Climatology of Surf ace Fronts

Similar documents
CHIAA Research Report No MOST SEVERE SUMMER HAILSTORMS IN ILLINOIS DURING

Dry Periods in Illinois A Climatological and Meteorological Analysis

1. TEMPORAL CHANGES IN HEAVY RAINFALL FREQUENCIES IN ILLINOIS

Illinois State Water Survey at the University of Illinois Urbana, Illinois

The Analysis of Urban Effects on Winter Snowfall in the Saint Louis Metropolitan Area

State Water Survey Division CLIMATOLOGY SECTION AT THE UNIVERSITY OF ILLINOIS

Atmospheric Sciences Section Illinois State Water Survey Urbana, Illinois COLLECTION OF RAIN AND HAIL DATA IN NORTHEASTERN ILLINOIS

A PRELIMINARY REPORT UNIQUE HAIL AND TORNADIC STORM OBSERVATIONS CENTRAL ILLINOIS AND EASTERN INDIANA 3 APRIL 1974

Illinois State Water Survey at the University of Illinois Urbana, Illinois

ANNUAL REPORT 1 March February 1972 Period FIELD STUDY OF URBAN EFFECTS ON PRECIPITATION AND SEVERE WEATHER AT ST. LOUIS

Synoptic Analysis of Total Rainfall Patterns at Azerbaijan District.

Hydrometeorology of Heavy Rainstorms in Chicago and Northeastern Illinois

ISWS RI-33 copy 2 loan SWS1103

Atmospheric Sciences Section Illinois State Water Survey Urbana, Illinois 61801

Atmospheric Sciences Section Illinois State Water Survey Urbana, Illinois 61801

STUDY OF URBAN EFFECTS ON PRECIPITATION AND SEVERE WEATHER AT ST. LOUIS. Annual Report for March February 1973

CYCLONIC AND FRONTAL ACTIVITY IN OHIO DURING THE SUMMER OF 1953

INTRODUCTION. A central area of research and services of the Atmospheric Sciences

Impacts of the April 2013 Mean trough over central North America

DOWNLOAD PDF READING CLIMATE MAPS

7 - DE Website Document Weather Meteorology

C1: From Weather to Climate Looking at Air Temperature Data

ILLINOIS STATE WATER SURVEY at the University of Illinois Urbana, Illinois CLIMATOLOGICAL ASSESSMENT OF URBAN EFFECTS ON PRECIPITATION

DEPARTMENT OF EARTH & CLIMATE SCIENCES Name SAN FRANCISCO STATE UNIVERSITY Nov 29, ERTH 360 Test #2 200 pts

Extreme Air Temperature at the Southwestern Slope of Pirin Mountain (Bulgaria)

State Water Survey Division METEOROLOGY SECTION

ILLINOIS STATE WATER SURVEY. at the. University of Illinois Urbana, Illinois A STATISTICAL METHODOLOGY FOR THE PLANNING AND EVALUATION

AOSC 200 Tim Canty. Class Web Site: Topics for today: Air Masses. Fronts. Lecture 19 Apr

THE EFFECT OF NATURAL RAINFALL

Counselor s Name: Counselor s Ph #: 1) Define meteorology. Explain how the weather affects farmers, sailors, aviators,

Further Studies of the Whitetop Cloud-Seeding Experiment

Characteristics of 2014 summer climate over South Korea

Springer Atmospheric Sciences

May 2005 Climate Summary

The Australian Operational Daily Rain Gauge Analysis

P3.1 Development of MOS Thunderstorm and Severe Thunderstorm Forecast Equations with Multiple Data Sources

Weather to Climate Investigation: Maximum Temperature

Drought Climatology of Illinois

Recent Trends in Northern and Southern Hemispheric Cold and Warm Pockets

Weather Merit Badge Worksheet Hiller Aviation Museum

Adding Value to the Guidance Beyond Day Two: Temperature Forecast Opportunities Across the NWS Southern Region

Use the terms from the following list to complete the sentences below. Each term may be used only once.

Practical Atmospheric Analysis

Weather Merit Badge Workbook

General Circulation. Nili Harnik DEES, Lamont-Doherty Earth Observatory

Chapter 5: Weather. Only Section 1: What is Weather?

Global Winds AOSC 200 Tim Canty

Cuba. General Climate. Recent Climate Trends. UNDP Climate Change Country Profiles. Temperature. C. McSweeney 1, M. New 1,2 and G.

FORMATION OF AIR MASSES

Nonlinear atmospheric response to Arctic sea-ice loss under different sea ice scenarios

RR#5 - Free Response

Name: Climate Date: EI Niño Conditions

Worksheet: The Climate in Numbers and Graphs

Chapter 12 Fronts & Air Masses

Local Ctimatotogical Data Summary White Hall, Illinois

Atmospheric Sciences Section Illinois State Water Survey Urbana, Illinois 61801

Interdecadal variation in rainfall patterns in South West of Western Australia

DISTRIBUTION AND DIURNAL VARIATION OF WARM-SEASON SHORT-DURATION HEAVY RAINFALL IN RELATION TO THE MCSS IN CHINA

Tropical Storms Reduced Drought in Illinois in 2005

Introduction to Climatology. GEOG/ENST 2331: Lecture 1

Quiz 2 Review Questions

Champaign-Urbana 1999 Annual Weather Summary

Severe weather. Some case studies for medium-range forecasting. T. La Rocca, Department of Synoptic Meteorology, Italian Met. Service, Rome.

Eastern United States Wild Weather April 2014-Draft

P2.4 Synoptic Conditions Associated with Dense Fog in the Midwest

Air Masses and Fronts. Ahrens Chapter 12

GEO165 LAB EXERCISE #3

Scout s Address: City State Zip:

DEPARTMENT OF GEOSCIENCES SAN FRANCISCO STATE UNIVERSITY. Metr Fall 2012 Test #1 200 pts. Part I. Surface Chart Interpretation.

1. Which weather map symbol is associated with extremely low air pressure? A) B) C) D) 2. The diagram below represents a weather instrument.

Plan for operational nowcasting system implementation in Pulkovo airport (St. Petersburg, Russia)

Custom Weather Forecast

Background: What is Weather?

Annex I to Target Area Assessments

CURRICULUM OUTLINE. DEPARTMENT: Science DATE: January, 2004

WEATHER ON WHEELS Elementary School Program

Appalachian Lee Troughs and their Association with Severe Thunderstorms

The Palfai Drought Index (PaDI) Expansion of applicability of Hungarian PAI for South East Europe (SEE) region Summary

INTRODUCTION. Storm Types. Rationale for the Study

A Study on Estimation Technique of Extreme Precipitation Diameter

Weather Unit Part 2: Meteorology

Atmospheric circulation analysis for seasonal forecasting

ILLINOIS STATE WATER SURVEY at the University of Illinois Urbana, Illinois ATMOSPHERIC EFFECTS FROM WASTE HEAT TRANSFER ASSOCIATED WITH COOLING LAKES

Precipitation Climatology of Lake Michigan Basin

Air Masses and Fronts

FIRST PROGRESS REPORT ILLINOIS COOPERATIVE PROJECT IN CLIMATOLOGY

Gridding of precipitation and air temperature observations in Belgium. Michel Journée Royal Meteorological Institute of Belgium (RMI)

ABSTRACT 3 RADIAL VELOCITY ASSIMILATION IN BJRUC 3.1 ASSIMILATION STRATEGY OF RADIAL

4 Forecasting Weather

THREE LATE SPRING FRONTS IN THE CARIBBEAN by W. K. Henry Texas A&M University College Station, TX

MAST ACADEMY OUTREACH. WOW (Weather on Wheels)

What Is the Weather Like in Different Regions of the United States?

Paul T. Schickedanz, Prameela V. Reddy, and Stanley A. Changnon

Development of Empirical Weather Forecasting Techniques for Soaring Flight

The Pennsylvania Observer

Bugs in JRA-55 snow depth analysis

5.0 WHAT IS THE FUTURE ( ) WEATHER EXPECTED TO BE?

STUDIES OF HAIL DATA IN Stanley A. Changnon, Jr., and Nell G. Towery. Final Report

Discussion Paper on the Impacts of Climate Change for Mount Pearl. August, Darlene Butler. Planning Department. City of Mount Pearl

Application and verification of ECMWF products 2010

Transcription:

LOAN COPY ISWS-7S-CIRI22 Circular I22 STATE OF ILLINOIS DEPARTMENT OF REGISTRATION AND EDUCATION Climatology of Surf ace Fronts by GRIFFITH M. MORGAN, JR., DAVID G. BRUNKOW, and ROBERT C. BEEBE ILLINOIS STATE WATER SURVEY URBANA 1975

CONTENTS PAGE Introduction 1 Tabulation technique 1 Comments on interpretation 4 References 4 Appendix A. Frequency of cold fronts, in days per 10 years 5 Appendix B. Frequency of warm fronts, in days per 10 years 11 Appendix C. Frequency of occluded fronts, in days per 10 years.... 17 Appendix D. Frequency of stationary fronts, in days per 10 years.... 23 Appendix E. Frequency of squall lines, in days per 10 years 29 Appendix F. Frequency of high pressure centers, in days per 10 years.. 35 Appendix G. Frequency of low pressure centers, in days per 10 years.. 41

Printed by authority of the State of Illinois - Cb. 127, IRS, Par. 58.29 (3-75-1000)

CLIMATOLOGY OF SURFACE FRONTS By Griffith M. Morgan, Jr., David A. Brunkow, and Robert C. Beebe Introduction This report presents information on the frequency of occurrence of frontal systems (cold, warm, occluded, stationary), squall lines, and high and low pressure centers over North America. It provides maps of average frequencies for all months for the 10-year period 1961-1970, given in appendices A through G. Surface frontal systems are idealized devices that weather forecasters find useful in simplifying an otherwise bewildering array of data to the point that a forecast of the more directly sensible weather elements can be made. Fronts figure in various ways in climatological studies. For instance, Hiser (1956) determined the percentage of rainfalls in central Illinois which are associated with various frontal categories. Beebe and Morgan (1972) used frontal categories in investigating the synoptic factors important to the downwind enhancement of rainfall by the urban complex of St. Louis, Missouri. The present frontal climatology is similar to, but on a much greater scale, than that of Chiang (1961) who determined the frequency of occurrence of various types of fronts in 60 60 n mi boxes in Illinois on the basis of the Daily Weather Map Series for the 15-year period 1945-1959. Similar tabulations on a much coarser scale were used during the 1950s in the weather summaries appearing in the Monthly Weather Review. Huff (1961) utilized Chiang's frontal frequencies in a study of the relationship between the distribution of Illinois hailstorms and other climatological factors. The distribution of climate elements within Illinois can best be interpreted in relation to the pattern over a much larger area. For this reason it was decided to pursue the study of frontal climatology on the scale of the entire North American Daily Weather Map. The results of a tabulation at this scale will also be useful for studies in areas other than Illinois, and should be of use to researchers in other regions. This Circular aims to make these results available to a wide audience of users. It contains a minimum of interpretative comments. These data are expected to find useful application in various areas of research at the Water Survey, and are available to any bonafide user in the form of punched cards or magnetic tape. The program for processing the raw data can also be made available. Initial use of the data on Project Metromex (Changnon et al., 1971) is described by Morgan, Beebe, and Brunkow (1973). This work was carried out under the general supervision of Stanley A. Changnon, Jr., Head of Atmospheric Sciences Section, Illinois State Water Survey. Mildred Broquard accomplished the initial stages of the PLI programming. Digitizing of the maps was done by Catherine Jackson, Janet Lang, and Susan Moyer. Keypunching was done by the Water Survey Data Processing Unit. This study has been financed by the National Science Foundation under Grant GI-38371. Tabulation Technique The basis for this frontal climatology is the Daily Weather Map Series for the period 1 January 1961 through 31 December 1970. This was a 10-year period of apparently uniform analysis technique. The Daily Weather Map is printed on a polar stereographic projection, true at latitude 60 N. A grid was made by dividing this into quasisquares 60 n mi on a side created by marking off every 60 n mi along latitude circles, starting from a fixed reference longitude (100 W). This grid, printed on plastic, was overlain on each map and the squares through which fronts passed were tabulated. Squares with high and low pressure centers were also tabulated. The total in each grid square for each frontal and pressure-center type was determined and examined in two forms: 1) printed computer output of grid-box totals, and 2) computer- 1

plotted contour maps on the original map projection. [The data presented are in the latter form. Because the contouring program examines the range of values on each map and draws contours at approximately 10 levels, the contour interval must be noted in comparing maps.] The basic 60 X 60 n mi grid yields distributions that are quite detailed. Some of this detail may be of climatological significance and some is undoubtedly due to sampling inadequacies. For this Circular the following computerexecuted smoothing operation was employed. On each map, each 60 X 60 n mi grid square contained a yes or a no and a type code. With no smoothing employed, it was necessary only to accumulate the yeses over a specified time period, say one month or one month-decade, for each square and then to map the results. Smoothing was accomplished by scanning the grid square and adjacent grid squares and entering a yes if there was an element (front or pressure center) in any of them. This is the same as increasing the size of the basic grid square, but sliding it around by increments of 60 n mi in each direction. A sample of the effect of progressively increasing the grid size from 60 X 60 to 180 X 180 to 300 X 300 n mi is shown in figures 1,2, and 3. The maps presented in appendices A-G are based on the 300 300 n mi smoothing grid. Figure 1. Frequency of stationary fronts (days), August 1971, 60 X 60 n mi grid 2

Figure 2. Frequency of stationary fronts (days), August 1971, 180 X 180 n mi grid Figure 3. Frequency of stationary fronts (days), August 1971, 300 X 300 n mi grid 3

Comments on Interpretation There are a number of things to be kept in mind in interpreting the maps shown here. The Daily Weather Maps are subjective synoptic analyses. Individual analysts tend to have their own emphasis, style, and degree of attention to detail. It is probable that at times fronts exist which are not indicated on the map, and the reverse may also happen. Fronts can also on occasion be improperly identified (a slow cold front may be labeled as a stationary front or even a warm front). Squall lines and cold fronts can also be confused. On occasion fronts are placed on maps just to explain some weather which shortly disappears and the front with it. An experienced analyst understands this and can make allowances for it. To undertake critical re-analysis of 10 years of weather maps is out of the question and would not really alter the situation. In spite of these subjective factors, the long series of maps employed here should provide meaningful and useful results. The easiest maps to interpret are those of stationary fronts. In general a pronounced belt of maximum stationary front occurrence can be observed. The region of this belt can be considered as one where the leading edges of southward surges of cold air tend to 'stall out.' Most frequently cold air lies to the north of this belt and warm air to the south of it. Squall lines are the least meaningful elements in the map series because of the morning map times, the short lifetimes of these phenomena, and the difficulty of defining squall lines with synoptic data. Interpretation of the geographical distributions of frequency of moving frontal systems is less straightforward and requires study. High frequency of occurrence of, say, cold fronts can be due to 1) lower speed of translation through the region than through neighboring regions, 2) high frequency of frontogenesis in and near the region, and 3) analysis quirks. The inverse of 1) and 2) would apply to regions of low frequency. References Beebe, R. C, and G. M. Morgan, Jr. 1972. Synoptic analysis of summer rainfall periods exhibiting urban effects. Preprints, AMS Conference on Urban Environment, Philadelphia, pp. 173-176. Changnon, S. A. Jr., F. A. Huff, and R. G. Semonin. 1971. Metromex: an investigation of inadvertent weather modification. Bulletin American Meteorological Society, v. 52(10):958-967. Chiang, I. 1961. A study of synoptic climatology in Illinois. Masters Thesis, Southern Illinois University, Carbondale. Hiser, H. W. 1956. Type distributions of precipitation at selected stations in Illinois. Transactions American Geophysical Union, v. 37(4):421-424. Huff, F. A. 1961. Correlation between summer hail patterns in Illinois and associated climatological events. Prepared for Crop-Hail Insurance Actuarial Association, Chicago, Research Report 10, 17 pp. Morgan, G. M., Jr., R. C. Beebe, and D. A. Brunkow. 1973. Application of frontal climatology by digital techniques to Project Metromex. In Summary Report of Metromex Studies, 1971-1972, F. A. Huff, Ed., Illinois State Water Survey Report of Investigation 74, pp. 28-35. 4

Appendix A. Frequency of Cold Fronts, in Days per 10 Years 5

A. Cold Fronts 6

A. Cold Fronts 7

A. Cold Fronts 8

A. Cold Fronts 9

A. Cold Fronts 10

Appendix B. Frequency of Warm Fronts, in Days per 10 Years 11

B. Warm Fronts 12

B. -Warm Fronts 13

B. Warm Fronts 14

B. Warm Fronts 15

B. Warm Fronts 16

Appendix C. Frequency of Occluded Fronts, in Days per 10 Years 17

C. Occluded Fronts 18

C. Occluded Fronts 19

C. Occluded Fronts 20

C. Occluded Fronts 21

C. Occluded Fronts 22

Appendix D. Frequency of Stationary Fronts, in Days per 10 Years 23

D. Stationary Fronts 24

D. Stationary Fronts 25

D. Stationary Fronts 26

D. Stationary Fronts 27

D. Stationary Fronts 28

Appendix E. Frequency of Squall Lines, in Days per 10 Years 29

E. Squall Lines 30

E. Squall Lines 31

E. Squall Lines 32

E. Squall Lines 33

E. Squall Lines 34

Appendix F. Frequency of High Pressure Centers, in Days per 10 Years 35

F. High Pressure Centers 36

F. High Pressure Centers 37

F. High Pressure Centers 38

F. High Pressure Centers 39

F. High Pressure Centers 40

Appendix G. Frequency of Low Pressure Centers, in Days per 10 Years 41

G. Low Pressure Centers 42

G. Low Pressure Centers 43

G. Low Pressure Centers 44

G. Low Pressure Centers 45

G. Low Pressure Centers 46

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback