EAS372 -- Lecture Log -- 2017

• Tues 11 April (final class). Weather briefing (Andrew). NCEP's GFS model. Downscaling a reanalysis: the July 1976 "Big Freeze" in southern New Zealand.

• Thurs 6 April. Weather briefing (Zheqi). NCEP's Regional ("NAM") and Global ("GFS") NWP models.
  Open: Exercise 6 Apr. Orientation to Assignment 3. Close: Exercise 6 Apr.

  • This multi-column Excel file has two non-empty columns, labelled w and T (vertical wind speed in m s^-1 and temperature in ^oC). It is a "practice file", in the sense that there are only 27 rows of data (thus, not a representative sample, merely a basis for familiarizing yourselves with needed calculations for Assignment 3). In the following, I use angle brackets to denote an average.

  • First, compute the (column) averages for the w and T columns, averages that we may designate by the terminology ⟨w⟩ and ⟨T⟩. Then fill in the empty columns headed w' (for the fluctuation w'=w-⟨w⟩) and T' (for the fluctuation T'=T-⟨T⟩).

  • Next, fill in the columns for w' w' and T'T'. The average of the first of these columns is the variance of the vertical wind speed, whose square root is the standard deviation "σ_w". Compute these, and repeat for the temperature variance and standard deviation.

  • Finally, fill in the column w' T', whose average is the (kinematic) eddy heat flux ⟨w' T'⟩. Multiply the latter by a nominal ρc_p=1000 [J m^-3 K^-1] to get the eddy heat flux Q_H = ρc_p ⟨w' T'⟩ [W m^-2].

  • Assignment 3 entails analogous calculations on a much bigger file, and in addition to ⟨w' T'⟩ requires that you compute statistics like (the "Reynolds stresses") ⟨u' w'⟩ and ⟨v' w'⟩. From these computed statistics one is able to evaluate the friction velocity and Obukhov length.

  Added after class: completed calculation as PDF (numbers rounded) and as spreadsheet.

• Tues 4 April. Weather briefing (Sarah). Continuing file on Canada's NWP model (GEM): parameterizations ("model physics").
  Open: Exercise 4 Apr. Weather forecast. Calculate boundaries for 3 equi-probable climatological temperature classes. Close: Exercise 4 Apr.

  • Prepare and submit a weather forecast form summarising anticipated conditions in C. Alberta for 00Z Thurs 6 April.

  • Excel files give the entire record of February minimum and maximum surface temperatures as observed at Edmonton and Winnipeg through February 2013. The temperature data are given as integers, to be interpreted as 10 x (T^oC), and each row gives row number, minimum, maximum temperature ("M" means "missing data"). Choosing one file or the other (optionally, both), sort the temperature columns from smallest to largest and, for each, determine the 33rd and 66th percentiles: these define the boundaries for three equi-probable classes. By this means one determines February climatological mean minimum and maximum temperatures, at Edmonton and Winnipeg.

  Added after class:

  1. With a sample size of 1356 after deleting missing data, the three equi-probable classes for Winnipeg February mean minimum temperature are defined by 33rd and 66th percentiles -24.4 and -15.6^oC, i.e. the normal class for the minimum spans -24.4 to -15.6^oC. The normal class for the maximum spans to -12.8 to -5^oC. The corresponding normal classes for Edmonton's February (based on sample size 1272) are a considerably milder -16.7 to -8.6^oC (normal minimum) and -7.2 to -1.8^oC (normal maximum).

  2. Available guidance for forecast:
     • GEM RDPS prog initialized 12Z Tues 4 April (36h forecast):
       • MSLP & thickness
       • 500 hPa height & vorticity
       • 700 hPa height & humidity
       • 850 hPa height & humidity
       • total cloud
       • omega at 700 hPa and at 500 hPa
       • precipitable water
       • 850 hPa temperature
       • surface temperature
       • surface wind
       • Meteogram for Edmonton

     • NAM model MSLP, thickness & precip

     JDW's diagnosis: surface/850 hPa pattern, the Alberta lee trough; thermal ridge over Alberta, thermal trough over the east; somewhat humid, southwest upper flow. Partly cloudy (trend to increasing rather than decreasing cloudiness). Mild (up to about 10^oC). Light S or SE wind. [As an aside: south of the Great Lakes and into S. Ontario, convective storms are expected.]

  3. Data for forecast assessment:
     • RDPS 0h progs valid 00Z Thurs 6 April:
       • MSLP and thickness
       • 700 hPa height and humidity
       • temperature at 850 hPa
       • surface temperature
       • surface wind
       • omega at 500 hPa
       • total cloud
       • precipitable water

     • Other evidence:
       • CMC surface analysis (lee trough evident)
       • CMC 850 hPa analysis (lee trough; and trowal - TRough Of Warm air ALoft)
       • CMC 700 hPa analysis (firm SW flow stricking the Rockies, cause of the lee trough)
       • CMC 500 hPa analysis
       • GOES IR 00Z
       • GOES VIS 00Z
       • Stony Plain sounding 00Z (note well-mixed ground-based layer)
       • hourly conditions at YEG
       • photograph: sky view to west, apprx. 03Z

• We're into the season for convective cloud (Mon. 3 April), the spring atmosphere being less stable than winter's. (But in mid April we received a covering of snow: here, Edmonton on 16th April 2017.)

• Thurs 30 March. Weather briefing (Lisong). More on Canada's NWP model (GEM).
  Open: Exercise 30 Mar. Generating NWP re-analyses. Close: Exercise 30 Mar.

  • Based on the NCEP Reanalysis 2 (covering from 1979 to Dec. 2016), recreate the field of MSLP for 12Z on 29 Oct. 2012 (Hurricane Sandy on the US east coast).
    • Select Surface data
    • Mean sea level pressure 4-times daily, click on the map
    • Make a plot or subset
    • Select the polar stereographic option; select a 400 Pa contour interval; set the latitude range as 30N to 60N; and set the longitude range as 90W to 60W.
    Compare with the CMC surface analysis (cropped) for the same time. Compare the positions of the 1016 hPa contour (on the CMC analysis it runs through Toronto, the station near the west edge of the chart that reported T=5^oC and T_d=2^oC). Here is the GOES ir image for 1515Z. Canadian Hurricane Centre (EC) 8:52 AM ADT Mon 29 Oct. 2012: "Large and dangerous hurricane Sandy beginning to turn toward U.S. coastline. S. Ontario, S. Quebec and SW. Maritimes will experience high wind gusts and periods of heavy rain beginning later today and continuing into Tuesday."

  • Based on NCEP Reanalysis 1 (covering 1948/01 to present), recreate the field of MSLP for 12Z on 27 March 2017 (TC Debbie on the NE coast of Australia).
    • Select surface
    • Select sea-level pressure 4 times daily
    • Click the map; make plot or subset
    • select a 400 Pa contour interval; set the latitude range as 45S to 0S; and set the longitude range as 100E to 170E.
    Compare with the Australian Bureau of Meteorology (BOM) analysis and with the CMC GDPS 0h prog. What do you conclude from this comparison as regards the optimal source of information for the "truth" of a weather event? (Optional reading on the purpose and procedure for the NCEP reanalyses, Kalnay et al. 1996. Other national weather services now produce their own reanalyses, based on their own preferred data assimilation systems, which, necessarily involve their chosen NWP model.)

  • Obtain the most recent Environment Canada deterministic seasonal forecast for the March-April-May temperature anomaly. How do you suppose one could determine what range (T_max-T_min) for the March/April/May seasonal mean temperature would correspond to the "above normal" category for (say) YEG (Edmonton International Airport)?

  Added after class:

  • NCEP II reanalysis: MSLP for Hurricane Sandy.
  • NCEP I reanalysis: MSLP for TC Debbie
  • Environment Canada deterministic seasonal temperature anomaly forecast for Mar/Apr/May 2017
  • Environment Canada deterministic seasonal temperature anomaly forecast for Apr/May/June 2017

• Tues 28 March. Weather briefing (Karen). Follow up on Tropical Cyclone Debbie in NE Australia, predicted 5 (or more) days in advance by GEM-GDPS. Background on Canada's NWP model (GEM).
  Open: Exercise 28 Mar. Daily cycle of surface energy balance components. Close: Exercise 28 Mar.

  • Plot the daily cycle in hourly-averaged energy balance components (file flanagan.txt) over grassland in Alberta, 1 July 2003. This is most easily done using a computer program (e.g. Excel or Matlab, etc.), but can also be done by hand on standard graph paper. The data file gives net radiation (labelled Q^∗), sensible and latent heat flux densities (Q_H, Q_E) and the "ground" heat flux (Q_G). All fluxes are in [W m^-2]; data courtesy of Dr. L. Flanagan (U. Lethbridge). Please plot each of these flux densities, and the "residual" (or "imbalance")
    R = Q^∗ - Q_H - Q_E - Q_G.

  Added after class: Matlab plot of energy balance components.

• Thurs 23 March. Lecture: slope of dewpoint lapse-rate lines (isohumes).
  Open: Exercise 23 Mar. Slope of isohumes. Weather forecast. Close: Exercise 23 Mar.

  • Compute the mixing ratio r [g/kg] of a saturated parcel whose pressure and temperature are (950 hPa, 0^oC). Is this consistent with the label on a skew-T diagram associated with the isohume that runs through (950 hPa, 0^oC) on the chart?

  • On a skew-T diagram, evaluate the slope ΔT_d/Δlnp of a dewpoint lapse rate line using suitable finite differences. Repeat this calculation for two different layers (i.e. pressure intervals) and, for one of those layers, repeat for two distantly separated dewpoint lapse rate lines, i.e. using "isohumes" for two widely different locations on the saturation mixing ratio axis. Compare with the theoretical value

    ∂T_d / ∂lnp = (273+T_d)² / (273 x 22.5)

    which for T_d=(-20, 0, 20)^o evaluates to (10.4, 12.1, 14.0) K.

  • The GDPS prog initialized (t₀) at 12Z Wed. 22 March indicates that at 12Z Monday 27 March (t₀+120h) a strong, compact but slow-moving tropical storm will be just offshore from the NE coast of Australia, in the Townsville area north of Brisbane: see GDPS MSLP & surface wind, and 700 hPa height & humidity (the storm's slow movement but rather abrupt deepening is seen in this animation of the GDPS panels).

    Interestingly, the corresponding Australian 120h global prog (accessed from Bureau of Meteorology, "BOM") is very different, showing only a weak remnant of this low pressure centre, some distance inland. However the Australian prog does place that storm on the coast at about 12Z Saturday 25 March, albeit as a much shallower centre... this BOM multipanel chart gives the path of the storm according to the Australian model. The Bureau of Meteorology issued this statement in regard to the system (from http://www.bom.gov.au/qld/forecasts/cyclone.shtml). The site weather-forecast.com gave this public forecast, with no sign of a tropical storm.

    Please follow up on this discrepancy, by accessing the most recent available NWP guidance (GEM GDPS via Vizaweb and BOM Global) for NE Australia valid 12Z Monday 27 March. Very briefly record your interpretation on the weather forecast form.

  Added after class:

  • ρ=950 x 10²/(287 x 273.15) = 1.21 kg m^-3. The dewpoint is 0^oC, so e=e_*(0^oC) = 6.11 hPa. Then ρ_v=611/(462*273.15)=4.84 x 10^-3 kg m^-3. The mixing ratio is therefore r=ρ_v/ρ = 4.00 x 10^-3 kg/kg (or 4 g/kg). This is indeed consistent with the label on the isohume in question.

  • Sample answer: the 4 g/kg isohume runs through (p,T)=(950 hPa, 0^oC) and (nearly enough) (p,T)=(650 hPa, -5^oC). Then for Δ ln(p)=ln(650)-ln(950)= - 0.379 we have ΔT_d= -5 K, giving ΔT_d/Δlnp = 13.2.

  • The GDPS 108h prog (initialised 00Z Tues 23 March) indicates that the Coral Sea storm arrives on the coast as a much weaker system than had the longer range (120h) prog:
    • MSLP & sfc wind
    • MSLP & thickness
    • 700 hPa
    • 6h precip
    The corresponding BOM 108h progs are:
    • MSLP
    • 700 hPa
    • 6h precip
    and the updated BOM statement anticipates high likelihood of a storm on Sunday. As this GDPS animation shows, the Canadian forecast is suggesting an earlier landing for the storm than it (i.e the earlier forecast run) had previously done, with the central pressure, albeit difficult to read, not as deep as in the previous day's forecast. The Canadian and Australian progs are not as glaringly inconsistent as they had been.

• Tues 21 March. An illustration (by way of prog fields) of PVA & PTA near a surface cyclone. Lecture on satellite meteorology.
  Open: Exercise 21 Mar. Moisture convergence field in relation to heavy precipitation. Close: Exercise 21 Mar.

  During 19-20-21 June 2013 severe flooding occurred in S. Alberta (here is the June 2013 weather record for Crowsnest Pass). Based on the CMC 700 hPa analysis analysis (12Z June 20th 2013) one might immediately guess a slow-moving upper low, directing a stream of moisture against the mountains, could have been the culprit (note: this is an extrapolation based only on this snapshot; of course other factors ought to be considered).

  • Prolonged heavy precipitation demands a moisture source, and it would be interesting to display the convergence of the horizontal moisture flux,

    ∇_H • (u_H q ) = ∂ (u q) / ∂x + ∂ (v q) / ∂ y

    where q is the specific humidity. Note that where this quantity is negative, moisture is being suppied to the air column and represents a source for precipitation; note also that since q is dimensionless, the quantity has the unit velocity/length. It would be nicer to have used the absolute humidity (ρ_v) in place of q, in which case the moisture convergence would have the sensible unit [kg m^-3 s^-1], clearly a moisture source strength. Be that as it may, use the Plymouth State Weather Center web site to generate the moisture convergence field on the 700 hPa level over Western Canada at 12Z on 20 June 2013 (the unit will be knots m^-1).

    • Region: Western Canada
    • Variable 1: Moisture Convergence, Contour/Plot Type: line & color fill, Interval: 10, Color: black
    • Variable 2: Geopotential Height, Contour/Plot Type: line, Interval: 30, Color: black

  • Use the NCEP Reanalysis data to generate a chart for Omega at the 700 hPa level for 12Z June 20th 2013
    • Select "pressure level"
    • Select "Omega (Vertical Velocity) 4-times Daily"
    • Select "Make plot or subset" in the upper row ("4 Time Daily Individual Obs ... Multiple Levels")
    • Fill in these specifications (for lat/long range, date & time etc.) to create your chart

  Note: Computing or measuring divergence always entails finding the small difference between large numbers, and as such, is a legendary difficulty. Some of the features plotted on your chart may in fact be artifices. The quality of a flux divergence field is to some extent dependent on the quality of the velocity divergence field, and that (in turn) to some extent linked to the density of upper air observations (radiosonde stations) informing the underlying weather model. Secondly, recall that unresolved terrain detail may have played a role in the precipitation pattern, so that while suggestive, a map like this is not definitive.

  Added after class:

  • Moisture convergence for 12Z 20 June 2013.
  • Omega at 700 hPa for 12Z 20 June 2013 (NCEP reanalysis).

• Thurs 16 March. (Short) lecture on fronts and frontogenesis.
  Open: Exercise 16 Mar. Calculate vorticity advection. Plot wind profile in neutral surface layer. Close: Exercise 16 Mar.

  • The RDPS 0h prog valid 06Z Wednesday 15 March showed a vortmax in west-central Saskatchewan (associated with a shortwave trough rippling towards a longwave ridge). In the same location, the prog indicated ascending vertical motion. Estimate the rate of vorticity advection A_η = - U ∂ η / ∂ s downwind of (i.e. northeastward from) the vortmax. Note: U is the 500 hPa wind speed, which you'll need to compute from the height gradient; η is the absolute vorticity; and s is the natural coordinate aligned with the height contours. (This exercise relates to a calculation needed for Assignment 2.)

  • Plot a surface layer wind profile on semi-logarithmic graph paper (hard copy handout), and deduce the friction velocity.

  Answers:

  • Graph of mean wind profile for PPG Run 57, and computation of friction velocity
  • Graph of two point mean wind profile, and computation of friction velocity, surface drag, 10 m wind speed and standard deviation (σ_w) of vertical velocity
  • Note on extracting Δln(z): observe that ln(10)-ln(1) = 2.30259 = ln(8)-ln(0.8) = ... Thus one decade on the paper always has the same ruler length (say, "D"), and this ruler distance corresponds to the constant ln(10). Thus, measure the length D on your graph paper and the length d correspondingto your interval on the ln(z) axis. Then Δln(z)=2.30259 (d/D). [It is usually quicker to use your calculator to obtain the difference ln(z₂)-ln(z₁)].

• Tues 14 March. Complete lecture on the atmospheric surface layer and Monin-Obukhov similarity theory.
  Open: Exercise 14 Mar. Resolved vertical humidity flux (involving water vapour calculations). Close: Exercise 14 Mar.

  • A so-called north-easter storm is presently rolling (quite quickly) up the US east coast, causing the usual media alarms (the storm is visible on this morning's CMC surface analysis). Onshore winds will occur north of the low's centre, while south and southwest of the low cold dry air will advance towards the coast.The storm will result in rain offshore and near the coast, with snow further inland (weather radar 9:45 EDT). Broadly speaking, a warm sector associated with the storm is depicted in the 700 hPa temperature and relative humidity charts from this morning's 12h RDPS prog valid 18Z Tues 14 March. The prog also indicates a shield of elevated values of precipitable water over the U.S. east coast, and ascent at the 700 hPa level. Relative humidity at 700 hPa exceeds 90% and temperature at 700 hPa peaks in the 1.5 to 5^oC range. Taking the upper end of the ranges for ω₇₀₀, T₇₀₀ and RH₇₀₀ (such that e₇₀₀=e*(5^oC)), calculate an upper limiting value for the resolved vertical vapour flux density (in kg m^-2 s^-1) in the area, and convert this to an equivalent liquid precipitation rate in mm hr^-1.

  • Please review your forecast from last class relative to observed conditions (given below) in Newfoundland at 12Z on Saturday 11 March

  Added after class:

  The storm did cause chaos in the eastern U.S. and Canada, but perhaps the most prominent news item was that much less snow fell in New York City than had been forecast. From the New York Times: "The blizzard warning was canceled quickly for New York. The so-called March Madness storm did not quite live up to its name. But for air travelers, in particular, the storm hype resulted in woes, rebookings and a bit of creative thinking. Many airlines started grounding flights well before the weather system moved through the Northeast, keeping planes away from a region that was expected to be paralyzed. In total, more than 6,000 flights were canceled across the United States on Tuesday, including all American Airlines flights to New York City's three main airports" (Zach Wichter, 14 March)

  • Taking T₇₀₀=+5^oC and the relative humidity as 100%, we have e=e_*(5^oC)=8.719 hPa. Using the ideal gas law for vapour, this implies ρ_v=872/(462 x 278.15)=6.79 x 10^-3 kg m^-3.

    Now with ω₇₀₀ = -4 Pa s^-1 (there were cores of even higher ω) and density ρ=700/(287 x 278.15)=0.877 kg m^-3 we deduce that w=-ω/(ρ g) = +0.46 m s^-1 and so the resolved vertical vapour flux density (according to this calculation) is

    E=⟨w⟩ ⟨ρ_v⟩ = 3.1 x 10^-3 kg m^-2 s^-1. To convert this vapour flux density to a velocity, we divide by the density of liquid water, i.e. by 1000 kg m^-3. This gives us E= 3.1 x 10^-6 m³ m^-2 s^-1 (so we have the unit: [m s^-1]). To converting this to a velocity in mm/hr we multiply by 1000 (m to mm) and by 3600, so, E= 11 mm hr^-1. It is common to multiply liquid water depths by 10 to get snow depths, thus 11 cm/hr of snow.

    Just for interest, here is the analysed 24h cumulative precip (valid 12Z Wed. 15 March), which you might compare against the forecast precipitable water. It is important to understand that this computation -- for the resolved vertical vapour flux E -- is by no means necessarily equal to the actual precipitation rate at ground. Neither should the precipitable water [mm] be regarded as being a forecast for actual precipitation (over 6h? 12h? 24?). That said, strong precipitation rates are unlikely to be seen in regions where the precipitable water is low (dry air) and where the air aloft, as well as being quite dry, is not in a state of rapid ascent. Convective (summer storm) rainfall events are a possible exception to this statement.

• Thurs 9 Mar. Discussion of yesterday's blizzard in Central Canada. Lecture on the (idealized) atmospheric surface layer and Monin-Obukhov similarity theory (background for the third and final assignment).
  Open: Exercise 9 Mar. Weather forecast. Close: Exercise 9 Mar.

  • Prepare and submit a weather forecast form summarising forecast conditions for the St. John's Newfoundland region around 12Z on Saturday 11 March.

  • Suppose x_i=(-3,-2,0,2,-4,1) represents the temperature at six points (labelled "i"). Determine the mean "X" and the vector x'_i of deviations (or "fluctuations") from the mean. Demonstrate to yourself that the mean of the deviations is zero.

  Added after class:

  Available guidance:

  • GEM RDPS prog initialized 12Z Thurs 9 March (48h forecast):
    • MSLP & thickness
    • 700 hPa height & humidity
    • total cloud
    • total cloud
    • omega at 700 hPa and at 500 hPa (these two charts from the GDPS 48h fcst, as instructor forgot to archive the corresponding RDPS charts))
    • precipitable water (from the GDPS 48h prog)
    • dominant precip type (over 6h prior to 12Z March 11)
    • cumulative precip (over 6h prior to 12Z March 11)
    • 850 hPa temperature
    • surface temperature
    • surface wind
    • 500 hPa height & vorticity

  • NAM model MSLP, thickness & precip
  • RDPS meteogram
  • NAM meteogram
  • EC public forecast

  Data for forecast verification:

  • The "strongest storm we've seen in more than a decade"... (media)

  • CMC analyses:
    • 700 hPa analysis
    • 850 hPa analysis
    • surface analysis

    Observations:

    • past 24h, St. John's
    • past 24h, Gander
    • EC weather alerts, Newfoudland
    • GOES EAST visible
    • GOES EAST ir (1215Z)
    • GOES EAST ir (1145Z)
    • radar

  • RDPS 0h progs valid 12Z Saturday 11 March 2017:
    • MSLP and thickness
    • 700 hPa height and humidity
    • total cloud
    • precipitable water
    • omega at 700 hPa
    • omega at 500 hPa
    • CaPA 6h cumulative precip
    • 850 hPa temperature
    • surface temperature
    • surface wind

  • Other:
    • 3h dominant precip type (3h prog valid 15Z)
    • 3h cumulative precip (3h prog valid 15Z)

• Tues 7 Mar. Weather discussion: comparison of weather fcst from previous class with observed conditions. Lecture: governing equations resulting from the Reynolds decomposition; the "Reynolds-averaged" equation expressing conservation of sensible heat, showing the influence of unresolved motion on evolution of the resolved (potential) temperature.
  Open: Exercise 7 Mar. Forecast critique; and ABL heat budget. Close: Exercise 7 Mar.

  • Please re-assess your own circa. 120 h forecasts from last class, relative to observed conditions around Winnipeg at 00Z today (i.e. 18 CST Monday 6 March). (Observed data, as well as information available at the time forecasts were prepared, are given below).

  • Heat budget calculations relating to diurnal warming in an ideal ABL

  Answers to heat budget questions (angle bracket denotes average): (1) surface kinematic heat flux ⟨w'θ'⟩₀ ≈ 0.28 K m s^-1; (2) ∂⟨θ⟩ / ∂t ≈ 0.6 K hr^-1.

• Thurs 2 Mar. Lecture: basis for the unsaturated adiabatic lapse rate; energetics of vertical motion; the Reynolds decomposition, as basis to distinguish resolved and unresolved scales of motion in NWP (and as essential basis for obtaining many useful governing equations for the turbulent part of the atmosphere).
  Open: Exercise 2 Mar. Weather forecast; Calculation of static stability σ Close: Exercise 2 Mar.

  • Prepare and submit a weather forecast form summarising forecast conditions for the Winnipeg region around 00Z on Tuesday 7 March.

  • Compute an estimate of the static stability σ of the 850-400 hPa layer from the morning sounding at Resolute Bay (CYRB; 71924) on 1 March 2017. There are several ways to do this, the easiest being to use the sounding data (otherwise one could use the dry adiabats on the skew-T diagram; or, compute potential temperatures using the formula that defines them). [Note: unfortunately only the raw ascii sounding data are available for CYRB, so students will have to use the dry adiabats, which recall are isolines of potential temperature].

  • Repeat the above for the afternoon sounding at Albuquerque (ABQ) New Mexico on 12 Aug. 2016.

  (These soundings illustrate an extreme range in stratification.)

  Added after class: Guidance available from the GEM RDPS prog initialized 00Z Thurs 2 March (mostly 120h forecasts; the RDPS run initialized at 12Z Thurs 2 March had not completed in time to be used for this task):

  • MSLP & thickness (versus initial state)
  • 12h cumulative precip as of 00Z Tuesday 7 March
  • 700 hPa height and humidity
  • total cloud
  • 500 hPa height & vorticity
  • omega at 500 hPa
  • omega at 700 hPa
  • temperature at 850 hPa
  • surface temperature
  • sfc wind (close-up seen on Central Canada grid)
  • 6h dominant precip type as of 12Z Tuesday 7 March
  • 6h dominant precip type as of 18Z Monday 6 March
  • Meteogram

  • Some other interesting charts:
    • GFS 700 hPa level, height and horiz. divergence: as expected, we see negative divergence (i.e. convergence) in the bottom half of the troposphere associated with the closed upper low (this plot produced at this site).
    • GFS Q-vectors at 700 hPa:

  Actual conditions around Winnipeg at 00Z on Tuesday 7 March 2017:

  • Winnipeg hourly observations through 00Z Tues 7 March (18CST Monday 6 March)
  • Winnipeg hourly observations leading up to 00Z Tues 7 March
  • GOES vis image
  • GOES ir image
  • Radar image
  • CMC surface analysis and RDPS 0h prog's MSLP & thickness
  • CMC 500 hPa analysis and RDPS 0h prog's 500 hPa height & vorticity
  • CMC 700 hPa analysis and RDPS 0h prog's 700 hPa height & humidity
  • CMC 850 hPa analysis and RDPS 0h prog's 850 hPa temperature
  • RDPS 0h prog's surface temperature and surface wind
  • RDPS 0h prog's total cloud
  • RDPS 0h prog's Omega 700 hPa and Omega 500 hPa
  • CaPA 6h cumulative precip as of 00Z
  • CaPA 24h cumulative precip as of 12Z Tues 7 March
  • RDPS 0h prog's 3h surface pressure tendency vld 03Z Tues 7 March
  • temperature change as observed in nearby soundings at International Falls at 00Z and 12Z 7 March
  • NAM 0h prog's divergence at 900 hPa (low level CONvergence over Winnipeg region)... from www.weather.uwyo.edu/models/fcst/index.html
  • NAM 0h prog's divergence at 400 hPa (high level DIvergence over Winnipeg region)

• Tues 28 Feb. Second lecture on the quasi-geostrophic paradigm for mid-latitude, synoptic scale meteorology. (Background for assignment 2; also, please do consult the added file on propogation of uncertainty in calculations).
  Open: Exercise 28 Feb. Visualize computed (backward) air trajectories. Close: Exercise 28 Feb.

  On Tues 31 January we anticipated (what was then) a forthcoming cold spell, noted in a 180h GEM forecast. On Tues 7 February we compared that prog against the actual 12Z conditions of that morning. Today's exercise investigates the recent (72h) history of the air that was present around Edmonton at 12Z Tues 7 Feb. 2017. We wish to see "backward trajectories" of air that ended up in Edmonton in the depths of the cold spell.

  • Using NOAA's HYSPLIT application, create an ensemble of 72 h backward trajectories, ending at CYEG (Edmonton International Airport) at 12Z February 7 2017 (CYEG's 12Z temperature at 12Z on 7 February 2017 was -31^oC). Details:
    • Select "Compute archive trajectories"
    • Number of start locations: 1
    • Type of Trajectory: Ensemble
    • Meteorology: select GDAS (Global Data Acquisition System) 0.5 degree, global, 09/2007-present
    • Source location: CYEG
    • Select archive file: 20170207_gdas0p5
    • Select "Backward", 72h, start time 2017 02 07 12
    • New trajectory every 0 hours, Max of 24 trajectories
    • Level 1 height: 500 m AGL

    Please hand in a paragraph summarizing what this exercise has demonstrated (or what you conclude from it).

    Added after class: Example

• Thurs 16 Feb. Midterm examination.

• Tues 14 Feb. First of several lectures on the quasi-geostrophic paradigm for mid-latitude, synoptic scale meteorology. (Preparation for Assignment 2, which will be posted soon and due 21 March.)
  Open: Exercises 14 Feb. Functions of the skew-T diagram. Compute sensible heating from difference of soundings. Close: Exercises 14 Feb.

  • Complete the following exercises relating to skew-T diagrams (find LCL, LFC, shade in CAPE, etc).

  • Compute the apparent amount of heat added to the lower atmosphere over Edmonton between 12Z on 10 Aug. 2011 and 00Z on 11 Aug., by "differencing" these two (sequential) temperature soundings (these are the first two soundings of the exercise above). In other words by differencing the two soundings and integrating w.r.t. height, compute (a very approximate value for) the amount of sensible heat injected over the 12 hour interval, i.e. Q_H Δt [J m^-2] where Δt=12 x 3600 [s]. Note that the potential temperature is roughly height independent (303K) on the afternoon sounding, meaning one can compute a temperature for any height where it is wanted: T=θ (p/p_ref)^0.287.

    For simplicity, let's label the morning sounding T_1i (i=1...8) where p_i, z_i are the corresponding pressure and height. Now on the afternoon sounding θ is constant (we'll take θ=303 K). Thus, for each p_i of the morning sounding we are able to compute an afternoon temperature T_2i (i=1...8), where each T_2i is obtained by using (rearranging) the equation that defines θ (in this equation, for each p_i we know θ, so rearrange to get T_2i).

    Now for each p_i (which corresponds to height z_i) compute ΔT_i = T_2i - T_1i and the local density ρ_i.

    Finally, compute the total heat added by the approximation Q_i Δt = Σ_i ρ_i c_p ΔT_i (z_i+1 - z_i ), with the summation (Σ_i) running from =1...7.

  • On your own time, please assess your own weather forecast (made Thursday 9 Feb.) against observed conditions in Winnipeg during 12Z Thurs 9 Feb. to 12Z Saturday 11 Feb., as judged by the data given below (under the exercise for 9 Feb.)

• Thurs 9 Feb. Lecture: conservation equations (for mass & horizontal momentum) in the isobaric coordinate system. Height-integrated form of the continuity equation. The notion of "Dines compensation".
  Open: Exercises 9 Feb. Weather Forecast. METARs. Close: Exercises 9 Feb.

  • Prepare and submit a weather forecast form summarising the main weather events to be expected for the Winnipeg region in the time interval between 12Z Thursday 9 and 12Z Saturday 11 February 2017.

  • Obtain, decode and submit the METARs for CYEG (Edmonton International Airport) and for CYWG (Winnipeg) for 12Z Tuesday 7 February and for 12Z today. Note METAR cloud base heights are AGL.

  Added after class:

  • Instructor's forecast, and charts consulted:
    • Movie of the GEM RDPS MSLP & thickness progs** (a storm moves out of Alberta and across Winnipeg).
    • 700 hPa height and humidity at 06Z Friday. While the pattern was not exactly zonal and varied a bit, it could be summarized as a firm and roughly zonal flow.
    • Surface temperature at 12Z Thursday (minus 10 to minus 20), 15Z Friday (warm air perhaps not quite reaching Winnipeg?) and 12Z Saturday (cold air flows back).
    • Surface wind at 09Z Friday (SE) and at 18Z Friday (NW).
    • Temperature at 850 hPa at 12Z Thursday ("cold") and 12Z Friday ("warm").
    • Total cloud at 09Z Friday (cloud arriving) and at 00Z Saturday (cloud leaving/dissipating).
    • Omega at 700 hPa at 00Z Friday and at 09Z Friday (some decent lift in the area).
    • Omega at 500 hPa, 09Z Friday
    • 500 hPa height and vorticity at 06Z Friday and at 12Z Friday (a shortwave trough accompanies the surface storm).
    • GEM RDPPS Meteogram for Winnipeg
    **The movie was created (on a Linux system) by placing the .png files (consistently named "prog_RDPS_15h_MSLP_vld_20170210@12Z.png" etc) into a directory and running "convert -delay 40 -quality 100 prog*.png moviename.gif"

  • METARs:
    • CYEG 091200Z 17002KT 15SM OVC180 M19/M23 A2961 RMK AC8 SLP092=
    • CYEG 071200Z 23006KT 15SM SCT180 M31/M33 A3003 RMK AC4 SLP253
    • CYWG 071200Z 36012KT 1 1/2SM -SHSN DRSN OVC021 M20/M23 A2997 RMK SN4SC4 SLP177
    • CYWG 091200Z 26012KT 15SM SKC M22/M26 A3008 RMK SLP216=

  • Charts/info for forecast verification:

    • Observed conditions in Winnipeg on Thurs 9 Feb (times are CST, and CST=GMT-6). Strong south winds by late in the day, and a warming trend. (Past weather data can be obtained here).

    • Observed conditions in Winnipeg on Friday 10th Feb. Winds switch to northerly and pick up, after about 08 CST (14Z Friday 10th Feb.)

    • Animation of CMC surface analyses (formation of low in S. Alberta, and its rapid movement to the east)
      • CMC surface analysis 12Z Thursday 9 Feb
      • CMC surface analysis 18Z Thursday 9 Feb
      • CMC surface analysis 00Z Friday 10 Feb
      • CMC surface analysis 06Z Friday 10 Feb (note: snowing in Edmonton, overnight Thursday 9 Feb)
      • CMC surface analysis 12Z Friday 10 Feb
      • CMC surface analysis 18Z Friday 10 Feb
      • CMC surface analysis 00Z Saturday 11 Feb
      • CMC surface analysis 06Z Saturday 11 Feb
      • CMC surface analysis 12Z Saturday 11 Feb

    • GEM GDPS 0h prog for MSLP/thickness at 12Z Thursday 9 Feb. About 510 dam at Winnipeg.
    • GEM GDPS 0h prog for MSLP/thickness at 12Z Friday 10 Feb. About 540 dam at Winnipeg (15^oC warming over past 24 h).
    • GEM GDPS 0h prog for MSLP/thickness at 12Z Saturday 11 Feb. About 528 dam at Winnipeg (6^oC cooling over past 24 h)

    • CMC 700 hPa analysis 12Z Friday 10 Feb. We see the (roughly) zonal flow across the southern prairies; and the shield of high humidity that has almost progressed past Winnipeg by this time

    • GEM RDPS 0h prog for surface temperature 12Z Friday 10 Feb. The low did not manage to push the mild air up as far as Winnipeg. (The instructor's forecast "briefly above freezing around 12Z Friday" is a bust in that respect)
    • GEM RDPS 0h prog for surface temperature 18Z Friday 10 Feb. By now the wind in Winniupeg has turned to being a northerly... no chance now of the mild air affecting Winnipeg.

    • CaPA 24h cumulative precip as of 12Z Friday 10 Feb (2.5 to 5 mm liquid, equiv. to roughly 2.5 to 5 cm snow)
    • CaPA 24h cumulative precip as of 12Z Saturday 11 Feb (perhaps a further 1/2 cm of snow)

• Tues 7 Feb. Weather discussion: comparison of this morning's 12Z situation with the GEM 180h prognosis. Lecture: thermal wind and the hodograph.
  Open: Exercises 7 Feb. Hodograph. Thermal wind. Close: Exercises 7 Feb.

  • Plot the hodograph for Glasgow, Montana (KGGW) for 00Z Monday 6 Feb. 2017. More specifically, plot the vind vector at these levels: (850,832,800,770,700,500) hPa. Draw on a thermal wind vector for the 850 to 500 hPa layer, and deduce the orientation of thickness contours. Where does colder air lie? Compare with the isotherm pattern on the 850 hPa analysis.
  • Via the course URLs (or shortcutting, here), use the U. Wyoming site to create a hodograph and verify the correctness of your own.

  Added after class:

  The thermal wind was (roughly) a westerly, thus colder air lay to the north - as confirmed by the isotherm pattern on the 850 hPa analysis.

  • Sounding data
  • Hodograph as per U. Wyoming (produced online)
  • Sounding and hodograph produced using RAOB
  • Sounding as per Twister

• Thurs 2 Feb. Lecture: recognizing (and recognizing the underlying processes contributing to) some classical transport equations (in one or more space dimensions, and steady-state or otherwise): the "heat" equation, "diffusion" equation; "advection" equation; "advection-diffusion" equation, "Poisson" equation, "Laplace" equation. Review of water vapour variables and their relationship to one another.
  Open: Exercises 2 Feb. Water vapour calculations. Close: Exercises 2 Feb.

  Perform the following calculations for the Key West sounding (00Z 1 Feb. 2017): here are the corresponding data:

  • From (T,T_d )₈₅₀ compute the equilibrium vapour pressure and the actual vapour pressure; the absolute humidity ρ_v; the relative humidity; specific humidity and mixing ratio
  • Repeat the calculation for the 700 hPa level
  • Compute the difference between the actual and the virtual temperatures of the surface air; repeat for the air at 300 hPa

  Answers:

  • 850 hPa level: (T,T_d)=(5.5, 9.0)^oC. Then e=e_*(T_d)=9.028 hPa, while the "benchmark" (i.e. equilibrium vapour pressure) is e_*(T)=11.474 hPa. Then the RH=0.79 (in agreement with the sounding data). The absolute humidity ρ_v=e/(R_v T) = 6.926 x 10^-3 kg m^-3. The partial pressure of dry air p-e=840.97 hPa, so the partial density of dry air is ρ_d=(p-e)/(R_d T)=1.039 kg m^-3. Thus the mixing ratio r=ρ_v/ρ_d=6.67 x 10^-3 (agreeing with the sounding data) and the specific humidity q=ρ_v/(ρ_d+ρ_v)=6.62 x 10^-3
  • 700 hPa level: (T,T_d)=(5.0, -33.0)^oC. The "benchmark" (i.e. equilibrium vapour pressure) is e_*(T)=e_*(5^oC) = 8.7192 hPa. The vapour pressure is e=e_*(w)(T_d)=e_*(w)(-33^oC)=0.3818 hPa. This gives RH=0.044, which rounds to 4% (agreeing with the sounding data). Had we computed the vapour pressure as e=e_*(i)(T_d)=e_*(i)(-33^oC)=0.2769 hPa we'd deduce that RH=0.032 or 3%. Apart from this point, i.e. that the convention is to use e_*(w) for computations with subfreezing (T,T_d), the needed calculations for the 700 hPa level mimic those given above for the 850 hPa level.
  • Taking the 1000 hPa level to represent the "surface", T=18.0^oC, while r=8.3 x 10^-3. Thus T_v=T(1 + 0.61 r)=291.15 (1 + 0.61 x 8.3 x 10^-3) = 292.62 K or 19.47^oC.

• Tues 31 Jan. Weather outlook for 7 to 9 Feb. 2017 (extreme cold). Lecture: review first-law of thermodynamics, meaning of potential temperature and the skew-T diagram.
  Open: Exercises 31 Jan. Skew-T diagram. Critique a weather forecast. Close: Exercises 31 Jan.

  • Yesterday afternoon it was sunny, dry and windy in Edmonton. What feature of the Stony Plain (wse) sounding reflects that state?
  • Plot the 12Z 29 Jan. 2017 radiosonde temperature profile from Fort Smith (YSM, near the NE corner of Alberta) on a blank skew T diagram (hard copy handout). Plot T(p) up to the 500 hPa level. What stability category applies to the 700-500 hPa layer? What is the potential temperature of air at the 500 hPa level (taking 1000 hPa as the reference pressure). Does this value agree with the value reported with the sounding data?
  • Briefly annotate a fellow student's forecast from our previous class, assessing the forecast against the observed situation; verification data are given below along with the charts used to prepare these forecasts.

  Answers:

  • The Stony Plain sounding (00Z on 31 Jan.) exhibits a well-mixed layer from ground to about 750 hPa. The 700-500 hPa layer of the Fort Smith sounding (12Z Jan. 29th) is conditionally unstable (however students may legitimately have drawn a different conclusion based on their hand-plotted soundings). Using the dry adiabat through (p,T)₅₀₀ we get θ₅₀₀≈20^oC (≈ 293 K) which agrees with the formula: θ₅₀₀=(273.15-33)*(1000/500)^0.287 ≈ 293 K. The sounding data gives θ₅₀₀=292.6 K.

• Thurs 26 Jan. Lecture: specific cases of our conservation equation (or "transport equation") for "φ", viz. taking φ ⇒ ρ_v (the absolute humidity, kg m^-3) to obtain the statement of conservation for water vapour; taking φ ⇒ ρ_a c_p T (sensible heat content, J m^-3) to obtain the conservation equation for sensible heat; and taking φ ⇒ ρ_a (air density) to obtain the conservation equation for air mass (the "continuity equation").
  Open: Exercises 26 Jan. Weather forecast. Close: Exercises 26 Jan.

  • Prepare a forecast for Central Alberta at 00Z Sunday 29 January. Submit your forecast on this forecast form

  Some of the available charts, mostly GEM RDPS:

  • MSLP and thickness (versus MSLP and thickness at t0)
  • 500 hPa height and vorticity
  • 700 hPa height and humidity
  • Temperature at 850 hPa
  • Surface temperature
  • Surface wind
  • Omega at 500 hPa
  • Omega at 700 hPa
  • Forecast sounding (NAM)
  • Total cloud
  • 12h cumulative precip

  • Instructor's forecast summary

  Observed conditions at around 00Z Sunday 29 January, mostly GEM RDPS 0h progs:

  • MSLP and thickness
  • 700 hPa height and humidity
  • Temperature at 850 hPa
  • Surface temperature
  • Surface wind
  • Total cloud
  • CaPA 6h cum. precip
  • Stony Plain sounding
  • CYEG Metars
  • Tory webcam
  • GOES ir
  • GOES vis
  • YEG hourly observations
  • Omega at 850 hPa
  • Omega at 700 hPa
  • Omega at 500 hPa
  • 500 hPa height and vorticity

• Tues 24 Jan. Discussion of the meteorology of our foggy weekend. Lecture: Eulerian derivation of the conservation equation for an arbitrary species "φ", a "volumetric concentration" with units like [kg m^-3 or J m^-3]. Evaluating the "flux" of φ: convection, diffusion/conduction, radiation. Fourier's law of conduction, Fick's law of diffusion.
  Open: Exercises 24 Jan. Practice with the hydrostatic & hypsometric eqns. Close: Exercises 24 Jan.

  • obtain the WSE (Stony Plain) sounding data for 12Z Sunday 22 January 2017, and determine the 850-700 hPa thickness ΔZ

  • substitute this value into the hypsometric equation to determine the implied mean (virtual) temperature of the layer

  • compute a density -- ρ=p/(R_dT) -- for the 850 hPa level from the sounding data, then use the hydrostatic equation in finite difference form -- Δp/Δz = - ρg -- to give an approximate estimate of the 850-700 hPa thickness

  Note: remember to use MKS units in calculations. The gas constant for dry air R_d=287 J kg^-1 K^-1.

  Answers:

  • From the sounding, the wanted thickness is ΔZ=2918-1406 m = 151 dam.

  • It is easy to show that the relationship between the 850-700 hPa thickness and the layer mean temperature is ΔZ [dam] = 0.568 T_avg [K], so the measured thickness implies T_avg=265.8 K

  • Since T₈₅₀=-5.1^oC we have ρ=85000 / (287 (273.15-5.1)) = 1.1 kg m^-3

  • Using the hydrostatic law in an approximate way, Δ z = Δ p / (ρ g) = 15000/(1.1 9.81) = 1390 m = 139 dam, rather different from the true value.

• Thurs 19 Jan. Current weather: mild SW flow and Alberta lee trough. Lecture: horizontal momentum equations; vector cross-product; geostrophic wind equations.
  Open: Exercise 19 Jan. Calculate geostrophic wind speed. Close: Exercise 19 Jan.

  • Compute the geostrophic wind speed at the 500 hPa level at The Pass (radiosonde station YQD, near the Saskatchewan-Manitoba border) and compare with the value (55 knots, or nominally 22 m s^-1) reported by the YQD radiosonde

• Tues 17 Jan. Lecture: natural coordinate system; thermal advection; derivation of the hypsometric equation; first mean value theorem; projection of one vector onto another.
  Open: Exercise 17 Jan. Calculate advective heating rate. Close: Exercise 17 Jan.

  • Calculate the advective heating rate on these cropped 850 hPa analyses

• Thurs. 11 Jan. Lecture: Lagrangian derivative; conserved variables; grad operator, and its action on scalars and vectors; vector dot product. Complete the weather discussion started on Tuesday
  Open: Exercise 12 Jan. Weather forecast. Close: Exercise 12 Jan.

  • Prepare a forecast for conditions in C. Alberta valid (nominally) at 18Z Saturday 14 January. Base your forecast on the CMC RDPS run itialized at 12Z today, and state your forecast in a written summary of a few paragraphs (optionally, you might use this forecast form). The Meteocentre meteogram might also be helpful (but preferably accessed after you've digested the prog outputs for yourself).

  Some of the guidance available at the time:

  • MSLP & thickness (about 534 dam thickness over Edmonton, contrasting with about 510 dam at the initial time)
  • 700 hPa height & humidity (firm westerly upper flow; patchy humidity)
  • Surface temperature (minus 5 to minus 10^oC range)
  • Surface wind (light to moderate SW)
  • Total cloud
  • Cumulative precip (none)
  • NAM prog (consistent with GEM)
  • Meteogram

  JDW's Summary: the forecast thickness increase (24 dam or 12^oC) implies the lower stratosphere should be considerably milder; surface temperature in the minus 5 to minus 15^o bracket; sunny, with possible patchy high cloud; light SW wind; no precip.

  Actual conditions in C. Alberta at 18Z Saturday 14 January (incl. RDPS 0h prog):

  • YEG hourly conditions (minus 5 at 18Z)
  • GOES West ir image (cloudy)
  • GOES West vis. image
  • Tory webcam (cloudy)
  • RDPS 0h MSLP & thickness (thickness about 532 dam)
  • RDPS 0h 700 hPa (firm westerly, somewhat humid)
  • RDPS 0h surface temperature
  • RDPS 0h surface wind (light SW)
  • RDPS 0h total cloud (less than 50% over most of the region)
  • CaPA 6h cumulative precip (none)

• Tues 10 Jan. Orientation to EAS 372. Course Outline. Grading. Scope. Familiarization with web weather resources. Discussion of recent, present and pending weather in C. Alberta.
  Open: Exercise 10 Jan. Accessing CMC weather analyses and forecasts. Close: Exercise 10 Jan.

  • Access the CMC analyses and forecasts at the public web site (via class URLs).

  • Access the CMC NWP forecasts at Vizaweb (again, via class URLs). Bring up the most recent GEM-Global forecast valid 12Z Monday 16 January (i.e. the forecast initialized 12Z today, if available - otherwise, the forecast initialized 00Z today). Estimate the forecast 1000-500 hPa thickness for that time, subtract it from the present value (i.e. at 12Z today) and infer the change in temperature of the layer below 500 hPa.

Link to Earth & Atmospheric Sciences home page.

Last Modified: 17 Apr., 2017