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NOISE FILTERING AND AIR POLLUTION MODELING AND FORECASTING
Eugene Genikhovich Voeikov Main Geophysical ObservatorySt. Petersburg
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CONTENT Introduction; Stochastic components influencing
dispersion of pollutants; Majorant approach in dispersion
modeling and its application in Russian regulatory guidelines;
Statistical forecast of daily extremes of concentrations;
Conclusion
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MAJOR FACTORS INFLUENCING URBAN AIR POLLUTION /1
Urban sources of emission, temporal and spatial variation of their characteristics
Urban vehicular and industrial emissions
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MAJOR FACTORS INFLUENCING URBAN AIR POLLUTION /2
Meteorological and synoptic conditionsMidday surface pressure and air temperature fields corresponding to the highest ozone concentrations in St. Petersburg in 2002, July 31 (weather map downloaded from the Köln University site)
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MAJOR FACTORS INFLUENCING URBAN AIR POLLUTION /3
Structure of the urban canopy, location, shape and size of buildings, roads etc
Marc Chagall
"Above the city"
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URBAN AIR POLLUTION FORECASTS -- WHAT FOR? To warn people about possible high-
pollution episodes in the city; To provide information for policy- and
decision-makers in order to implement emission-control measures, like emission reduction at stationary sources, limitations imposed on traffic intensity and pattern etc, resulting in reduction of peak concentrations
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PROBLEMS WITH PREDICTION OF URBAN AIR POLLUTION Emission parameters and their temporal and
spatial variability are not known well; Fields of mean and turbulent characteristics
of the wind flow transporting pollutants are non-uniform and have sharp gradients;
Concentration fields are highly irregular in space and time;
Concentrations are excessively noisy (include intensive stochastic component);
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Stochastic component in atmospheric processes limiting precision of dispersion models and forecasts (1)
Plume meanderingF. Gifford (1958):
Probability density of fluctuations of centerline concentrations due to the plume meandering:
,)2
(2
)(20
2
2
2
2
2
lmIe
elp
l
m
UacQalR
2
112;)/ln(
RRCym /5.0;)2/( 222
where
,)2
(2
)(20
2
2
2
2
2
lmIe
elp
l
m
UacQalR
2
112;)/ln(
RRCym /5.0;)2/( 222
where
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AXIAL GLCs, KINCAIDx = 10 km; 1.5< u10<2.7; -10.6< L<-3.2
y = 0.5867x + 0.684
-1.5-1
-0.50
0.51
1.52
-3 -2 -1 0 1
ln C
erf-1
Stochastic component in atmospheric processes limiting precision of dispersion models and forecasts (2)
The straight line corresponds to the best lognormal fit
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Deterministic models can predict non-stochastic characteristics (conditional statistics) of atmospheric properties (e.g., math expectations, percentiles, PDFs, ensembles and so on);
Comparison of predictions of a deterministic model with stochastic measurements results in errors that cannot be eliminated by any improvements and tuning of the model;
Error of prediction at the plume axis is about 100% and at the fixed space/time point is of the order of 1000%.
Mean square stochastic error in the axial GLC
for a "perfect" dispersion model for a
single point source (Genikhovich, 2003)
0
0.5
1
1.5
2
2.5
0 0.2 0.4 0.6 0.8 1 1.2 1.4
S
Err
Stochastic component in atmospheric processes limiting precision of dispersion models and forecasts (3)
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FILTERING THE NOISE WITH THE USE OF EXTREMES AND UPPER PERCENTILES OF CONCENTRATIONS
Statistically stable characteristics; Described with the universal double
exponential distribution exp(-exp(-a(x-u)));
As a result, determined by just two parameters, "a" and "u" – easier to model and predict.
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TWO MAIN APPROACHES TO AIR POLLUTION FORECASTING
Deterministic forecast Based on general
physical principles and semi-empirical parameterizations;
Very sensitive to errors in emission- and meteorological data;
Cannot not reproduce the stochastic component of air pollution;
Needs monitoring data only for validation purposes;
Statistical forecast Based on empirical
relationships between characteristics of the air pollution ("predictants") and governing parameters ("predictors");
Doesn't make use of emission data;
In principle, can reproduce all components of the turbulent spectra;
Uses monitoring data for constructing and teaching the model as well as for its "initialization";
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MGO DISPERSION MODEL OND-86
Based on the analytical approximation of the numerical solution of ADE;
Calculates the field of the upper 98th to 99th percentiles of the annual PDF of concentrations;
Uses climatological rather than meteorological input data;
Intensively validated upon numerous data sets of field and laboratory measurements.
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PDF OF RATIOS OF MEASURED AROUND ALUMINUM PLANTS AND CALCULATED MAJORANT CONCENTRATIONS
0 0.25 0.5 0.75 1 1.25 1.50
0,2
0,4
0,6
0,8
1
1,2
C/Ccal
P(C/Ccal) Measured concentrations are less than 1.25 times calculated ones in 98% of all observations. Thus, the field of the 98th percentiles is calculated with the error of 25%.
This PDF was estimated using ~50,000 measured concentrations of HF
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Specifics of the emergency-response modeling
Estimates have to be conservative; Doses are more appropriate
characteristics than concentrations (because of their monotonous dependence from the exposure/averaging time);
Models should work in two regimes corresponding to potential (emergency response planning) and actual accidents
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Analytical approximation of the numerical solution of ADE for a ground-level source
;)exp(2
2
22/3 x
ky
xU
QD
;)(
;
221
1
UxifUxaaa
Uxifa
1)]}(/[{;/1.0
zzzzzuKf
kaa ,,21 are constants.
where
• This expression is resolved to determine the scale of contamination;
• The exposure time is 1 hour or more;
• The governing parameters are the wind speed and direction, and ; in the case of liquid spills, the air temperature is accounted for too;
• An impact for a ground-level source is considered as a majorant for those for an elevated source;
•Majorants are calculated for given intervals of U, wind direction and
• Dose criteria are listed for 34 poisonous pollutants.
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Validation of the MGO emergency-response dispersion model
1 – Stable stratifications (Mubareck field test, MGO);
2 - Stable stratifications (Prairie Grass, Green Glow, Ocean Breeze, Dry Gulch – after D. Slade);
3 – Neutral stratifications (Prairie Grass, Green Glow, Ocean Breeze, Dry Gulch – after D. Slade);
4 - Unstable stratifications (Prairie Grass, Green Glow, Ocean Breeze, Dry Gulch – after D. Slade);
5 - Neutral stratifications (wind tunnel – after J. Solaile)
ACCIDENTAL RELEASES - VALIDATION
0.0000001
0.000001
0.00001
0.0001
0.001
0.01
0.1
1.E-07 1.E-05 1.E-03 1.E-01
(UD/Q)p, m-2
(UD
/Q)m
, m-2
1
2
3
4
5
Perfect
Here D was calculated as a conditional majorant corresponding to given meteorological conditions
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STATISTICAL FORECASTS IN RUSSIA: STATUS REPORT
Routine forecasts produced in 235 cities on daily basis in 2002 using statistic models (SMs) developed for each of these cities using the same methodology;
Dimensionless parameter P predicted with SMs characterizes unfavorable meteorological conditions that could lead to high levels of air pollution over the whole urban area:
P = m/n, where "n" is the total number of measurements during
the day and "m" is the number of measurements in excess of 1.5 of corresponding seasonal average values;
A quantified characteristic of the synoptic situation is used as a synoptic predictor S;
"Previous" value of P is used as a predictor ("inertial factor");
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MAIN FEATURES OF A NEW MGO FORECASTING MODEL Predicts daily maxima of concentrations at monitoring
stations rather than their individual values corresponding to certain moments of time or average characteristics of air pollution over the city;
Can be efficiently used for conservative pollutants as well as ozone;
Selects initial set of predictors from physical considerations;
Includes stepwise transformations of predictors; Finally selects predictors and constructs the
prognostic model using stepwise multiple regression.
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MAIN STEPS OF TRANSFORMATION OF PREDICTORS
Normalization of daily maxima (optional): Cmax →B = Cmax / Cseason;
Censuring the sample to exclude smallest concentrations (optional; uses P);
Transformation of the predictant to the normal distribution;
Transformation of nonlinear dependencies in linear ones.
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GENERAL FORMULATION OF THE MODEL IN USE
The prognostic equation is written as follows:
Bt+1 = a0 + Σai[Xi] ,
where [Xi] are transformed predictors Xi at the moment "t", and coefficients "a" are determined using the method
of the stepwise regression.
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EFFICIENCY OF TRANSFORMATIONS /1
Fig
Trans-forma-tion
Sam-ple
<Bm> <Bp> m p Corr <m/p>
m/p
a) No 160 1.82 1.82 2.26 1.22 0.54 1.10 1.61
b) Censur. 70 2.82 2.82 2.62 1.51 0.58 1.10 0.91
c) Censur.+ Linear
70 2.82 2.77 2.62 1.64 0.78 1.09 0.65
d) Censur.+Norm+Linear
70 2.82 2.82 2.62 1.96 0.84 1.05 0.57
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EFFICIENCY OF TRANSFORMATIONS /2
0 2 4 6 8 10 12 14 16
Measured B
0
2
4
6
8
10
12
14
16
Pre
dic
ted B
a)
R=0.5386
0 2 4 6 8 10 12 14 16
Measured B
0
2
4
6
8
10
12
14
16
Pre
dic
ted
B
b)
R=0.5833
0 2 4 6 8 10 12 14 16
Measured B
0
2
4
6
8
10
12
14
16
Pre
dic
ted
B
c)
R=0.7795
0 2 4 6 8 10 12 14 16
Measured B
0
2
4
6
8
10
12
14
16
Pre
dic
ted
B
d)
R=0.8447
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PERFORMANCE OF STATISTICAL FORECASTS AT INDIVIDUAL MONITORING STATIONS
City Pollutant (R2; F) at each station
Krasnoyarsk CS2 (0.34;7.8), (0.36;14.0), (0.36;10.2), (0.55;30.3), (0.61;22.4), (0.52;21.4), (0.30;7.6), (0.36;9.9)
Krasnoyarsk HF (0.38;11.2), (0.37;10.1), (0.42;9.6), (0.48;11.2), (0.48;10.9), (0.42;9.5), (0.36,17.2)
Ufa Ethylbenzene (0.61;22.4), (0.55;26.4), (0.50;20.3)
Ufa Benzene (0.45;14.4), (0.48;16.4), (0.37;9.8)
On average, R2 ~ 0.4 – 0.6 with independent data sets
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OZONE MONITORING IN ST. PETERSBURG
Started in a street canyon in 1998 with two DOAS instruments located at 3 m and 15 m height; several monitors were additionally put in operation last year by the city;
The data set in the street canyon is not homogeneous because the pattern of traffic changed several times;
Meteorological mast is mounted on the top of the building with DOAS instruments;
Concentrations are usually rather moderate.
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SCHEMATIC LAYOUT OF DOAS SCHEMATIC LAYOUT OF DOAS INSTRUMENTS IN ST. PETERSBURGINSTRUMENTS IN ST. PETERSBURG
Fig. 1. Upper level site 1 - Meteorological mast; 2 - Upper level instruments (emitter, receiver) ; 3 - Upper level mirror.
3
2
1
5
4
Fig. 2 Street level site 4 -Street level instruments (emitter, receiver); 5 - Street level mirror
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STATISTICAL MODEL # 1 FOR DAILY OZONE MAXIMA IN ST. PETERSBURG (WARM SEASON)
O3,t+1 = 0.684[O3,t]+0.705[d]+ 0.53[NO2] + 0.525[ T]+0.683[V]- 141.9
where O3t and O3t+1 are daily maxima for days t and t+1, d – wind direction, T – air temperature, V – wind speed, NO2 – concentration of nitrogen dioxide;all predictors in the right-hand side are determined from measurements carried out on day t+1 at 7 a.m.
Predictor [O3t] [d] [NO2] [ T ] [V]Correlations with O3t+1 0.25 0.11 0.34 - 0.15 - 0.05Coefficient of multiple correlation R = 0.76
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PREDICTED VS MEASURED OZONE CONCENTRATIONS IN ST. PETERSBURG – STATISTICAL MODEL #1
20 30 40 50 60 70 80 90 100
O 3 meas
20
30
40
50
60
70
80
90
100
О3
pre
dic
t
R2 = 0,5796; R = 0,7613, p = 0,0000
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STATISTICAL MODEL # 2 FOR DAILY OZONE MAXIMA IN ST. PETERSBURG (WARM SEASON)
Bt+1 = 0.404[Bt]+0.322[d]+ 0.205[NO2] + 0.186[ T]+0.175[V]- 141.9
WHERE B = (O3,MAX-O3,7)/O3,7
Predictor [Bt] [d] [NO2] [ T ] [V]
Correlations with Bt+1 0.59 0.46 0.34 0.36 0.15
Coefficient of multiple correlation R ~ 0.9
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PREDICTED VS MEASURED OZONE CONCENTRATIONS IN ST. PETERSBURG – STATISTICAL MODEL #2
B = (O3,MAX-O3,7)/O3,7
-1,5 -1,0 -0,5 0,0 0,5 1,0 1,5 2,0 2,5 3,0 3,5
B Predicted
-1,5
-1,0
-0,5
0,0
0,5
1,0
1,5
2,0
2,5
3,0
3,5
4,0
B O
bse
rved
95% confidence
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CONCLUSION
When predicting majorants, one can expect reduction in the noise influencing the performance of the model and forecast;
Depending on the problem at hand, the majorants could correspond to different time intervals (e.g., day, week, year) and arbitrary or given meteorological conditions ("unconditional or conditional extremes");
The majorant approach is efficient with both, deterministic and statistical models.
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THANK YOU VERY MUCH FOR YOUR
ATTENTION!