral: needs sun, clouds, forests, surface only
• Structure-from-Motion: coverage, clouds, needs sun
Sensing Techniques for Global Snow
2/26/18 NASA HQ 36


NASA's SnowEx Campaign and Measuring Global Snow from Space

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