12.540 Principles of the global Positioning System Lecture 15 Prof. Thomas Herring 0409/03 12540Lec15 Propagation Medium: Neutral atmosphere Summary Basic structure of the atmosphere: Here we exclude the effects of electrons in the ionosphere(covered next lecture) Refractivity of constituents in the atmosphere Separation of atmospheric delay into "hydrostatic and wet components Elevation angle dependence Azimuthally symmetric mapping functions Gradient formulations Effects of atmospheric delays on position estimates 12540Lec15
04/09/03 12.540 Lec 15 1 12.540 Principles of the Global Positioning System Lecture 15 Prof. Thomas Herring Propagation Medium: Neutral atmosphere • Summary – Basic structure of the atmosphere: Here we exclude the effects of electrons in the ionosphere (covered next lecture). – Refractivity of constituents in the atmosphere – Separation of atmospheric delay into “hydrostatic” and wet components. – Elevation angle dependence: • Azimuthally symmetric mapping functions • Gradient formulations – Effects of atmospheric delays on position estimates 04/09/03 12.540 Lec 15 2 1
Basic atmospheric structure mosphere Troposphere is 2 100 where the temperature stops decreasing in the tmosphere(10 km altitude) 0409/03 12540Lec15 Troposphere Lots of examples of web-based documents about the mosphere: See for example Tropopause is where temperature stops decreasing Generally at pressure levels of about 300 mbar but can be as low as 500 mbar Sometimes term"tropospheric delay used but this only about 70%of delay Generally by height of 50-100km all of atmospheric delay accounted for Troposphere is where weather systems occur and aircraft fly on the tropopause 12540Lec15
04/09/03 12.540 Lec 15 3 Basic atmospheric structure Troposphere is where the temperature stops decreasing in the atmosphere. (~10 km altitude) 04/09/03 12.540 Lec 15 4 Troposphere • Lots of examples of web-based documents about the atmosphere: See for example. http://www-das.uwyo.edu/~geerts/cwx/notes/chap01/tropo.html • Tropopause is where temperature stops decreasing. Generally at pressure levels of about 300 mbar but can be as low as 500 mbar. • only about 70% of delay. • Generally by height of 50-100km all of atmospheric delay accounted for. • Troposphere is where weather systems occur and aircraft fly on the tropopause. Sometimes term “tropospheric delay” used but this is 2
Refractivity of air Air is made up of specific combination of gases, the most important ones being oxygen and nitrogen Each gas has its own refractive index that depends on re and temp For the main air constituents, the mixing ratio of the constituents is constant and so the refractivity of a packet of air at a specific pressure and temperature The one exception to this is water vapor which has a very variable mixing ratio Water vapor refractivity also depends on density/temperature due to dipole component 0409/03 12540Lec15 Refractivity of air The refractivity of moist air is given by N=k tk k1=77.60±0.05K/mbar k,=70.4±22 k2=(3.730±0.012)×105K2/mba For most constituents, refractivity depends on density (ie, number of air molecules ). Water vapor dipole terms depends on temperature as well as density 12540Lec15
Refractivity of air • Air is made up of specific combination of gases, the most important ones being oxygen and nitrogen. • Each gas has its own refractive index that depends on pressure and temperature. • For the main air constituents, the mixing ratio of the constituents is constant and so the refractivity of a packet of air at a specific pressure and temperature can be defined. • The one exception to this is water vapor which has a very variable mixing ratio. • Water vapor refractivity also depends on density/temperature due to dipole component. 04/09/03 12.540 Lec 15 5 04/09/03 12.540 Lec 15 6 Refractivity of air • The refractivity of moist air is given by: • For most constituents, refractivity depends on density (ie., number of air molecules). Water vapor dipole terms depends on temperature as well as density N = k1 Pd T Zd -1 Density of dry air + k2 Pw T Zd -1 Density of water vapor + k3 Pw T2 Zd -1 Dipole compoent of water vapor r/T k1 = 77.60 ± 0.05 k2 = 70.4 ± 2.2 k3 = (3.730 ± 0.012) ¥105 K2 123 123 123 K/mbar K/mbar /mbar 3
Refractivity in terms of density We can write the refractivity in terms of density R N=k k',=k,-kM、/M,=22.1±2.2 K/mbar Density p is the density of the air parcel including water vapor. R is universal gas constant, Md and M are molecular weights. Zw is compressibility(deviation from ideal gas law) See Davis, J L, T AHerring, and L. baseline vectors from VLBl, J Geophys. Res, 96, 643-650, 199of Shapiro, Effects of atmospheric modeling errors on determinatio 04/09/03 12540Lec15 Integration of Refractivity To model the atmospheric delay, we express the atmospheric delay as D=Jn(sd-∫dm(e)J2(m()-d-m(JN(2)×10 Where the atm path is along the curved propagation ath vac is straight path, z is height for station height Z and m(e) is a mapping function Extended later for non-azimuthally symmetric atmosphere) The final integral is referred to as the"zenith delay 12540Lec15
04/09/03 12.540 Lec 15 7 Refractivity in terms of density • We can write the refractivity in terms of density: • Density r is the density of the air parcel including water vapor. R is universal gas constant, Md and Mw w from ideal gas law) See Davis, J. L., T. A. Herring, and I.I. Shapiro, Effects of atmospheric modeling errors on determinations of baseline vectors from VLBI, N = k1 R Md r + k' 2 T + k3 T2 Ê Ë Á ˆ ¯ ˜PwZw -1 k' 2 = k2 - k1Mw /Md = 22.1± 2.2 K/mbar are molecular weights. Z is compressibility (deviation J. Geophys. Res., 96, 643–650, 1991. 04/09/03 12.540 Lec 15 8 Integration of Refractivity • To model the atmospheric delay, we express the atmospheric delay as: • Where the atm path; vac is straight vacuum path, z is height for station height Z and m(e) is a mapping function. (Extended later for non-azimuthally symmetric atmosphere) • D = n(s)ds - ds vac Ú atm Ú ª m(e) (n(z) -1)dz = Z • Ú m(e) N(z) ¥10-6 dz Z • Ú path is along the curved propagation The final integral is referred to as the ”zenith delay” 4
Zenith delay The zenith delay is determined by the integration of refractivity vertically The atmospheric is very close to hydrostatic equilibrium meaning that surface pressure is given by the vertical integration of density. Since the first term in refractivity depends only on density, its vertical integration will depend only on surface pressure. This integral is called the "zenith hydrostatic delay(zHD) Often referred to as "dry delay "but this is incorrect because has water vapor contribution 04/09/03 12540Lec15 Zenith hydrostatic delay The Zenith hydrostatic delay is given by ZHD=10k.8m Ps =0.00228 m/mbar Where gm is mean value of gravity in column of air (Davis et al. 1991) gm=98062(1000265c0s(2中)3.1×107(0.92+7300)ms2 Ps is total surface pressure(again water vapor contribution included Since Ps is 1013 mbar at mean sea level; typical ZHD =2. 3 meters 04903 12540Lec15
Zenith delay • The zenith delay is determined by the integration of refractivity vertically. • The atmospheric is very close to hydrostatic equilibrium meaning that surface pressure is given by the vertical integration of density. Since the first term in refractivity depends only on density, its vertical integration will depend only on surface pressure. This integral is called the “zenith hydrostatic delay (ZHD)”. (Often referred to as “dry delay” but this is incorrect because has water vapor contribution). 04/09/03 12.540 Lec 15 9 Zenith hydrostatic delay • The Zenith hydrostatic delay is given by: ZHD =10-6 k1 M R d gm -1 P ª 0.00228 m/mbar s • Where gm is mean value of gravity in column of air (Davis et al. 1991) gm=9.8062(1-0.00265cos(2f)-3.1x10-7(0.9Z+7300)) ms-2 • Ps is total surface pressure (again water vapor contribution included) • Since Ps is 1013 mbar at mean sea level; typical ZHD =2.3 meters 04/09/03 12.540 Lec 15 10 5
Zenith wet delay The water vapor delay second term in refractivity )is not so easily integrated because of distribution of water vapor with height Surface measurements of water vapor pressure (deduced from relative humidity) are not very effective because it can be dry at surface and moist above and vIsa versa Only effective method is to sense the whole column of water vapor. Can be done with water vapor radiometer (WVR) which infers water vapor delay from thermal emission from water vapor molecules and some laser profiling methods(LIDAR). Both methods are very expensive(200Ks per site) 0409/03 12540Lec15 Zenith wet delay In meteorology, the term" Precipitable water (PW)is used. This is the integral of water vapor density with height and equals the depth of water if all the water vapor precipitated as rain(amount measured on rain gauge) If the mean temperature of atmosphere is known Pw can be related to zenith wet Delay(zWD)(See next page) 04903 12540Lec15
Zenith wet delay • The water vapor delay (second term in refractivity) is not so easily integrated because of distribution of water vapor with height. • Surface measurements of water vapor pressure (deduced from relative humidity) are not very effective because it can be dry at surface and moist above and visa versa. • Only effective method is to sense the whole column of water vapor. Can be done with water vapor radiometer (WVR) which infers water vapor delay from thermal emission from water vapor molecules and some laser profiling methods (LIDAR). Both methods are very expensive (200K$ per site) 04/09/03 12.540 Lec 15 11 Zenith wet delay • In meteorology, the term “Precipitable water” (PW) is used. This is the integral of water vapor density with height and equals the depth of water if all the water vapor precipitated as rain (amount measured on rain gauge). • If the mean temperature of atmosphere is known, PW can be related to Zenith Wet Delay (ZWD) (See next page) 04/09/03 12.540 Lec 15 12 6
PW and zwd Relationship ZWD=10(2+k,/Tm)PW P/Tdz T ∫P./ridz The factor for conversion is -6.7 mm delay/mm PW This relationship is the basis of ground based GPS meteorology where gPs data are used to determine water vapor content of atmosphere ZWD is usually between 0-30cn 0409/03 12540Lec15 Mapping functions Zenith delays discussed so far; how to relate to measurements not at zenith Problem has been studied since 1970s In simplest form, for a plain atmosphere, elevation angle dependence would behave as 1/sin(elev).(At the horizon, elev=0 and this form goes to infinity For a spherically symmetric atmosphere, the 1/sin(elev) term is"tempered" by curvature effects Most complete form is"continued fraction representation"(Davis et aL., 1991) 04903 12540Lec15
04/09/03 12.540 Lec 15 13 PW and ZWD • Relationship: • The factor for conversion is ~6.7 mm delay/mm PW • This relationship is the basis of ground based GPS meteorology where GPS data are used to determine water vapor content of atmosphere. • ZWD is usually between 0-30cm. ZWD =10-6 R Mw (k' 2 +k3 /Tm )PW Tm = Pw Ú /Tdz Pw /T2 Ú dz Mapping functions • Zenith delays discussed so far; how to relate to measurements not at zenith • Problem has been studied since 1970’s. • In simplest form, for a plain atmosphere, elevation angle dependence would behave as 1/sin(elev). (At the horizon, elev=0 and this form goes to infinity. • For a spherically symmetric atmosphere, the 1/sin(elev) term is “tempered” by curvature effects. • Most complete form is “continued fraction representation” (Davis et al., 1991). 04/09/03 12.540 Lec 15 14 7
Continued fraction mapping function Basic form of mapping function was deduced by marini( 1972)and matches the behavior of the atmosphere at near zenith and lot elevation angles. Form is m(E)= sin(e)+ SIn(e)+ sin(e)+ sin(e)+ 0409/03 12540Lec15 Truncated version When the mapping function is truncated to the finite number of terms then the form is 1+ m(E)= I+c sin(e)+ sIn(e)+- b sin(e)+c when E=90: m(e)=1 Davis et al. 1991 solved problem by using tan for second sin argument 04903 12540Lec15
04/09/03 12.540 Lec 15 15 Continued fraction mapping function elevation angles. Form is: m(e) = 1 sin(e) + a sin(e) + b sin(e) + c sin(e) +L • Basic form of mapping function was deduced by Marini (1972) and matches the behavior of the atmosphere at near-zenith and low 04/09/03 12.540 Lec 15 16 Truncated version m(e) = 1+ a 1+ b 1+ c e) + a e) + b e) + c when e = 90; m(e) =1 Davis et al. 1991 solved problem by using tan for second sin argument. • When the mapping function is truncated to the finite number of terms then the form is: sin( sin( sin( 8
Mapping functions Basic problem with forming a mapping function is determining the coefficient a, b,c etc for specific weather conditions There are different parameterization Niell mapping function uses a, b, c that are latitude height and time of year dependent MTT(MIT Temperature)model uses temperature as proxy for atmospheric conditions Recent Niell work uses height of 500mbar surface (needs to be determined from assimilation models 0409/03 12540Lec15 Coefficients in mapping function The typical values for the coefficients are Hydrostatic a=1232e-3,b=316e-3;c=712e-3 Wet delay a=0.583e-3;b=1.402e3;c=45.85e3 Since coefficients are smaller for wet delay, this mapping function increases more rapidly at low elevation angles At0 degrees, hydrostatic mapping function is 36. Total delay -82 meter 12540Lec15
04/09/03 12.540 Lec 15 17 Mapping functions – height and time of year dependent – MTT (MIT Temperature) model uses temperature as proxy for atmospheric conditions. – 04/09/03 12.540 Lec 15 18 Coefficients in mapping function – a=1.232e-3, b=3.16e-3; c=71.2e-3 – a =0.583e-3; b=1.402e-3; c=45.85e-3 ~36. • Basic problem with forming a mapping function is determining the coefficient a,b, c etc for specific weather conditions. • There are different parameterizations: Niell mapping function uses a, b,c that are latitude, Recent Niell work uses height of 500mbar surface (needs to be determined from assimilation models). • The typical values for the coefficients are • Hydrostatic: • Wet delay • Since coefficients are smaller for wet delay, this mapping function increases more rapidly at low elevation angles. • At 0 degrees, hydrostatic mapping function is Total delay ~82 meter 9
Mapping functions The basic form of the continued fraction fit raytracing through radiosonde temperature pressure and humidity profiles to a few millimeters at 3deg elevation angle Basic problem is parameterizing a, b, c in terms of observable meteorological parameters Comparison on mapping functions http://gauss.gge.unb.ca/papers.pdf/igs97tropo.pdf 04/09/03 12540Lec15 Gradients In recent years; more emphasis put on deviation of tmospheric delays from azimuthal symmetry. S Chen, G. and T A Herring, Effects of atmospheric azimuthal asymmetry of the analysis of space geodetic data, J Geophys These effects are much smaller(usually <30mm)but do effect modern gPSmlbl measurements There is a mean ns gradient that is latitude dependent and probably due to equator to pole temperature grader Parameterized as cos(azimuth) and sin(azimuth)terms with a" tilted"atmosphere model (1/(sin(E)+0.032) 12540Lec15
Mapping functions • The basic form of the continued fraction fit raytracing through radiosonde temperature, pressure and humidity profiles to a few millimeters at 3deg elevation angle. • Basic problem is parameterizing a,b,c in terms of observable meteorological parameters. • Comparison on mapping functions: http://gauss.gge.unb.ca/papers.pdf/igs97tropo.pdf 04/09/03 12.540 Lec 15 19 Gradients • In recent years; more emphasis put on deviation of atmospheric delays from azimuthal symmetry. See: Chen, G. and T. A. Herring, Effects of atmospheric azimuthal asymmetry of the analysis of space geodetic data, J. Geophys. Res., 102, 20,489–20,502, 1997. • These effects are much smaller (usually <30mm) but do effect modern GPS/VLBI measurements. • There is a mean NS gradient that is latitude dependent and probably due to equator to pole temperature gradient. • Parameterized as cos(azimuth) and sin(azimuth) terms with a “tilted” atmosphere model (1/(sin(e)+0.032) 04/09/03 12.540 Lec 15 20 10