climate monitoring with radio occultation data systematic error sources c. rocken, s. sokolovskiy,...
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Climate Monitoring with Radio Occultation Data
Systematic Error Sources
C. Rocken, S. Sokolovskiy, B. Schreiner, D. Hunt,
B. Ho, B. Kuo, U. Foelsche
Purpose of this Presentation
• Identify potential sources of error that may affect the RO climate record
• We distinguish between two Error types– (1) Observational Errors
• Errors in RO phase observation• Errors in RO atmospheric excess phase
– (2) Inversion Errors• Errors in RO inversion products: bending, refractivity,
geopotential height, pressure temperature humidity profiles
QuickTime™ and a decompressor
are needed to see this picture.
Radio Occultation
RO Steps
(1) Observation
(2) Excess Phase Computation - determine the signal delay caused by the atmosphere compared to a vacuum signal
(3) Process the Excess Phase to determine atmospheric profiles (bending, refractivity, geopotential height, pressure temperature humidity)
Simplified GPS Observation Principle
• GPS satellites transmit two carriers (L1 & L2)• GPS receivers generate internal replicas of
the L1 and L2 carriers• The phase of the beat frequency between the
doppler-shifted incoming signal and the signal replica is measured for L1 and L2. This is the phase observation based on which all subsequent analysis is based.
• Amplitude ignored - no influence on RO climate
The GPS Observation Equation
From Phase to Bending
Bending is computed from Excess Doppler
Because Doppler is the time derivative of “Excess Phase” RO occultation is insensitive to constant errors in “Excess Phase”
Phase Observations
Excess Phase Observations
Doppler Bending Angle
We are insensitive to position errors & time errors etc. that remain constant during the occultation
We are sensitive to velocity, clock frequency, and other errors that change during the 2-minute occultation
From Phase to Excess Phase
RO phase observation
RO excess phase observation
IGS Clock Estimation Network
Hydrogen masers (57) are indicated in brown, cesiums (32) in green, and rubidiums (30) in blue. Stars indicate clocks at BIPM timing laboratories (includes,standard labs at NIST, Paris, Braunschweig, ….)
The quality of the clocks in this GPS tracking network (some as good as 1e-15 sec/sec or 0.0003 mm/sec) ensures time and frequency synchronization of the GPS satellite clocks.
Eliminating Clock Errors• Double Difference
– Advantage: Station clock errors removed, satellite clock errors mostly removed (differential light time creates different transmit times), general and special relativistic effects mostly removed
– Problem: Fid. site MP, atmos.
noise, thermal noise
• Single Difference
– LEO clock errors removed
– use solved-for GPS clocks
– Main advantage: Minimizes
double difference errors
QuickTime™ and aTIFF (LZW) decompressor
are needed to see this picture.
From Phase to Excess Phase
RO phase observation
RO excess phase observation
Multipath Reflection from COSMIC Solar panel
0.05 0.15 0.25 0.35 0.45 0.55 0.65 0.75 0.85 0.950.5
2
3.5
50
0.5
1
1.5
2
2.5
Velocity Error [mm / sec]
Reflection Coefficient
Spacecraft Size [m]
Multipath-induced Velocity Error
2-2.51.5-21-1.50.5-10-0.5
Multipath - Induced Equivalent Excess Doppler Error
Multipath can be a significant and systematic error source
Can be larger than 2 mm /sec for large satellites For COSMIC it is smaller than 0.05 mm / sec
COSMIC MPeffect
From Phase to Excess Phase
RO phase observation
RO excess phase observation
Orbit Determination•LEO satellite orbits can be determined to < 10 cm rms
•Velocity error due to LEO POD < 0.03 mm/ sec
•COSMIC is affected by additional attitude error
•This POD/attitude error is NOT systematic
•Systematic velocity error due to GPS POD is negligible
…. except
• Error due to surveying occultation antenna relative to satellite center of mass or due to systematic attitude error: 1 cm radial error gives 0.01 mm/sec velocity error - thus this error is minimized by using small satellites (i.e for COSMIC < 0.01 mm/sec)
From Phase to Excess Phase
RO phase observation
RO excess phase observation
Summary Excess Phase
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LrS = ρ trp + ρ ion + εnoise + εsystematic[ ]
Systematic errors affecting the excess phase Doppler are:
Multipath error: < 0.05 mm/sec (good small satellite design needed but no attempt is made to correct for this error )
Orbit determination error: < 0.01 mm / sec (with reasonable survey of GPS antenna placements and antenna specification)
These errors are spacecraft / mission dependent
€
∂LrS
∂t
Impact of Systematic Observation Errors on RO Refractivity
A systematic obs. error of 0.05 mm/sec results in a systematic refractivity error of 0.01% and a temperature error of 0.06 degK at 25 km and decreases exponentially towards the surface.
Processing of real GPS RO signals includes several steps.Lay-out of inversion of GPS RO signals at Cosmic Data Analysis and
Archive Center (CDAAC)
Processing of real GPS RO signals includes a number of steps.Lay-out of inversion of GPS RO signals at Cosmic Data Analysis and
Archive Center (CDAAC)
Processing of real GPS RO signals includes a number of steps.Lay-out of inversion of GPS RO signals at Cosmic Data Analysis and
Archive Center (CDAAC)
Processing of real GPS RO signals includes a number of steps.Lay-out of inversion of GPS RO signals at Cosmic Data Analysis and
Archive Center (CDAAC)
Processing of real GPS RO signals includes a number of steps.Lay-out of inversion of GPS RO signals at Cosmic Data Analysis and
Archive Center (CDAAC)This processing step assumes spherical symmetry in refractivity.
A systematic error may be introduced because “surfaces of equal refractivity” will, on average, have a slight angle relative to surfaces of equal gravitational potential.
The size of this error is not known - but believed to be (a) small (b) nearly constant in time. Needs to be quantified.
Processing of real GPS RO signals includes a number of steps.Lay-out of inversion of GPS RO signals at Cosmic Data Analysis and
Archive Center (CDAAC)
This processing step assumes spherical symmetry in refractivity.
Important error source in the lower troposphere (below 5km height).
The bias / long term change of this error is not known.
This error is still under investigation.
Processing of real GPS RO signals includes a number of steps.Lay-out of inversion of GPS RO signals at Cosmic Data Analysis and
Archive Center (CDAAC)
Processing of real GPS RO signals includes a number of steps.Lay-out of inversion of GPS RO signals at Cosmic Data Analysis and
Archive Center (CDAAC)
Ionospheric CalibrationWe estimate systematic ionospheric error by computing the “mean of the iono-free bending angle minus neutral bending angle (from climatology) in the 60-80 km height bin”.
We compare this quantity “smean” for daytime vs. nighttime soundings.
COSMIC Days 0-120, 2007
-20 < Lat. < 20
DAY (11<LT<15) smean= -1.19 e-7 rad
NIGHT (2<LT<6) smean=-0.37e-7 rad
Because we can see the day vs. night iono bias change we expect that we can monitor the change of this bias to better than 0.5e-7 rad during the 11-year solar cycle.
Climate change effect on Temperature and Bending Angles
Temperature change due to 2xCO2Bending Angle change
due to 2xCO2
•Bending angle signal over 80 years (from model) is ~ 7e-5 rad
•Bending angle iono. bias can be calibrated to better than 5e-8 rad
•Thus the ratio of climate signal to measurement bias is almost 1000 !
Processing of real GPS RO signals includes a number of steps.Lay-out of inversion of GPS RO signals at Cosmic Data Analysis and
Archive Center (CDAAC)
Statistical Optimization
Error in climatology introduces errors in temperature profile at greater altitude. This error depends on (a) climatology and (b) noise level of data. “Small” below 30 km.
Processing of real GPS RO signals includes a number of steps.Lay-out of inversion of GPS RO signals at Cosmic Data Analysis and
Archive Center (CDAAC)
Systematic lower troposphere errors could be large due to horizontal refractivity gradients, tracking errors, super refraction - their change in time is not well understood.
Refractivity in the lowest 5 km may have systematic errors that are not yet well defined.
Processing of real GPS RO signals includes a number of steps.Lay-out of inversion of GPS RO signals at Cosmic Data Analysis and
Archive Center (CDAAC)
Integration of hydrostat. eqn. starts at 150km assuming P=T=0. Above water vapor no new systematic errors introduced.
Water vapor retrieval requires additional external information. This can introduce an additional systematic error.
Summary• Observational systematic error is < 0.05 mm/sec
– At 25 km this corresponds to a refractivity / temperature error of 0.01 % / 0.06 degK
– This error is mission dependent. Caused by multipath and antenna position error. To minimize this error: use micro satellites for climate missions!
• The main inversion errors are:– Ionosphere bias can be monitored better than 5e-8 rad corresponding to ~0.1
mm/sec (0.02 % / 0.12 degK at 25 km)– These errors decrease exponentially towards the surface– Method of initialization of bending angle can have significant impact on
these numbers - will be discussed in next talk
• For climates studies we can quantify errors of raw BA: 40 to ~5 km, N: 20 to ~5 km, T: 20 to 5-10 km height range
Is there an error in the ionospheric calibration?
Idea:
Looks at “raw ionosphere - free” bending angle at ~65-70 km and see if:
a) Is bending angle “~0” as it should be?
b) Is there a difference between local time noon and night time bending angles?
CHAMP RO Data LT Sampling for 30S-30N in 2004
Difference between day and night bending angles for CHAMP at ~ 65 km height in 2004 is less than 1-e7 radians
This is small - but study is preliminary and needs to be repeated as we approach solar max.
Orbits
A velocity bias could be caused by:
1) Scale error in the reference frame - future changes in reference frame will be smaller than 1 ppb - (0.03 - 0.1 mm/sec )
2) Center of Mass systematic error (10 cm radial error will produce a velocity error 0.11 mm/sec at 500 km according to Mannucci et al. ‘06)
3) Other … ????
If we would not correct for this pattern 0.01 - 0.03 mm/sec effect.
Small!
Phase Pattern Effect
Previous error analysis
…. for climate studies we need to separate systematic and random error components
Kursinski et al, 1997
Double/Single-Difference Processing Description
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L1ab (tr ) = ρ a
b (tr ) + c ⋅δta (tr ) −δta,rel (tr ) − c ⋅δt b (tr −τ ab ) +δtrel ,1
b (tr −τ ab ) +δρ a,ion
b (tr ) +δρ a,tropb (tr ) +δρ a,rel ,2
b (tr )
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L3ac (tr ) = ρ a
c (tr ) + c ⋅δta (tr ) −δta,rel (tr ) − c ⋅δt c (tr −τ ac ) +δtrel ,1
c (tr −τ ac ) +δρ a,rel ,2
c (tr )
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L3dc (tr ) = ρ d
c (tr ) + c ⋅δtd (tr ) −δtd ,rel (tr ) − c ⋅δt c (tr −τ dc ) +δtrel ,1
c (tr −τ dc ) +δρ d ,rel ,2
c (tr ) +δρ d ,tropc (tr )
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L3db (tr ) = ρ d
b (tr ) + c ⋅δtd (tr ) −δtd ,rel (tr ) − c ⋅δt b (tr −τ db ) +δtrel ,1
b (tr −τ db ) +δρ d ,rel ,2
b (tr ) +δρ d ,tropb (tr )
Neglecting ambiguities, multipath, and thermal noise, the observed occulting-link L1 phase path and the non-occulting L3 (ionosphere-free) phase paths can be written as
where and are the combined oscillator effects of general and special relativity at the ground station (constant) and LEO receiver, respectively, and is the geometric distance and is the signal travel time. The desired L1 excess phase path is shown in GREEN, and quantities computed from previous POD and ZTD estimates are shown in BLUE.
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δta,rel (tr )
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δtd ,rel (tr )
Forming the Double-Difference and subtracting known quantities leaves the desired excess phase path and an error term of small magnitude due to incomplete cancellation of the GPS satellite clocks because each observation has a slightly different signal transmission time.
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ρ
€
τ
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ΔΔL1ab =δρ a,ion
b (tr ) +δρ a,tropb (tr ) − c ⋅(δt b (tr −τ a
b ) −δt b (tr −τ db )) + c ⋅(δt c (tr −τ a
c ) −δt c (tr −τ dc ))
Forming the Single-Difference and subtracting known quantities, including the GPS solved-for clocks at transmit time leaves the desired excess phase. The GPS clocks are not solved for perfectly and contribute some residual errors.
€
ΔL1ab = δρ a,ion
b (tr )+δρ a,tropb (tr )
Effects of CO2 increase on climate change simulated by NCAR Climate System Model
(CSM)
Vertical cross sections of zonally-averaged model temperature changes averaged over 20 years (years 60- 79) in NCAR Climate System Model in which carbon dioxide alone is increased by 1% per year (Meehl et al., 1998).
Climate Change and Geopotential Heights
Effect of 2xCO2 on Temperature and GPH
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